EPA-670/9-75-006
August 1975
HANDBOOK
FOR EVALUATING
WATER BACTERIOLO
LABORATORIES
U.S. ENVIRONMENTAL PROTECTION AGENCY
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This document is available to the public through the National Technical
Information Service, Springfield, Virginia 22151.
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EPA-670/9-75-006
August 1975
Handbook for
EVALUATING
WATER BACTERIOLOGICAL
LABORATORIES
Second Edition
Edwin E. Geldreich
Microbiological Quality Control
Water Supply Research Division
Municipal Environmental Research Laboratory
Cincinnati, Ohio 45268
Program Element No. 1CB047
MUNICIPAL ENVIRONMENTAL RESEARCH LABORATORY
OFFICE OF RESEARCH AND DEVELOPMENT
U.S. ENVIRONMENTAL PROTECTION AGENCY
CINCINNATI, OHIO 45268
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REVIEW NOTICE
The Municipal Environmental Research Laboratory, U.S. Environ-
mental Protection Agency, has reviewed the report and approved its
publication. Mention of trade names or commercial products does not
constitute endorsement or recommendation for use.
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FOREWORD
The Safe Drinking Water Act (Title XIX of the Public Health Act),
enacted into law on December 16,1974, requires the Administrator of the
U.S. Environmental Protection Agency to promulgate a set of primary
drinking water regulations. These regulations, which will apply to all
public drinking water systems as defined in "The Act" shall
• specify contaminants that may have any adverse effect on the health
of persons;
• specify a maximum contaminant level or a treatment technique;
• contain criteria and procedures to ensure a safe drinking water
supply.
The various states will be responsible for ensuring that the local water
supply utilities meet the primary drinking water regulations. Therefore,
the U.S. Environmental Protection Agency's State Laboratory Certifica-
tion Program has become an integral part of carrying out the provisions of
the Safe Drinking Water Act.
This report, developed by the Water Supply Research Division, Munic-
ipal Environmental Research Laboratory, as part of our continuing re-
sponsibilities for the certification of state water supply laboratories, is an
update and expansion of a similar document published by the Public
Health Service in 1966. The effort contained in this supportive document
represents part of the U.S. Environmental Protection Agency's total
quality assurance and laboratory certification program in the areas of
water pollution abatement and water supply protection. The Environ-
mental Monitoring and Support Laboratory, U.S. Environmental Protec-
tion Agency, is responsible for developing certification criteria and
methods manuals for both water and wastewater laboratories and is
responsible for coordinating all Federal involvements in the total water
quality assurance and laboratory certification programs.
A. W. Breidenbach, Ph.D.
Director
Municipal Environmental
Research Laboratory
Hi
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ABSTRACT
The material included in this Handbook is designed and intended to
provide a comprehensive source of information and reference for the
evaluation of laboratories involved in bacteriological testing of potable
water supplies and their sources. The information is based upon more
than 15 years experience by the author in bacteriological laboratory
surveys and observations of laboratory practices in water examination
throughout this Nation.
The Handbook covers all aspects of the laboratory operation including
material and media preparation, equipment needs and specifications,
sample collection and handling, bacteriological methodology, quality
control considerations, laboratory management, and the survey officer's
qualifications and responsibilities.
The purpose of this Handbook is to assist the laboratory survey officer,
laboratory director, and senior bacteriologist in charge of the water
program to evaluate the many aspects of the laboratory that are involved
in attaining reliable data.
iv
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PREFACE
The intensified concern with potable water quality and the develop-
ment of criteria and standards for various classes of natural water are
reflected in increased requests for more laboratory analyses. These re-
quests now include not only the traditional total coliform procedure used
to monitor contamination breakthroughs into finished waters, but also
standard plate counts to detect water quality deterioration in distribution
networks. Recreational water quality criteria include fecal coliform
limits, and epidemiological investigations may require examinations for
some specific waterborne pathogens. Thus, the bacteriological labora-
tory today must have capabilities for expanded examinations.
In 1943, L. A. Black of the U.S. Public Health Service, developed a
survey form for water bacteriology laboratories, which was utilized by
the Public Health Service personnel during periodic evaluations of state
laboratories. Additionally the form was used by various state survey
officers in the evaluation of those laboratories within their respective
states that were involved in the examination of water. A similar check of
state water chemistry laboratories was not made, however, since only a
few states performed routine chemical analyses. In fact, even today,
some states do few or no routine water chemical determinations and the
remainder do less than an adequate job of surveillance. In an effort to
improve this situation, the development of a water chemistry survey form
was initiated in July 1969 and is now being used to evaluate state and
Federal water chemistry laboratories by specialists in chemistry.
The demand for expanded laboratory involvement by various en-
vironmental agencies has created a need for this second edition of the
manual Evaluation of Water Laboratories first published by the Public
Health Service in 1966. This document was the product of prepared notes
and ideas developed by both Harold F. Clark and Edwin E. Geldreich in
their assignments to evaluate bacteriological laboratories responsible for
the examination of water supplies. Many of their laboratory research
developments in methodology have since been adopted by Standard
Methods for the Examination of Water and Wastewater.
Over 5,000 copies of the first edition were circulated to bacteriologists,
chemists, sanitary engineers, water plant management personnel, univer-
sity professors, college students, and numerous foreign scientific centers
concerned with laboratory quality control in their countries. As a result of
the unforeseen demand for a modest attempt to supply guideline assist-
ance to those persons involved in laboratory evaluations, the supply of
the first edition is now depleted.
While preparing the second edition, a more general coverage of
laboratory practice beyond the scope or intent of Standard Methods for
Examination of Water and Wastewater was sought. This new approach
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was also used in revising the bacteriological survey form (EPA-103) to
increase its flexibility and make it more useful in evaluating laboratories
that examine stream and/or marine pollution samples in addition to pota-
ble waters. In developing both the survey form and the handbook, the
intent was to present guidelines for conformity with Standard Methods
for the Examination of Water and Wastewater, U.S. Environmental
Protection Agency methods manuals, and other generally accepted
laboratory practices. The underlying goal is to facilitate the collection of
data having the greatest sensitivity, reliability and precision whether for
monitoring potable and recreational water quality or for enforcement
actions concerned with water quality degradation.
Edwin E. Geldreich
June 1975
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ACKNOWLEDGMENTS
No study of this scope could be possible without the assistance of many
state sanitary engineers, water-plant managers, laboratory directors,
state survey officers, bacteriologists, sanitarians, and technicians who
share a sincere interest and concern about potable water supplies and the
meaningful measurement of bacteriological quality. The willingness of
this multidiscipline group to discuss openly their problems, make records
available for analysis, and correct recognized deviations in procedures
conscientiously is greatly appreciated.
Special acknowledgements must also be given to Dr. Harry D. Nash,
Dr. Donald J. Reasoner, and Mr. Raymond H. Taylor for their critical
review of technical material and suggestions on narrative structure; to
Mrs. Virginia Maphet for the difficult and precise task of manuscript
preparation; to my wife, Delta, for proofreading copy during various
stages of manuscript development; and to Mrs. Marion Curry for much
appreciated editorial assistance in the evolution of the Handbook.
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CONTENTS
Foreword iii
Abstract iv
Preface v
Acknowledgments vii
I. Introduction to Laboratory Evaluation 1
II. Sampling and Monitoring Response 11
III. Laboratory Apparatus 27
IV. Glassware, Metal Utensils, and Plastic Items 43
V Laboratory Materials Preparation 57
VI. Culture Media Specifications 77
VII. Multiple Tube Coliform Procedures 97
VIII. Membrane Filter Coliform Procedures 117
IX. Supplementary Bacteriological Methods 135
X. Laboratory Management 159
XI. The Narrative Report 171
Glossary 177
Subject Index 191
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CHAPTER I
INTRODUCTION TO LABORATORY EVALUATION
It is essential that laboratory methods be adopted that are reliable and
produce uniform results in all laboratories involved in monitoring this
Nation's 40,000 public water systems and the 10 million individual water
supplies and the 200,000 water supplies serving the traveling public.
Analysis of data available to the U.S. Environmental Protection
Agency (EPA) laboratory evaluation program indicates that state health,
state environmental, city-county health, municipal water treatment, and
private laboratories are examining approximately 3.5 million samples
annually from this Nation's public and private water supplies and are
gathering monitoring data on natural waters relative to state and Federal
standards for a variety of water quality uses. An estimated million addi-
tional samples are analyzed by local laboratories in quality control
monitoring of industrial and municipal waste discharges as required in the
National Pollution Discharge Elimination System.
Data developed from these examinations must be reliable and beyond
reproach when used in judgment of technical operations in water treat-
ment or in legal action involving public health hazards. For these reasons,
it is desirable to use a generally accepted set of standard test methods that
are acknowledged by the scientific community as representing the best
available procedures. The need to develop a unified approach to the
examination of water quality was recognized in 1905 with the publication
of the first edition of Standard Methods of Water Analysis. New editions
of this reference appearing through the intervening years recognize a
continuing need to reevaluate recommended procedures in response to
new research developments.
Current editions of Standard Methods for the Examination of Water
and Wastewater (1) (Standard Methods) receive legal acceptance at all
levels of state and Federal court systems. By government regulation (2),
all analyses of drinking water and water supply systems used by carriers
and others subject to Federal quarantine regulations must conform with
provisions of the current edition of the Standard Methods reference. One
of the mission responsibilities of EPA's Water Supply Research Labora-
tory is to ensure that all laboratories follow proper application of Stand-
ard Methods in the examination of potable waters. Since this program
includes not only state health laboratories, but also county and city health
laboratories, municipal water plant laboratories, hospital, and university
and private laboratories, there is a need for assistance at the state level in
maintaining the extensive coverage of all laboratories involved.
Traditionally, the Federal water supply program has approved the state
laboratories, which in turn, through qualified state laboratory survey
officers, certify the local laboratories within each state. On occasion, the
INTRODUCTION 1
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Federal water program performs cross-section studies of the laboratory
service within a given state to ascertain the quality of work being per-
formed not only by the large state laboratory system but also by the small
water plant laboratories that are checking finished water and quality
throughout the distribution system. The ultimate goal is to upgrade the
quality of data in all water plant laboratories so that it is acceptable as part
of the official monitoring of public water supplies. At present, the data
obtained by many small water plant laboratories cannot be used as official
data because of questionable application of recommended procedures.
Thus the state laboratory service is burdened with the complete monitor-
ing requirements for all official samples examined monthly from each
public water supply.
THE APPROACH TO LABORATORY EVALUATION
The laboratory survey officer should view the evaluation as a confer-
ence relating to methods and procedures recommended in Standard
Methods and appropriate EPA Methods Manuals (3-5), emphasizing the
need and importance for standard procedures that will produce reliable
data, comparable to similar data from other laboratories. Certainly, en-
dorsement of the laboratory as being approved by the state or Federal
government does bring significant prestige, and discussion with recog-
nized experts in water analyses affords the opportunity for increased
technician knowledge. This attitude yields much better results with the
majority of the laboratories than does an attitude that emphasizes the
regulatory activities of the visit.
PROGRAM OBJECTIVES
The objectives of a laboratory evaluation are to improve the quality of
technical procedures so that the data compiled are reliable and to ensure
that the water consumer and recreational water user are provided the
greatest possible health protection. Techniques must always remain as
sensitive as the state-of-the-art permits. This is of particular importance
in the continued monitoring for the low levels of coliform bacteria that
could signal the occurrence of possible contamination by pathogenic
microorganisms. Technicians must always attach equal importance to
every potable water examination, regardless of the source or the fre-
quency of negative results. Monotony of negative results tends to breed
technical carelessness that can quickly lead to bad habits and deviations
from standard procedures. Although occasional deviations in technique
may in themselves be insignificant, the cumulative effect of several devia-
tions decreases test sensitivity and adversely reflects on data reliability.
Failure to detect low levels of coliform organisms obviously poses a
potential health hazard to consumers of such water.
Deviations in laboratory procedures will continue as a result of such
factors as attempted shortcuts, ignorance of technical procedures, inex-
perience in new methods, equipment failures, inadequate facilities, tech-
nical carelessness, shifts of competent personnel to other laboratory
assignments, and lack of interest in this phase of public health bacteriolo-
gy. Thus, there exists a continuing need for laboratory evaluation serv-
ices, both at the state and the municipal levels, to hold number of
2 Evaluating Water Bacteriology LaboratorieslGeldreich
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deviations to an absolute minimum (6, 7). For the purposes of estimating
cost for this activity, 5 man-days are required per state or regional
laboratory as contrasted with 3 man-days required for this same service at
small local laboratories where testing capabilities are more limited. These
time/cost studies should include survey preparation, travel time, per
diem, site visits, and report preparation (8).
The optimum frequency of laboratory evaluations at the state level
appears to be every 3 years. Visits at more frequent intervals are of little
value to either the staffer the program; whereas, the longer the interval,
the more deviations observed. However, where there are major difficul-
ties or where there is a large turnover of laboratory personnel, evaluations
must be performed at more frequent intervals, depending on the indi-
vidual situation. For these reasons, EPA's Water Supply Division re-
commends that these laboratory evaluations should be accomplished at
least every 3 years.
STATE WATER LABORATORY EVALUATION PROGRAM
The key to expanding the network of qualified laboratories monitoring
public water supply quality throughout the Nation is in an effective and
vigorously pursued certification program at both the Federal and state
levels. The Federal program pioneered the development of the in-depth
laboratory survey approach over 40 years ago and, through the years, has
encouraged all states to formulate or expand their own certification
programs (9).
As a result of these experiences, a protocol has emerged that is being
used with some variations by many state laboratory evaluation groups.
The first step is to establish an inventory of all laboratories known to be
examining water. This exploratory list should include laboratories in the
state; county, city health, and environmental protection departments;
universities; and water and sewage plants, plus those commercial
laboratories that advertise such services. Inquiry by letter or telephone is
then made to determine the extent of the services available. The initial
contact must establish what microbiological testing is being performed,
type of waters examined, use of most probable number (MPN) or mem-
brane filter (MF) procedure, and the availability of essential equipment
items, including a copy of the current edition of Standard Methods. If it is
established that the laboratory has all of the essential equipment and is
using the recommended procedures, then the state survey officer should
schedule the first on-site evaluation within 3 months of the initial contact.
During this interval, a copy of the U.S. Environmental Protection Agency
Bacteriological Survey Form is then sent to the laboratory personnel for a
self-appraisal of their water program. Where it becomes evident that the
laboratory does not have the required expertise, their designated person-
nel are generally invited to visit the state laboratory for several days to
receive necessary bench training. These persons should also be encour-
aged to participate in a regional EPA laboratory training course or possi-
bly receive individual training on specific techniques in water bacteriolo-
gy-
Following the on-site survey, a copy of the evaluation report must be
sent to the participating laboratory. If the laboratory is approved, a
INTRODUCTION 3
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certificate with expiration date and a registration number should be
issued. The certificate should state that the named laboratory has met the
requirements and recommendations of the state agency and the EPA and
is, therefore, authorized to perform specified bacteriological examina-
tions of water. Certificates should then be reissued every 2 or 3 years
following a satisfactory on-site laboratory evaluation.
There may be occasions when private laboratories in adjacent states
may request certification for purposes of testing waters within the state.
Reciprocal certification is feasible if the adjacent state survey officer can
provide a copy of his evaluation report including a statement of satisfac-
tory laboratory certification status. To this reciprocal agreement must be
added a statement that laboratory data developed by the out-of-state
laboratory are acceptable as official data only where sample transit times
for potable waters do not exceed 30 hours; or where maximum transit
times for stream and effluent water quality measurements do not exceed 6
hours.
During the interval between recertification, the state evaluation pro-
gram should develop a bacteriological split-sampling protocol to test
laboratory proficiency and to reaffirm the continuing production of reli-
able data (10-13). Pure cultures might afford some measure of testing
laboratory proficiency, but they will not be representative of the interplay
of mixed microbial flora common to a natural water sample. Possibly a
mixed microbial flora could be created in an artificial test sample that
would be representative of microbial interferences that produce some of
the characteristic interferences inherent to both the multiple tube and MF
procedures. Standard plate count agars should be tested for optimum
recovery and, by use of organisms that produce only small colonies, a test
of technician counting proficiency could be made.
A complete study of a laboratory including evaluation of procedures,
equipment, and research; consultations with the laboratory personnel;
and a review of findings can rarely be done in less than 4 hours. In
evaluating a new laboratory for the first time, extra time should be allotted
to orient the staff and management to the benefits of the evaluation and
the desired program objectives. Each state evaluation program should
maintain a current list of the laboratories having the capability for bac-
teriological examination of water and include those approved or certified
and any laboratories provisionally approved or in noncompliance. Survey
frequency should be on a 2-year basis when the laboratory procedures are
acceptable but on a 6-month to 1-year basis for those laboratories receiv-
ing a provisional approval status. Immediate reevaluation becomes man-
datory in the small local, private, or commercial laboratory upon a change
in the laboratory director's or chief laboratory technician's position.
The designated state laboratory survey officer must be certified by a
member of the Federal laboratory evaluation service. Certification is
based upon knowledge of coliform detection methods, required laborato-
ry apparatus, media requirements, and analysis of laboratory records
during a joint visit of the designated state survey officer and the Federal
counterpart. The state designate should be observed to have those qual-
ities of temperament conducive to establishing a cooperative attitude
among the laboratory personnel being reviewed without incurring re-
sentment.
4 Evaluating Water Bacteriology LaboratoryIGeldreich
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GENERAL STATUS OF LABORATORIES
In general, more current laboratory procedures, newer equipment and
laboratory facilities, and more experienced personnel are found in state
laboratories than are found in many municipal laboratories. The major
obstacles are related directly to limited financial budgets that prevent
purchasing necessary replacement equipment and low salary levels that
don't attract technicians with the desired academic background. These
two difficulties can contribute to poor quality laboratory service. A 1971
analysis of laboratory evaluation reports on 69 state, regional, local health
laboratories and 93 municipal laboratories indicated an average of four
deviations per state laboratory as contrasted to an average of six devia-
tions per municipal laboratory. Many of the deviations observed in
municipal laboratories reflected the need for equipment replacement
(autoclaves, incubators, pH meters, analytical balances, water stills) and
the lack of attention given to procedural details used in the examination of
potable water. It was particularly disturbing to note that 12 municipal
laboratories did not have the current edition of Standard Methods availa-
ble for reference to the acceptable techniques.
INITIATING A REQUEST FOR EVALUATION
Most requests for a laboratory evaluation originate from laboratories
that previously benefited from this service and have taken pride in receiv-
ing certification. In other instances, interest in a program review origi-
nates from laboratory personnel seeking advice on a major changeover in
choice of Standard Methods' tests or because of changes in laboratory
personnel. Infrequently, requests for a review of laboratory procedure
originate because of discrepancies in data obtained from different
laboratories involved in some overlap monitoring of municipal supplies or
surveillance of bathing water quality.
An upsurge in laboratory evaluation requests to the Federal water
supply program relate to a growing number of state water supply divisions
interested in obtaining in-depth studies of all elements of their program
activities. These special analyses of laboratory service include large and
small water plant laboratories that may or may not have been evaluated
by the state, plus study of the state branch laboratory system and water
supply surveillance program. The net result is the necessity to evaluate
more than just the central or state laboratory.
In initiating a request, local laboratories should transmit a written
request through supervisory channels to the director of state laboratories,
attention of the water laboratory survey officer. State health laboratories
requesting a similar review of their water laboratory section should ad-
dress their requests to the Regional Administrator, U.S. Environmental
Protection Agency. Dates for evaluation visits at both the state and
national level are usually grouped by geographical areas to conserve both
staff time and travel money. With an emergency request, however, every
effort will be made by the survey officer to respond as promptly as
possible.
INTRODUCTION 5
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CONDUCTING THE EVALUATION
The laboratory survey should be scheduled in advance and at a time
agreeable with both the consultant and laboratory personnel. Un-
scheduled surveys may be necessary under certain circumstances. For
example, if a laboratory is placed on provisional or prohibited status, the
subsequent survey should be scheduled. If, however, it is necessary to
retain the laboratory on provisional or prohibited status, the survey
officer could then exercise the prerogative of making an unannounced
visit for a progress report or for formulating a final decision on prohibiting
any further official water examination in that facility.
Both the survey officer and laboratory personnel must cooperate by
assuming certain responsibilities in order to gain maximum benefit from
the survey. The laboratory should schedule sufficient water examinations
so that all routine bacteriological procedures can be evaluated from the
initial processing steps to the concluding phase of reading test results and
recording data. All laboratory personnel involved in conducting any or all
of the analyses should be present during the survey and be prepared to
discuss all aspects of their operations. Records and bench sheets should
be available for inspection and a statistical summary prepared to show the
number of tests performed, types of procedures used, and types of water
samples examined each month.
The survey officer is responsible for examining procedures and equip-
ment in detail to determine their compliance with Standard Methods or
other acceptable laboratory practices. The survey officer is expected to
explain any deficiencies observed in the records, such as insufficient
samples per month, inadequate sampling of the distribution network,
sample transit time, and response to unsatisfactory samples. When tech-
nical procedures are questionable, the consultant should explain the
deviation and demonstrate the proper procedure—and should also be
prepared to offer assistance concerning economics relating to testing
time, available bench space, utilities, commercial media, presterilized
and disposable items, and instrumentation aids.
It is hoped that the execution of these responsibilities will result in a
rapport between the laboratory staff and consultant that will motivate an
open discussion beneficial to everyone.
USING THE SURVEY FORM
Systematic coverage of the many technical procedures, equipment
items, chemical reagents, media requirements, and allied activities that
are essential elements of the water laboratory can best be reviewed
through the use of a survey form. Rather than considering the survey form
as a check list of laboratory activities, it should serve as a guideline to the
creation of a specific description of the laboratory and its functions, work
load, and deficiencies.
The bacteriological survey form should be filled out during the labora-
tory program review. Each item should be investigated as to its applica-
tion, be it obvious or not. The marking code consists of an "X" for
deviation, an "O" for an item that does not apply to the laboratory being
reviewed, and a "U" for items not determined. These marks should be
6 Evaluating Water Bacteriology LaboratoriesIGetdreich
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placed in the space provided adjacent to the appropriate item. During the
program review, the survey officer will find it desirable to check-off the
items as they are observed since it is often more convenient to follow the
daily laboratory routine rather than to follow the order given on the
survey form. All information requested, such as number of tests per year
for each procedure, media lot numbers, and brand and model of equip-
ment should be entered in the appropriate space on the form.
All the information recorded on this survey form should be used to
formulate an oral report by the survey officer in a' 'wrap-up'' conference
held at the conclusion of the visit and to prepare a narrative report with
specific comments and recommendations. Remember, the intent of the
survey form is to serve as a guideline for complete coverage of the
laboratory activities and not as a grading sheet for answers supplied by
the laboratory staff.
REVIEW CONFERENCE
Each deviation observed during the laboratory evaluation should be
discussed at the time it is observed. The discussion should include the
deviation, its effect on the validity of results, remedial action, and reasons
justifying the change in procedures. The final portion of each laboratory
evaluation visit is devoted to an informal presentation of material to be
covered in the narrative report. Generally, these program reviews are
made to the laboratory director, chief bacteriologist in charge of the water
program, and a representative of the water supply engineering staff. The
presence of regional engineering staff members from the Federal water
programs should be encouraged whenever the evaluation involves public
water supply monitoring or water quality standards on interstate water-
ways.
Effective use of the time devoted to a review conference with the
laboratory director requires that the laboratory survey officer prepare
notes in a logical order for presentation. One suggested approach would
be to discuss related items in a systematic order, such as:
1. Sampling and monitoring response
2. Laboratory equipment and instrumentation
3. Laboratory materials preparation and sterilization
4. Media
5. Multiple tube procedures
6. Membrane filter procedures
7. Supplementary bacteriological methods
8. Quality control program
9. Data processing and records
10. Laboratory safety
11. Laboratory facilities and staff
12. Summary comments and recommendations
These comments should not only be presented in a clear, orderly fashion
but also be documented with illustrations from the records that under-
score specific deviations from acceptable practice.
INTRODUCTION 7
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REFERENCES
1. American Public Health Association, American Water Works Association, Water
Pollution Control Federation. Standard Methods for the Examination of Water and
Wastewater, 14th ed. American Public Health Association, Washington, D. C. (1975)
(In press).
2. U.S. Public Health Service. Drinking Water Standards. PHS Publ. No. 956 (1962).
3. Methods Development and Quality Assurance Research Laboratory. Methods for
Chemical Analysis of Water and Wastes. EPA-625/6-74-003, U.S. Environmental Pro-
tection Agency, Office of Technology Transfer, Washington, D.C. (1974).
4. Weber, C. I., ed. Biological Field and Laboratory Methods for Measuring the Quality of
Surface Waters and Effluents. EPA-670/4-73-001, U.S. Environmental Protection
Agency, Cincinnati, Ohio (July 1973).
5. Bordner, R. H., Scarpino, P. V., and Winter, J. A. Microbiological Methods for
Monitoring the Environment: I. Water and Waste Analyses. U.S. Environmental
Protection Agency (in preparation).
6. Geldreich, E. E. Status of Bacteriological Procedures Used by State and Municipal
Laboratories for Potable Water Examination. Health Lab. Sci. 4:9-16 (1967).
7. Geldreich, E. E. Application of lacteriological Data in Potable Water Surveillance.
Jour. Amer. Water Works Assoc. 63:225-229 (1971).
8. Water Supply Division. A Manual for the Evaluation of a State Drinking Water Supply
Program. EPA-430/9-74-009, U.S. Environmental Protection Agency, Washington,
D.C. (1974).
9. Geldreich, E. E., and Clark, H. F. Evaluation of Water Laboratories. PHS Publication
999-EE-l. Department of Health, Education, and Welfare, Washington, D.C. (1966).
10. Greenberg, A. E., Thomas, J. S., Lee, T. W., and Gaffey, W. R. Interlaboratory
Comparisons in Water Bacteriology. Jour. Amer. Water Works Assoc. 59:237-244
(1967).
11. Schaeffer, M., Widelock, D., Blatt, S., and Wilson, M. E. The Clinical Laboratory
Improvement Program in New York City. I. Methods of Evaluation and Results of
Performance Tests. Health Lab. Sci. 4:72-89 (1967).
12. Cada, R. L. Simulated Proficiency Test Specimens in Enteric Bacteriology. Health
Lab. Sci. 12:12-15 (1975).
13. Cada, R. L. Proficiency Test Specimens for Water Bacteriology. Appl. Microbiol.
29:255-259 (1975).
Evaluating Water Bacteriology Laboratories/Geidreich
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GUIDELINES ON EVALUATING LABORATORIES
Program Objectives
Improve quality of laboratory data _
Approve techniques based on current edition of Standard Methods or
generally acknowledged good laboratory practice _
Upgrade laboratory procedures so that data obtained in all laboratories
can become part of official record _
Minimize the number of deviations _
Laboratory Evaluation Service
Federal program evaluates Federal, state, and selected local laboratories
on a 3-year basis
State program evaluates all intra-state laboratories
State conducts survey on a year basis
State survey officer (Name)
Status of State laboratory evaluation service
Total:
labs known to examine water
approved laboratories
provisionally approved laboratories
nonapproved laboratories
Split sampling program supplements on-site survey
Conducting the Evaluation
Visit at mutually agreeable time unless laboratory is on a provisional
or prohibited status
Variety of water examinations scheduled during the survey
Water program staff available during the survey for discussion of procedures
Records, laboratory work sheets, and year summary of tests performed
available for inspection
Survey Officer's Responsibilities
Procedures and equipment used in the bacteriological examination
of water examined
Records for sampling frequency, sampling program, sample transit time,
and repeat sampling response inspected
Deviations in observed procedures discussed
Procedural changes, equipment and material needs, staffing requirements,
and facility improvements recommended, as necessary
Survey form filled out during the visit
Results of the laboratory evaluation reviewed in conference with the
Laboratory Director before concluding the visit
INTRODUCTION
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CHAPTER II
SAMPLING AND MONITORING RESPONSE
Essential links to meaningful laboratory data are the proper choice of
the sampling location, strict adherence to proper sampling procedures,
complete identification of the sample, and prompt transport of the sample
to the laboratory. Coupled with these restrictions is the problem of getting
a representative sample, be it potable water at various parts of the
distribution system, or representative samples of the typical effluent
quality of sewage or some industrial effluent.
The greatest obstacle to collection of a representative sample is in the
possible lack of homogenity. This problem is most pronounced in sam-
pling natural waters subjected to unpredictable inputs of storm water
runoff and to industrial effluents whose quality may fluctuate severely
because of varying industrial outputs or poorly managed treatment prac-
tices.
Even under the most favorable conditions, errors that relate to sam-
pling are usually much greater than those in laboratory analyses. Unless
samples are carefully selected and handled with care, taken at proper
locations, promptly transported and laboratory processed, the results of
these tests will be confusing, misleading, and detrimental to any monitor-
ing program.
POTABLE WATERS
Compliance with the bacteriological requirements as prescribed in the
Federal Drinking Water Standards must be based on a sampling program
that includes examination of the finished water and a selection of distribu-
tion samples so that a systematic coverage of the distribution network is
accomplished during each month. The essential consideration is the care-
ful choice of distribution sample locations including dead-end sections to
demonstrate that bacteriological quality is uniformly satisfactory
throughout the network and to ensure that localized contamination does
not occur through cross-connections, breaks in the distribution lines, or
reduction in positive pressure. Sample locations may be public sites
(police and fire stations, government office buildings, schools, bus and
train stations, airports, community parks), commercial establishments
(restaurants, gas stations, office buildings, industrial plants), private resi-
dences (single residences, apartment buildings, and townhouse complex-
es) and special sampling stations built into the distribution network. The
establishment of an effective sampling program should be the joint re-
sponsibility of a local administrator (the water plant operator, health
officer, or municipal engineer), the appropriate state engineering pro-
gram, and the regional water supply representative of the EPA.
Sampling frequency, established by the Federal Drinking Water Stand-
ards, is based on a minimum monthly number requirement that is related
SAMPLING AND MONITORING RESPONSE 11
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to the population served by a given water supply. Thus, fewer bac-
teriological samples are required from smaller supplies. Ironically, the
water systems serving populations of less than 50,000 people are more
prone to show unsatisfactory bacteriological results (1). Data collected in
1969 from the Community Water Supply Study (2) of 969 public water
supplies illustrate particular concern with bacteriological quality of pota-
ble supplies serving populations of 10,000 or less. Fifty percent of these
smaller supplies had a history of unsatisfactory bacteriological results.
The same study revealed that surveillance of 69 percent of the 969 water
supplies was limited to only half the minimum number of monthly samples
recommended by the Federal Drinking Water Standards; this reduced
surveillance resulted, in part, from insufficient personnel and program
funds.
Even though a sufficient number of monthly samples may be collected
from small distribution systems, studies of sample records indicate that
more than 75 percent of these required samples are taken from the same
locations: the municipal building, the laboratory tap, the residence of
some city official, and a favorite restaurant or tavern. Only occasional
attempts may be made to obtain other samples that would more meaning-
fully measure water quality throughout the entire distribution system (1).
It may be necessary to increase the number and location of monthly
samples where supplies serve populations under 25,000 so that the entire
network will be adequately monitored. Factors that must be considered in
any modification of the sampling requirements include: frequency of
unsatisfactory samples from supplies serving various population levels,
repeat sampling and the time interval for repeat sampling, impact of peak
water usage as related to seasonal shifts in populations, adequacy of
treatment plant capacity, proper sampling of the distribution system,
sample transit time to the laboratory, chlorine dosage, and raw water
quality (some raw-water sources consistently contain more than 1,000
fecal coliforms per 100 ml).
NATURAL RECREATIONAL WATERS
Sampling locations for recreational areas should reflect the water qual-
ity within the entire recreational zone. Selected sites should include
upstream peripheral areas and locations adjacent to drains or natural
contours that would discharge stormwater collections or possible septic
wastes from public restrooms, recreational buildings, and boat marinas.
Sample collections taken in the swimming area should be obtained from a
uniform depth of approximately 3 feet. Analysis of data taken from a
series of small recreational lakes indicated that sampling depths of 3 and 6
feet did not produce any significant difference in bacteriological quality.
Base-line data on estuarine bathing water quality must include sam-
pling at low tide, high tide and ebbtide. This initially intense sampling
program will determine if any cyclic water quality deterioration occurs
that must be controlled during the recreational season.
Sampling frequency should relate directly to the peak bathing period,
which generally occurs in the afternoon. Preferably, daily samples should
be collected during the recognized bathing season; minimum sampling
should include Friday, Saturday, Sunday, and holidays—the periods of
12 Evaluating Water Bacteriology Laboratories/Geldreich
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greatest recreational use. When limiting sampling to days of peak recrea-
tional use, a morning and afternoon sampling is desirable, particularly if
the closing of bathing beaches is to be enforced on the basis of bacteriolog-
ical quality of the water.
STREAM POLLUTION
Stream studies may be short-term high-intensity efforts involving the
collection of substantial amounts of data on the variety of water quality
criteria needed for some enforcement action. Choice of bacteriological
sampling locations should include a base-line location upstream from the
study area, industrial and municipal waste outfalls into the main stream
study area, tributaries with a flow greater than 10 percent of the main
stream, intake points for municipal water treatment plants and industrial
needs, in addition to stream flow-time intervals and downstream recrea-
tional areas. Dispersion of effluents into the receiving stream may neces-
sitate preliminary cross section studies to determine the completeness of
mixing before final selection of sample stations (3). Where a tributary
stream is involved, the sampling point should be near the confluence with
the main stream; care must be taken not to sample backflow from the main
stream. Sample collections are generally made from a boat or from
bridges near critical study points. Locating sampling stations at the water
treatment plant for collection of raw intake water may be useful but could
yield lower bacterial densities than at the in-stream intake point when a
raw water holding basin supply is, in fact, being measured. Frequency of
sampling during a special field investigation of stream pollution should
reflect conditions during normal industrial plant operation as well as
during nonoperating hours, if possible. This can be accomplished by
sampling every 4 to 6 hours and timing the same series to monitor slugs of
pollutional discharges at each downstream location. Sampling intervals
should be advanced 1 hour each day and be continued over a 7- to 10-day
period.
Monitoring stream and lake water quality involves the establishment of
sampling locations at critical sites that have been shown to reflect overall
water quality. These sampling stations should be chosen with care since
the resultant data may be used as base-line information on existing water
qualities and as an early alert to the need for special field investigations
involving specific polluters or waste treatment deficiencies. Sampling
frequency for monitoring stations may be seasonal for recreational wa-
ters, daily for water supply intake to the treatment plant, hourly where
waste treatment control is erratic and effluents are discharged into
shellfish harvesting areas, and continuous, if in the future, reuse water is
used for potable water.
SEDIMENTS AND SLUDGES
An important aspect of long-term water quality conditions occurring in
water supply reservoirs, in lakes, rivers and coastal waters for recrea-
tional purposes, and in shellfish growing waters may be found in the
bacteriology of bottom sediments. These sediment deposits may provide
a stable index of the general quality of the overlying water, particularly
where there is great variability in the bacterial quality of the water (4).
SAMPLING AND MONITORING RESPONSE 13
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Sampling frequency in reservoirs and lakes may be found to be related
more to seasonal changes in water temperatures that cause overturn of
stratified layers of differing water qualities. Bottom sediment changes in
river and estuarine waters may be more erratic, being influenced by
stormwater runoff, increased flow velocities, and sudden changes in the
quality of effluent discharges.
Bacteriological examination of sludges from either water or sewage
treatment processes are desirable to determine the impact of their dis-
posal into receiving waters, ocean dumping, or burial in land-fill opera-
tions. Monitoring the bacteriological quality of sludge may also indicate
the effectiveness of sewage treatment processes. Since the quality of
sludges is subject to variations reflected in changes occurring in sewage
composition and treatment responses, sampling frequency for this mate-
rial may possibly better correlate with substantial changes in the biochem-
ical oxygen demand in the effluent.
REPRESENTATIVE SAMPLES
Care must be exercised to collect samples representative of the water to
be tested and to ensure that the sample does not become contaminated at
the time of collection or before examination. Sterile sample bottles for
bacteriological analysis must remain closed until the moment the sample
is taken. At this time, ground glass stopper or screw cap and protective
cover are then carefully removed. During the collecting procedure, care
must be taken to avoid contact with the inner part of the closure or
accidentally placing the closure on some dirty surface. The bottle is
grasped at the base and filled nearly full without rinsing; ample air space is
left for sample mixing. The closure should be replaced immediately and
the protective cover, if employed, resecured around the bottle neck for
additional protection. At this point, the sample must be properly iden-
tified or labeled, then placed in the appropriate container for delivery to
the laboratory.
Ample Air Space
Adsorption of bacteria to particulate matter or to the inner surface of
the sample bottle can occur between collection and examination of sam-
ple. Therefore, an ample air space must be left in the sample bottle at time
of collection to permit adequate mixing for a resuspension of the bacterial
population. Under no circumstance should the bacteriologist decant part
of the sample in a full bottle to facilitate better mixing. This undesirable
practice changes the bacterial density per unit volume and contributes to
inaccurate bacteriological measurements. Samples without sufficient air
space should be rejected, and a request should be made for a repeat
sampling from that location. If this is not possible, carefully pour the
entire sample into a larger sterile bottle and vigorously shake for complete
mixing.
Minimum Sample Size
Fe
14
Evaluating Water Bacteriology LaboratoriesIGeldreich
The minimum official sample volume cited in earlier editions of the
Federal Drinking Water Standards and Standard Methods was either
-------�
stated or implied to be 50 ml. This volume is necessary to inoculate each
of a series of five lactose broth fermentation tubes with 10-ml portions of a
potable water sample. Few laboratories routinely inoculate 100-ml por-
tions in the multiple tube procedure because of the problems of preparing,
handling, and incubating bottles large enough to culture 100-ml sample
portions. The minimum sample volume collected for analysis from all
classes of water, ranging from potable supplies, to stream, estuarine, and
coastal waters, should be 100 ml, irrespective of the small volumes of
sample actually utilized. Where special studies involve analyses for sev-
eral bacterial indicators and a search for pathogens, the total sample
volumes may involve 500 ml or more in a single sampling. Sample con-
centration techniques may be necessary where attempts are made to
detect low levels of pathogen occurrences in water. Mack et at. (5)
reported isolating poliovirus type II from a restaurant well-water supply
only after 2.5-gallon samples were flocculated prior to centrifuging to
concentrate the low density virus particles. Coliform organisms were also
detected in the concentrates. Neither virus nor coliforms were detected in
50 ml portions of the unconcentrated water sample. Future studies relat-
ing to coliform to virus occurrences in potable water may suggest the
desirability of establishing a coliform standard based on 1-liter sample
examinations (6). This requirement would increase the base-line sensitiv-
ity and could be particularly important for measuring coliform reduction
resulting from the application of disinfectants at rates approaching those
essential for control of waterborne virus. However, routine bacteriologi-
cal examinations of potable water presently utilize 50-ml volumes for the
multiple tube test or 100-ml portions for the MF technique. Water quality
surveillance of streams and estuaries frequently requires smaller test
volumes because of significantly higher bacterial densities.
Sample Collecting Procedures
When samples must be hand collected directly from an estuary, river,
stream, lake, or reservoir, by wading-in for near-shore samples or from a
small boat, the procedure is to grasp the open bottle near its base and
plunge it, neck downward below the surface. The bottle should then be
turned until the neck points slightly upward, the mouth being directed
toward the current. If no current exists, as in a reservoir, a current should
be artificially created by pushing the bottle horizontally forward in a
direction away from the hand. When sampling from a boat, samples
should be obtained from the upstream side of the boat. When sampling
from a bridge or large boat, the sterilized sample bottle should be placed in
a weighted frame that holds the bottle securely. The sample bottle is then
opened and lowered into the water by a small diameter rope or nylon cord
without dislodging dirt or other material from the bridge that might fall
into the open bottle. As the bottle nears the water surface, the mouth of
the bottle is oriented to face upstream by swinging the sampler
downstream under the bridge and dropping the unit quickly into the water
without excessive slack in the rope. Too much slack in the rope may
permit the submerging sample bottle to reach bottom and pick up mud or
be broken from impact on submerged rocks. After the bottle is partially
filled, the sampler is pulled upstream and out of the water, simulating the
SAMPLING AND MONITORING RESPONSE 15
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scooping motion of sampling by hand. Water samples collected from a
well, either by mechanical or hand pumping, must be drawn and wasted
for several minutes before the sample is collected. The procedure ensures
that water in the well field is sampled and not the standing water in the
pump. An additional advantage is that contaminants that might have
entered the area of the tap are flushed away.
Potable water samples must be representative of the water quality
within a given segment of the distribution network; therefore, taps
selected for sample collection must be supplied with water from a service
pipe connected directly with the main rather than to a storage tank. The
sampling tap must be protected from exterior contamination associated
with being too close to the sink bottom or to the ground. Contaminated
water or soil from the faucet exterior may enter the bottle during the
collecting procedure since it is difficult to place a bottle underneath a low
tap without grazing the neck interior against the outside faucet surface.
Leaking taps that allow water to flow out from around the stem of the
valve handle and down the outside of the faucet or taps in which water
tends to run up on the outside of the lip are to be avoided as sampling
outlets. Aerator, strainer, and hose attachments on the tap must be
removed before sampling. These devices can harbor a significant bacte-
rial population if they are not cleaned routinely or replaced when worn or
cracked. Whenever an even stream of water cannot be obtained from taps
after such devices are removed, a more suitable tap must be sought. Taps
whose water flow is not steady should be avoided because temporary
fluctuation in line pressure may cause sheets of microbial growth that are
lodged in some pipe section or faucet connection to break loose. The
chosen cold water tap should be opened for 2 or 3 minutes or for sufficient
time to permit clearing the service line; a smooth-flowing water stream at
moderate pressure without splashing should be obtained. Then, without
changing the waterflow, which could dislodge some particles in the
faucet, sample collection can proceed.
When glass bottles fitted with ground-glass stoppers are used, a string
or paper wedge must be inserted between the bottle and closure before
sterilization to facilitate easy opening during sample collection. Upon
opening the bottle, discard the string or paper wedge without touching the
inner portion of either the bottle or stopper. Reinserting this item into the
sample bottle after sample collection will increase the risk of water
sample contamination.
Regardless of the type of sample bottle closure used, do not lay the
bottle cap down or put it in a pocket. Rather, hold the bottle in one hand
and the cap in the other, keeping the bottle cap right side up (threads
down) and using care not to touch the inside of the cap. Likewise, avoid
contaminating the sterile bottle with fingers or permitting the faucet to
touch the inside of the bottle. The bottle should not be rinsed or wiped out
or blown out by the sample collector's breath before use. Such practices
may not only contaminate the bottle but remove the thiosulfate de-
chlorinating agent. During the filling operation, be careful so splashing
drops of water from the ground or sink do not enter into either the bottle or
cap. Do not adjust the stream flow while sampling in order to avoid
dislodging some particles in the faucet. Fill the bottle to within 1 inch of
16 Evaluating Water Bacteriology Laboratories/Geldreich
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the bottle top or to the shoulder of the container; cap the bottle imme-
diately. The tap is then turned off.
Flaming Tap Myth
Treating water taps before collecting potable water samples is not
necessary if reasonable care is exercised in the choice of sampling tap
(clean, free of attachments, and in good repair) and if the water is allowed
to flow adequately at a uniform rate before sampling. Alterations in the
valve setting to change the flow rate during collection could affect the
sample quality adversely. Superficially passing a flame from a match or an
alcohol-soaked cotton applicator over the tap a few times may have
psychological effect on observers, but it will not have a lethal effect on
attached bacteria. The application of intense heat with a blow torch may
damage the valve-washer seating or create a fire hazard to combustible
materials adjacent to the tap. If successive samples from the same tap
continue to contain coliforms, however, the tap should be disinfected
with a hypochlorite solution to eliminate external contamination as the
source of these organisms (7).
This negative position on a protocol for flaming taps before sample
collection is supported by several independent studies. Thomas et al., (8)
after a study of 253 samples from farm water supplies, reported that
flaming taps before sampling resulted in no significant differences in the
multiple tube test (5-tube MPN) for both total coliforms and fecal col-
iforms, nor in the standard plate counts incubated at 37° or 22°C. They
noted that there was a tendency for the bacterial content to be lower, but
the trend was not significant and could have occurred by chance. In a
second study involving 527 distribution samples collected without tap
flaming from the Chicago public water supply, only two samples (orO.4%)
contained coliforms (9). For a third study, water was flushed from taps
located in 76 gasoline service stations in Dayton, Ohio, but again, the taps
were not flamed or otherwise disinfected (10). The results showed no
coliform positive samples from 40 of the 76 stations, and MF coliform
counts in excess of 4 per 100 ml occurred in only 4 of the 10,916 samples
tested.
Dechlorinating and Chelating Additives
All water samples collected from chlorinated sources must be dechlori-
nated at time of collection (11,12). Unless residual chlorine is neutralized,
the bactericidal activity will continue and decrease the opportunity of
detecting any organisms that would indicate a possible contamination in
the potable water supply. Before sample bottles are sterilized, a sufficient
concentration of sodium thiosulfate is added to each bottle so that after
the appropriate volume of water sample is collected, there will be an
equivalent 100 mg dechlorinating agent per liter of water. Thus, 4-oz (125
ml) capacity sample bottles require the addition of 0.1 ml (2 drops) of a 10
percent solution of sodium thiosulfate to each bottle, since approximately
100 ml of water will be added during sampling. The use of 6-oz (180 ml) or
8-oz (250 ml) capacity sample bottles requires a proportional increase in
the amount of dechlorinating agent added. Excess amounts (greater than
0.4 ml of a 10 percent solution) of sodium thiosulfate should be avoided,
SAMPLING AND MONITORING RESPONSE 17
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since this may encourage bacterial aftergrowth in the standard plate count
and, thereby, alter the bacterial concentration in the sample during transit
to the laboratory. Sterilization temperatures evaporate the sodium
thiosulfate solution to dryness, leaving a thin white film of the de-
chlorinating agent available to combine with any residual chlorine in the
sample. Theoretically, 7.1 mg of sodium thiosulfate will completely de-
chlorinate 1 mg of chlorine. In practice, this ratio is as low as 2:1 because
of the effects on samples of temperature, excess light exposure, and
various oxidizing complexes possible in a given water sample.
Inspection of the 10 percent sodium thiosulfate solution, which is used
as the dechlorinating agent when preparing the sample bottles, should not
reveal the agent to be turbid, either from bacterial growth or from chemi-
cal decomposition. Any biological or chemical alteration of the dechlori-
nation agent may adversely affect the detection of some residual coliform
population in a marginally chlorinated potable water during sample transit
time to the laboratory. Therefore, sterilization of the dechlorinating rea-
gent, preferably prepared in quantities of 50 ml or less, and its subsequent
storage in the refrigerator is recommended to reduce the probability of
chance contamination.
Chelation of the water sample, as a method maintaining the coliform
density during transit, may be desirable in waters naturally containing
copper or zinc and in sewage or industrial wastes with high levels of heavy
metal ions. These heavy metal ions exert a toxic effect on bacteria and
may significantly decrease total and fecal coliform densities during transit
periods of 24 hours or more (13,14). Although some of the bactericidal
action of copper is prevented by adding 100 mg/1 sodium thiosulfate to the
sample bottle (15), broader chelation is attainable with ethylenediamine
tetraacetic acid (EOTA) at a concentration of 372 mg/1. Thus, it may be
desirable to prepare sample bottles with the dechlorinating compound,
sodium thiosulfate, and also the chelating agent EDTA. One suggested
approach is to prepare a mixed stock solution of the proper concentration
of both chemical agents and to add appropriate 0.1- to 0.5-ml quantities,
as required, to each sample bottle. Quantities of these chemical agents,
added separately or collectively, should not exceed 0.5 ml per bottle since
larger volumes will not evaporate to a dry residual during sterilization and
liquid residuals may be spilled out through inadvertent inversion of sam-
ple bottles during the collection procedure.
SAMPLE IDENTITY—LEGAL CONSIDERATIONS
It is imperative that all laboratory and field personnel recognize the
legal aspects associated with collecting either monitoring or surveillance
data that could become involved in an enforcement action. In particular,
custody of samples must be clearly established from the time samples are
taken until the evidence is introduced in court. Sample collectors re-
quested to appear in court must be prepared to state the time and date
samples were taken (including assignment of a sample number), identify
specific sampling locations, describe field tests performed (chlorine re-
sidual, water temperature, and water pH), and validate the sample collec-
tor's signature.
These critical requirements make it mandatory for the sample collector
18
Evaluating Water Bacteriology Laboratories/Geldreich
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to fill out a sample identification form immediately after each sample is
taken. A ballpoint pen (waterproof ink) should be used with ample pres-
sure to ensure that all multiple copy forms are legible. Print or write all
information clearly. Samples received in the laboratory accompanied by
illegible report forms or of questionable identity should not be processed.
Notation should be made by the sample collector of any special condi-
tions that may suggest contamination, so that laboratory personnel may
prepare proper dilutions to cover the range of possible bacterial concent-
ration. If the sample is part of a resampling program, such as a followup of
unsatisfactory potable water results, such information should be noted on
the sample identification form. This form must also include a sample
bottle identification number that is either permanently marked on each
bottle or added with a wax marking pencil or waterproof pen to the side of
the bottle. Marking an identification number on the sample bottle closure
is not desirable because closures can be inadvertently mixed during
sampling or processing in the laboratory.
Laboratory personnel must be responsible for the custody, care, and
processing of the sample upon arrival in the laboratory and, therefore,
must be prepared to testify to this protective trust in court, if necessary.
The laboratory should maintain a logbook to show registration of the
sample on receipt from the sample collector, including arrival time and
date and initials of the recorder. The laboratory record or worksheet and
the sample form submitted with the sample must include information on
the procedures performed and the results of the testing and must also be
signed and dated by the person performing the tests. Where selected
procedures deviate from recommended methods, the laboratory person-
nel, under cross examination, should be prepared to justify procedural
changes by presenting validation data that adequately establish equiva-
lency and sensitivity of the nonstandard tests employed.
SAMPLE TRANSIT FOR STREAM AND MARINE SAMPLES
All water samples, regardless of source, must be examined as soon as
possible after collection. Sample transit time is especially critical for
stream and marine pollution investigations or for monitoring these stream
and marine waters as part of a water quality surveillance program. Be-
cause few field studies are in an area adjacent to the laboratory facility, a
special courier service must be established to transport all samples to the
laboratory within a maximum 6-hour time period. Samples may be trans-
ported long distance via air freight in sturdy picnic coolers using prefro-
zeh chemical cold packs to maintain a 4° to 10°C temperature during
shipment. This procedure requires coordinated scheduling relating to
sample collection, transportation to the airport for shipping, available
flights, and transportation from the air terminal to the laboratory for
examination. Upon receipt in the laboratory, these samples must be
processed within 2 hours to ensure valid data (12,16).
If the sample transit time requirement for a specific field study pre-
cludes use of the central laboratory, other alternatives must be sought
such as: (a) acceptance of the samples for analyses by an approved
laboratory nearer to the study area, (b) examination of samples by an
approved water laboratory field kit brought to the field study site, (c)
SAMPLING AND MONITORING RESPONSE 19
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on-site bacteriological testing in a mobile laboratory, or (d) application of
the delayed incubation procedure for total coliforms (17) or fecal col-
iforms (18).
SAMPLE TRANSIT FOR POTABLE WATER SAMPLES
Sample transit time and water temperature variations during transport
continue to be a problem for central laboratories that must analyze
samples collected from distant water supplies. Transit time should never
exceed 48 hours, preferably no more than 30 hours. These potable water
samples should be refrigerated whenever a standard plate count is re-
quested or the water is suspected of being contaminated with pathogens.
Refrigerated samples held longer than 30 to 48 hours will be subject to
unpredictable increasing or decreasing bacterial densities. This problem
is amplified with the standard plate count because the general bacterial
population undergoes a more rapid change than the coliform density.
Insulated sample containers provide some protection against rapid
changes in the water sample temperature, and perhaps a thermos-type
container that can be sterilized should be considered. Another promising
approach is to package the sample in a container engineered to maintain a
pre-set temperature in the range of 4° to 10°C for 48 hours.
Changes in bacterial density, in addition to being related to storage
time-temperature effects, are influenced by the chemical composition,
pH, electrolyte concentration, protein nitrogen, bacterial flora, and other
undetermined factors associated with specific water sources. Bacterial
nutrients present in a given water may support significant bacterial mul-
tiplication during sample transit, particularly at temperatures above 13"C.
If storage time is prolonged, the bacterial population may completely
exhaust specific nutrients and begin a sharp die away. Thus, samples low
in bacterial nutrients and stored for long periods before examination may
have undergone a considerable reduction in the original bacterial density
because of die off.
Every effort must be made by sample collectors to time mail shipments
of drinking water samples with existing mail, truck, bus, or air schedules.
Sample collectors should avoid routine sampling on Thursday, Friday, or
any work day before a holiday. When samples must be tested at other than
regular working hours arrangements must be made with laboratory per-
sonnel. If the postal service is unacceptable, shipment by truck, bus, bank
clearing house service, or other alternate means of transportation should
be, investigated. For those water supplies located within 2 hours' driving
time of the laboratory, every effort should be made by the sample collec-
tor to bring sample collections directly to the laboratory rather than resort
to mail service. When samples are to be transported by car, delivery
should be done promptly and not postponed to some more convenient
time during the next few days. Transporting samples for several hours in
the high temperature of a car trunk or on the back seat of the automobile
during the summer can drastically alter the bacterial population.
In subtropical and tropical areas, special effort should be made by
sample collectors to refrigerate all potable and nonpotable water samples
during transit to the laboratory because of the warm water and air temper-
ature. Keeping water samples cool will retard changes in the bacterial
20 Evaluating Water Bacteriology Laboratories/Geldreich
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density and, thereby, yield laboratory results that are a more meaningful
measurement of water quality at time of collection.
Samples shipped by commercial carrier must be adequately protected
in suitable shipping cases to avoid breakage or spilling. Where sample
collections are made within a reasonable driving radius of the laboratory,
sample collectors may use large picnic coolers as sample cases with a 4° to
10°C temperature maintained through use of ice, dry ice, or prefrozen
chemical cold packs. If only ice is available as a refrigerant, it may be
necessary to modify the sample case by constructing a water-tight center
compartment to contain the ice and, thus, avoid any contamination of
water sample with melted ice. The laboratory staff should also be au-
thorized to reject any samples submerged in reservoirs of melted ice. This
requirement eliminates any doubt concerning the integrity of the col-
lected sample during transit.
Sample processing must be initiated within 2 hours of the arrival time.
Where laboratories receive samples throughout the day, the staff should
plan to process all morning samples by 11:00 a.m. and samples received
during the afternoon after 3:00 p.m. Late sample collection arrivals may
necessitate using some staff assistance from other laboratory sections to
complete initial processing by close of business. When samples are deliv-
ered too late to be examined during the regular work day, serious efforts
should be made to authorize personnel for overtime processing. Over-
night refrigeration of these late arrivals is a permissible alternative pro-
vided processing is done promptly the next morning. Under no cir-
cumstances, should samples be stored in the refrigerator during the
weekend for processing on the following work day.
UNSATISFACTORY BACTERIOLOGICAL REPORTS
When the bacteriological results from a sample indicate unsatisfactory
quality, additional samples from the same location must be examined at
daily intervals until two consecutive negative samples are secured. Such
special samples should not be included in the monthly total of routine
sample examinations required by the Federal Drinking Water Standards.
The laboratory should promptly report unsatisfactory sample results to
the engineering division and to the water plant operator so that an im-
mediate resampling program is initiated. Slow processing of positive
results by the laboratory or engineering records section of the water plant
defeats the efforts by the laboratory to maintain a rapid monitoring and
warning alert system on public water supplies. When repeat sampling is
initiated several days or weeks later, the opportunity is lost to further
verify coliform occurrence resulting from short-term water quality de-
terioration. Because further confirmation through repeat bacteriological
sampling is frequently lacking, it might lead to the belief that the positive
sample result was a "fluke." To counteract this misinterpretation of the
bacteriological results, the laboratory should further verify any positive
coliform findings found in samples from public water supplies.
Repeated occurrences of low numbers of coliforms (1 to 10 coliforms
per 100 ml) indicate chronic contamination in some portions of the dis-
tribution system due to cross-connections, negative pressures during fire
emergencies, distribution line deterioration, or inadequate treatment
SAMPLING AND MONITORING RESPONSE 21
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practices. These positive findings should be viewed as an early warning of
a break in the protective barrier against pathogen entrance into the
potable water supply. Since one waterborne outbreak occurs each month
somewhere in the United States (19), the detection of low coliform den-
sity levels should be given more consideration.
The recommended course of action is to thoroughly flush sections of
the distribution networks supplying water of unsatisfactory bacteriologi-
cal quality to free them from sediments and chemical deposits, then
chlorinate these mains to reduce the bacterial population. Sufficient
disinfectant should be added to the finished water as it leaves the water
treatment plant to maintain a chlorine residual (preferably ^ 0.3 mg/1 free
chlorine) throughout all sections of the distribution network. Booster
chlorinators at various points in the system may be needed to maintain
this residual. Developing a systematic program for monitoring the
chlorine residual and turbidity at representative points throughout the
distribution system is also desirable.
On samples that yield MF cultures covered with confluent growth of
bacterial colonies, resampling is recommended because the true coliform
density may be obscured. In addition to interfering with the development
of typical sheen colonies, large densities of nonspecific organisms may
inhibit coliform growth. Coliform colonies can occasionally be observed
even though there is confluent growth. If four or less coliform colonies are
observed under such conditions, a new sample should be requested from
the same sampling point since it must be determined whether or not the
coliform density exceeds the defined limit. If there are over four coliform
colonies, confluent growth or not, action must be taken in compliance
with the Federal Drinking Water Standards.
Quantitation of noncoliform colonies from the MF total coliform pro-
cedure is of uncertain specific interpretation because M-Endo medium
suppression of this nonspecific population approaches 95 to 99 percent.
However, these observations of excessive background growth do imply
that the general bacterial quality of that treated potable water is below
normal attainment by conventional treatment practices. Some of these
background organisms may be a factor in creating health problems among
the very young, the debilitated, and the aged individuals in a community.
In addition, high noncoliform populations in finished water are implicated
in suppressing coliform detection in both MF and MPN procedures. Such
observations are particularly relevant since the medium utilized to detect
coliform organisms in the MF procedure will suppress substantial num-
bers of the general bacterial population. Therefore, when excessive
background growth is observed on the MF total coliform test, the water
plant operator should be alerted to submit a special sample for standard
plate count examination. Standard plate counts in excess of 500 per 1 ml
should justify a recommendation to the water plant operator that the
cause of the excessive noncoliform populations be determined and ap-
propriate measures taken to reduce the bacterial density below the
suggested health limit. Remedial action may include line flushing to
remove accumulating sediments and chemical deposits, determination of
dead-end sections, and maintenance of 0.3 mg/1 free chlorine residual
throughout the distribution lines.
22 Evaluating Water Bacteriology Laboratories/Geldreich
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REFERENCES
I. Geldreich, E. E. Application of Bacteriological Data in Potable Water Surveillance.
Jour. Amer. Water Works Assoc. 63:225-229 (1971).
2. McCabe, L. J., Symons, J. M., Lee, R. D., and Robeck, G. G. Survey of Community
Water Supply Systems. Jour. Amer. Water Works Assoc. 62:670-687 (1970).
3. Kittrell, F. W. A Practical Guide to Water Quality Studies of Streams. Publication
CWR-5. FWPCA, U.S. Department of the Interior, Cincinnati, Ohio. 135 p. (1969).
4. Van Donsel, D. J., and Geldreich, E. E. Relationships of Salmonellae to Fecal Col-
iforms in Bottom Sediments. Water Research 5:1079-1087 (1971).
5. Mack, N. M., Lu, Y.-S., and Coohon, D. B. Isolation of Poliomyelitis Virus from a
Contaminated Well. Health Services Reports, 87:271-274, 1972.
6. Geldreich, E. E., and Clarke, N. A. The Coliform Test: A Criterion for the Viral Safety
of Water. Proc. 13th Water Quality Conference, College of Engineering, Univ. of
Illinois, Urbana. p. 103-113 (1971).
7. Buelow, R. W. and Walton, G. Bacteriological Quality vs. Residual Chlorine. Jour.
Amer. Water Works Assoc. 63:28-35 (1971).
8. Thomas, S. B., Scarlett, C. A., Cuthbert, W. A., el at. The Effect of Flaming of Taps
before Sampling of the Bacteriological Examination of Farm Water Supplies. Jour.
Appl. Bacteriol. 17:175-181 (1954).
9. McCabe, L. J. Trace Metals Content of Drinking Water from a Large System. Presented
at Symposium on Water Quality in Distribution Systems, Amer. Chem. Soc. National
Meeting, Minneapolis, Minn. (Apr. 13, 1969).
10. Walton, G. Personal communication (August 1970).
11. Thompson, R. E. Bacteriological Examination of Chlorinated Water. Water and Sew-
age 82:27-28, 40-46 (1944).
12. Public Health Laboratory Service Water Sub-Committee. The Effect of Sodium
Thiosulfate on the Coliform and Bacterium coli Counts of Non-Chlorinated Water
Samples. Jour. Hyg. 51:572-577 (1953).
13. Shipe, E. L., and Fields, A. Chelation as a Method for Maintaining the Coliform Index
in Water Samples. Pub. Health Repts. 71:974-978 (1956).
14. Coles, H. G. Ethylenediamine Tetra-acetic Acid and Sodium Thiosulphate as Protec-
tive Agents for Coliform Organisms in Water Samples Stored for One Day at Atmos-
pheric Temperature. Proc. Soc. Water Treat. Exam. 13:350-363 (1964).
15. Heather, R. C. The Effect of Thiosulphate and of Phosphate on the Bactericidal Action
of Copper and Zinc in Samples of Water. Jour. Appl. Bacteriol. 20:180-187 (1957).
16. Henson, E. B. Investigations on Storage and Preservation of Water Samples for
Microbiological Examination. Master of Science Thesis, Dept. of Civil and Environ-
mental Engineering Univ. of Cincinnati, Ohio (1971).
17. Geldreich, E. E., Kabler, P. W., Jeter, H. L., and Clark, H. F. A Delayed Incubation
Membrane Filter Test for Coliform Bacteria in Water. Amer. Jour. Pub. Health
45:1462-1474(1955).
18. Taylor, R. H., Bordner, R. H., and Scarpino, P. V. Delayed Incubation Membrane
Filter Test for Fecal Coliforms. Appl. Microbiol. 25:363-368 (1973).
19. Craun, S. F., and McCabe, L. J. Review of the Causes of Waterborne-Disease Out-
breaks. Jour. Amer. Water Works Assoc. 65:74-84 (1973).
SAMPLING AND MONITORING RESPONSE 23
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GUIDELINES ON SAMPLING AND MONITORING RESPONSE
Potable Water Sampling
Representative points selected on the distribution network
Sampling frequency adequate
Bathing Water Sampling
Sampling sites reflected water quality within the entire recreational zone ..
Sampling frequency related to peak activity periods during the
entire bathing season
Stream Pollution Sampling
Sampling sites within the study area included domestic and industrial
effluents, water supply intake, and recreational areas
Sampling program included a base-line location upstream of the study area
Sampling frequency reflected conditions during normal operating and
nonoperating hours for industrial plant operations
Sampling interval of 4 to 6 hours selected for short-term, 7- to 10-day studies
Stream and lake monitoring sites reflected overall water quality
Sample Collection
Care exercised in collecting representative samples
Sample collected with ample air space in bottle for mixing
Minimum sample size of 100 ml collected for all types of water samples ..
Stream sampling directed into the current and at least 6 inches below surface
Well water drawn to waste for several minutes before sampling
Municipal water tap protected from exterior contamination and free of
aerator, strainer, or hose attachment
Water tap sampled after maintaining a smooth flowing water stream for
2 to 3 minutes to clear service line
Taps with history of previous contamination disinfected with a
hypochlorite solution; flaming tap not necessary
Dechlorinating and Chelating Additives
Sodium thiosulfate added before bottle sterilization at a concentration of
100 mg per liter for sample dechlorination
Chelation agent for stream samples added before bottle sterilization at a
concentration of 372 mg per liter
Sample Identification
Sample bottle promptly and completely identified immediately after collection
Essential information included: water source, location, time and date of
collection, chlorine residual, and sample collector's initials
Sample Transit Time and Temperature Limits
Transit time for source waters, reservoirs, and natural bathing waters
should not exceed 6 hours
Transit time for potable water samples should not exceed 48 hours,
preferably within 30 hours
Mandatory sample refrigeration provided for all bathing waters, source
waters, effluents, and certain drinking waters to be examined for
standard plate count or pathogen occurrence
Optional sample refrigeration provided on routine collections of potable
waters for coliform analyses
Routine sample collections timed to meet existing mail, truck, bus,
or air schedules .
24 Evaluating Water Bacteriology Laboratories/Geldreich
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Sample collections delivered by car reached the laboratory promptly
All samples examined within 2 hours of arrival in the laboratory
Unsatisfactory Sample Response (Potable Waters)
Unsatisfactory sample defined as three or more positive tubes per MPN
test or four or more colonies per 100 ml in MF test
High priority placed on alerting operator to unsatisfactory
potable water results
Unsatisfactory samples resampled promptly
Special sample for standard plate count requested when more than 200
noncoliform colonies occur on Endo-type MF media
Water plant operator alerted to take appropriate control measures when
standard plant count exceeded 500 organisms per 1 ml
SAMPLING AND MONITORING RESPONSE 25
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CHAPTER III
LABORATORY APPARATUS
Basic laboratory apparatus must be of adequate quality to meet levels
of sensitivity, be reliable, and need only minimum service repairs to
correct mechanical failure or intolerable fluctuations in some critical
characteristic. Long-term laboratory equipment items should be of ap-
propriate capacity to meet the current needs during peak work periods
and also have an approximate 50 percent additional reserve capacity for
future needs. Choice of equipment to be purchased must relate to those
laboratory specifications essential to obtaining reliable test results rather
than to nonessential attractive features or to cost alone. Instruction
manuals should be carefully read by all technicians for proper understand-
ing of the equipment operation and be available in the laboratory files for
reference when service repairs or parts replacement information is re-
quired. Technicians should be familiar with basic rules in the operation of
delicate instruments, such as the microscope and analytical balance,
before approval for their use is granted. All laboratory personnel must
have a thorough understanding of operational controls and of properly
using drying ovens, glassware washing equipment, and autoclaves in an
effort to minimize laboratory accidents related to these equipment items.
AIR INCUBATION REQUIREMENTS
Incubator temperature control is essential to detect organisms of sani-
tary significance in water. Many bacteria in water are without sanitary
significance—they die rapidly in the aquatic environment, come from
various unknown sources, are widely distributed in the natural environ-
ment, or have no known or suspected association with human or other
animal wastes (1-9). Since the major emphasis has been on studies of
those species or groups of bacteria derived from contamination by animal
wastes, it is necessary to choose an incubation temperature favorable to
this specific bacterial segment of the water flora (4,10,11). Thus, the
choice of incubation temperature, the length of incubation time, and the
necessity for lactose fermentation within these conditions essentially
defines an indicator system. Any change in these criteria will redefine the
heterogenous collection of bacterial species included in the total coliform
bacteria and their sanitary significance.
Unpublished studies performed in our laboratory on a series of polluted
Ohio River samples indicate that lowering the incubation temperature
below 37°C progressively slows the rate of gas production. In parallel
most probable number tests using 20°, 25°, 30°, and 37°C incubation
temperatures, the rate and amount of gas production increased as the
incubation temperature increased. Recent published data (12) on agar
plate counts forEscherichia coli isolated from well water, sewage, night-
LABORATORY APPARATUS 27
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soil, and polluted fish indicate that 35°C incubation was the optimum
incubation temperature. The next best temperature forE. coli recovery
was 37°C; other temperatures investigated included 20°, 30° and 44°C.
Reducing the incubator temperature below 35°C increases the prob-
lems of interference and false positives associated with noncoliform
organisms common to well waters, lakes, and some small streams. False
positive results in the multiple tube confirmed test may originate from
several sources including anaerobic spore formers of the Clostridium
perfring ens type, spore-bearing aerobic forms related to Bacillus subtilis,
and the synergistic action of two different organisms neither of which
alone can ferment lactose. On the membrane filter, the so-called' 'paraco-
lon group" of organisms occurs as the most frequent false positive; they
produce a sheen reaction as a result of the partial breakdown of lactose. In
general, these organisms grow better at temperatures below 35°C. It
should be emphasized that any reduction in incubation temperature will
change the spectrum of organisms included in the indicator group for
water analysis.
Since incubator temperature tolerance must be accurately measured to
within ± 0.5°C of 35°C, all thermometers used in this application should
include 0.5°C scale divisions as a minimum requirement. Extrapolation of
readings on thermometers with only 1°C scale divisions is not sufficiently
accurate.
BENCH-TOP INCUBATORS
Bench-top incubators must have sufficient space to accommodate all
multiple tube tests or MF cultures during peak work periods. A daily
record (preferably a morning and afternoon reading) of the incubator
temperature is mandatory in the absence of a recording thermometer.
This record should include the date, temperature, and the initials of the
person logging the data. Any deviations greater than ± 0.5°C from the
35°C incubator temperature must be corrected by proper thermostat
adjustment. Maintaining daily incubator temperature records will also
alert laboratory personnel to any gradual temperature changes that may
reflect decreased stiffness of a new bi-metallic strip or possible metal
fatigue in an older bi-metallic element in the incubator thermostat.
Bench-top incubators should have sufficient insulation to protect the
inner chamber from room temperature fluctuations. Generally, water-
jacketed incubators are far superior to any others in this respect. Temper-
ature instability may, in part, relate to poor insulation in the non-water-
jacketed incubator construction and also to power conservation efforts
that include turn-off of air conditioning equipment in the laboratory
during evenings and over weekend periods. Periodic decreases in line
voltage can also affect optimum operation of the heater elements. Where
line voltage droppage is a serious problem, insertion of a.powerstat
variable transformer between the incubator and power outlet may be
necessary to improve supply voltage to the incubator heating elements.
Temperature instability may also be caused by locating incubators in or
near a window where sunlight or cold air drafts produce large temperature
fluctuations within a poorly insulated unit and increase the difficulty of
adjusting control settings on the heating elements. Ambient temperature
28 Evaluating Water Bacteriology Laboratories/Geldreich
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in rooms with temperature controlling equipment should be held within
the 65° to 80°F (18° to 27°C) range, and when exceeded, air conditioning of
the laboratory may be justified to reduce these incubator temperature
fluctuations.
Stratified temperatures and "hot spots" resulting from nonuniform
radiation may cause some shelf areas in the incubator to be at higher or
lower temperature than the temperature desired. Built-in thermometers
generally cannot be assumed to give accurate measurements of the aver-
age temperature in the chamber until their accuracy is verified by supple-
mental measurements made with accurately calibrated thermometers
placed on top and bottom shelves. For more accurate reading of chamber
temperature, thermometer bulbs must be continuously immersed in water
to provide buffering from sudden temperature changes when the in-
cubator door is opened.
Air incubation at 35°C produces a low-humidity environment and
adequate broth volume and agar substrates must be retained during
long-term incubation. Agar plates incubated 48 hours at 35°C should not
have more than a 15 percent weight loss through desiccation. Loss of
medium through evaporation causes unfavorable pH changes in broth
cultures that can suppress bacterial growth and result in the development
of small, poorly differentiated colonies on membrane filter surfaces.
Partially submerging a towl in a beaker of water increases humidity in the
incubation chamber. The wet towel acts as a wick and produces a large
evaporation surface. Slime or mold growth may occur on these towels, so
it is necessary to replace them once every other week to prevent such
undesirable problems. Some commercial incubators have a built-in water
reservoir on the bottom, inside each chamber, to aid in maintaining the
humidity at approximately 75 to 85 percent. These reservoirs must be
periodically filled with water to replenish water lost through evaporation.
A plastic vegetable crisper with a tight fitting lid and a wet towel placed on
the bottom may also be used to hold total coliform MF cultures; the filled
container is then placed in the 35°C incubator.
INCUBATOR ROOM
Room-size incubators require a more complex environmental control-
ling system than do bench-top units because of their physical size, the
requirements for temperature control within ± 0.5°C of a preselected
temperature, and maintenance of 75 to 85 percent relative humidity. The
optimum design requires a primary heating source and coarse control to
regulate the temperature between 30° and 40°C, and a secondary heating
source to generate small inputs of heat that will maintain a temperature ±
0.5°C of the preselected temperature, normally 35°C. These two separate
heat generators must be controlled by two different thermostats, with the
primary thermostat being designed to cut off the large heat output ele-
ments at approximately 32 to 33°C. Residual heat buildup should bring the
peak room temperature to about 34 to 35°C at which point the secondary
heat source is then activated by another thermostat to establish the final
temperature at 35° ± 0.5°C. If the temperature control is improperly
adjusted or defective and results in temperature excursions to 40°C, an
electronic temperature monitoring system should completely shut down
LABORATORY APPARATUS 29
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both heating circuits and activate an alarm system to alert personnel of
excessive temperature buildup in the unit.
In some instances, incubator rooms are designed that employ only a
single heat source and a blower to maintain and distribute heat similar to a
forced-air heating system. This approach is more economical but is also
subject to problems of excessive temperature variations that frequently
exceed the recommended tolerance of ± 0.5°C. Uniform distribution of
heat throughout the incubator room is essential. One approach places the
primary heating elements on opposite walls near the floor and secondary
heating elements on all three walls near the floor. Heat stratification can
be prevented by establishing a low-rate air flow through an appropriate air
exhaust system. This is best accomplished by constructing intake ports in
each wall near the floor close to the heating elements. An exhaust port
should be placed in the center of the ceiling with a low speed exhaust fan
installed to pull heated air continuously through all portions of the room
and then exit it through the exhaust port. High-rate exhaust or blower
systems cause increased media evaporation and lower the relative humid-
ity. To maintain the desired relative humidity (between 75 to 85 percent),
a controlled humidifying system may be necessary.
Shelf areas in the incubator must conform to 35° ± 0.5°C temperature
requirement. In addition to any recording thermometer installed in the
incubator room, thermometers, with their bulbs immersed in water, may
be placed at several locations in the shelf area. Recording thermometer
charts document the extent of temperature cycling and possible instabil-
ity and drift in the control system. When temperature records reveal a
persistent drift or excessive temperature cycling, action must be taken to
service the control circuit for pitted, arcing contact points; defective
by-pass condenser; or metal fatigue in bi-metallic strips.
ELEVATED TEMPERATURE INCUBATION REQUIREMENTS
Various procedures recommended for selective recovery of Salmonel-
la, rapid (7 hour) detection of fecal coliforms, and the Standard Methods'
fecal coliform procedure require incubation ranging from 41.5° to 44.5°C
depending on the specific test chosen. Precise temperature control is
essential since temperatures lower than those recommended will permit
the growth of many nonspecific organisms, and temperatures higher,
decrease the recovery of the desired pathogen or indicator group. Once
the test is prepared, the inoculated media should be brought to the desired
temperature within 10 to 15 minutes and held precisely within the recom-
mended range. For these reasons, incubation in a water bath or in a solid
heat sink incubator (such as aluminum) is desirable because precise
temperature control in these systems is more easily attained than it is in
air incubators.
Accurate temperature measurements are essential for elevated tem-
perature tests. A continuous temperature recorder sensitive to 0.2°C
changes should be used for a permanent record. In addition, an accurate
thermometer must be immersed in the water bath to spot check the
precision of the recorder tracings once each day. If recorder tracings are
inaccurate, the ink pen should be adjusted so that the temperature trac-
ings agree with comparative readings of the immersed thermometer. If a
Evaluating Water Bacteriology LaboratorieslGeldreich
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recording thermometer is not used to monitor water bath temperatures, a
daily record of temperature readings from an immersed thermometer or
digital electronic thermometer must be made.
Since water bath or heat sink block temperature tolerance must be
accurately measured to within ± 0.2° of 44.5°C, all thermometers used in
this application should include 0.1°C scale divisions as a minimum re-
quirement. Extrapolation of readings on thermometers with only 1° or
0.5°C scale divisions is not sufficiently accurate.
Circulating water baths or heat sink block incubators may not have to
be kept turned-on during nonuse periods of 72 hours or longer provided
the laboratory has established, through adequate data, that the desired
stable temperature can be achieved prior to time of use. Noncirculating
water baths must be left on at all times since stability in these units, at the
recommended temperature tolerance of ± 0.2°C, is marginal.
WATER BATH MAINTENANCE
Large bench-top water baths with gabled covers can effectively main-
tain a temperature of 44.5°C within ± 0.5°C. Temperature measurements
in these noncirculating water baths may reveal that some are capable of
temperature control within ± 0.2°C; others exhibit a slightly greater
deviation. These latter water baths can be brought to within ± 0.2°C
temperature tolerances by adding a low speed stirring motor to create a
gentle circulation of water to prevent heat stratification. Coarse tempera-
ture control and inadequate heat diffuser bottom plates may create more
severe temperature control problems.
Stainless-steel or plastic-coated baskets and racks should be used in
water baths to avoid problems of metal corrosion. Heavy deposits of rust
from baskets and tube racks made of ferrous material accumulating as
sediment in the water bath may act as a heat insulator and must be
removed. Adding a rust inhibitor to the water bath will reduce rust
formation. A water bath rust inhibitor may be prepared by dissolving 2
grams of potassium or sodium dichromate and 0.5 gram of sodium car-
bonate or 1.0 gram of sodium bicarbonate each in a little water and adding
to the water bath separately because a violent heat reaction occurs if both
compounds are added to water at the same time.
Water baths that develop a slime or fungal growth or that become
contaminated by accidental culture spills may be disinfected by adding 1
ml of a 10 percent Roccal solution (or equivalent organic quaternary
ammonium compound) per gallon of bath water or by adding liquid
laundry bleach at the rate of 1 tablespoon per 20 gallons of water (13).
After a 24-hour contact period, the water should then be drained from the
bath, and the bath should be flushed and refilled with distilled water.
MODIFYING SEROLOGY WATER BATHS
Large-size serology water baths with top covers may be converted to
incubators with the more exacting temperature requirements so neces-
sary for fecal coliform incubation (14). An electronic control relay, ther-
moregulator, water pump, and water intake diffusing pipe are needed.
The switching contacts of the electronic control relay must be rated at
1,650 watts or more to match the wattage demands of the heating elements
LABORATORY APPARATUS 31
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and be wired for 115 volts or 230 volts, depending upon the heating circuit
requirements. Response sensitivity of this electronic control relay should
be 250 microamps to match the characteristics of the thermoregulator.
Temperature range of the thermoregulator should be from 10° to 105°C
(50° to 220°F), with a sensitivity to changes of ± O.OTC (0.02°F).
Provisions for water circulation require external connection of a simple
centrifuge pump powered by a ^-horsepower electric motor. Tygon
tubing connects the water circulating pump to intake and discharge ports
on one side of the water bath chamber. The input port is connected to a
diffusing pipe made of %-inch-diameter poly vinyl chloride plastic pipe (or
other noncorrosive materials) with diffusion holes VB inch in diameter on
two sides at 2-inch intervals. For an alternative water circulation system,
submersible pumps may prove adequate if a gentle circulating water
current can be created. When water circulation is combined with an
adequate temperature controlling circuit, water temperature can be held
within a ± 0.1°C variation.
DRY HEAT STERILIZATION
Commercial-type ovens used to sterilize glassware items should be
checked to verify that the 170°C (338°F) sterilization temperature is
reached and is maintained within ± 10°C temperature change for a 2-hour
period. This is of particular concern where kitchen-appliance-type ovens
are adapted to laboratory use; dial control calibrations of these ovens are
frequently inaccurate and must be calibrated by an accurate thermome-
ter.
Since both time and temperature are interrelated in sterilization, all
appliance-type and laboratory-designed ovens should preferably include
an accurately calibrated recording thermometer for more precise timing
of the sterilization process. As a minimum requirement, however, a
long-stem thermometer of known accuracy in the range of 160° to 180°C
should be inserted through a center ceiling port, with the bulb inserted
into a cylinder (e.g., 25-ml graduated) filled with fine sand and
positioned on the center shelf in the sterilization chamber. Immersion of
the bulb in a small container of sand will better simulate average tempera-
ture conditions in pipette or petri dish containers and in thick-walled glass
sample bottles. The sand acts as a buffer against sudden temperature
changes when the oven door is opened and permits more accurate calibra-
tion of the oven sterilization temperature following the recommended
2-hour sterilization period. Additionally, the sand prevents rapid temper-
ature fluctuations that cause the mercury column to suddenly contract
over a large section of the capillary and thereby increase the chance of
introducing air-space separations in the mercury and loss of
temperature-measuring accuracy.
A long-stemmed thermometer is necessary—the bulb is located near
the center of the sterilization chamber and the upper portion of the scale,
in the range of 150° to 200°C, is visible outside the oven for temperature
readings while the oven doors are closed. To protect the thermometer
from breakage, the top of the oven should not be used as a storage area.
Likewise, care should be exercised during loading of the oven so that the
bulb portion of the thermometer in the sterilizing chamber is not similarly
Evaluating Water Bacteriology LaboratoriesIGeldreich
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broken. Repeated breakage of thermometer bulbs may be a result of
operator carelessness or overloading the ovens with items to be sterilized.
The oven must be of sufficient size to prevent crowding of the interior.
AUTOCLAVES
Autoclaves are essential for preparing many sterile items including
bacteriological media, sample bottles, and membrane filter equipment, as
well as for decontaminating test culture discards. This equipment should
be of adequate capacity to prevent crowding the interior, which would
result in ineffectual sterilization of some items in baskets or trays packed
tightly together.
The chamber of the autoclave should be equipped with an accurate
thermometer with bulb properly located in the exhaust line so that it
registers the minimum temperature in the sterilizing chamber. Pressure
gage readings generally correlate with sterilization temperatures, but
must not be used as a sterilization guide because certain variables can
distort this relationship, such as incomplete exhaustion of all air in the
chamber. Therefore, the sterilization period should correlate, primarily,
with that time when the necessary chamber temperature plateau is
achieved.
The use of the recording thermometer built into the automatic auto-
clave provides essential information related to rate of initial temperature
acceleration, maximum temperature achieved, constancy of sterilization
temperature during predetermined time period, rapidity of exhaust, and
total exposure time during the complete sterilization cycle. This record is
important in evaluating effects on sterilization of various carbohydrate
media and in detecting unsatisfactory changes in automatic cycles and
impending equipment failure. Such records, developed from the appro-
priate daily or weekly charts recommended for the specific recorder,
should be dated and type of material autoclaved identified for each
specific sterilization cycle, then stored for possible reference use over a
minimum of 2 years. Retention of these records is necessary in the event
such evidence is needed in future laboratory evaluation studies or in
disputes on health risks related to decontamination procedures for micro-
biologically hazardous material discards.
Vertical autoclaves and household pressure cookers may be used in
emergency service if equipped with pressure gages and thermometers
with bulbs positioned 1 inch above the water level. However, they are not
to be considered the equivalent of the general purpose steam sterilizer
recommended for permanent laboratory facilities. Their small size is
inadequate for large-volume work loads, and they can be difficult to
regulate.
Labeling tapes with heat-sensitive color changing inks, heat-sensitive
crayons, or other materials that change color or physical state are useful
for autoclave control procedures. Heat resistant spore suspensions of
Bacillus stearothermophilus in culture medium that are killed only when
exposed to 121°Cfor 15 minutes (15,16)alsoprovideapositivecontrolon
autoclave procedures when the spores are incorporated into culture
media. These sterilization indicators should be used each time the auto-
clave is operated. Placing sterilization indicators in the central area of a
LABORATORY APPARATUS 33
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large load of materials to be sterilized will monitor heat penetration to the
most protected items.
Steam for the autoclave may be supplied from a saturated steam line, or
from gas, or from an electrically heated steam generator incorporated in
the equipment item. Autoclaves connected to a building supply of satu-
rated steam usually reach sterilization temperature more quickly than
autoclaves that require an accessory steam generator. Poorly regulated
steam pressure may come from electric steam generators or autoclave
chambers that heat slowly because portions of the heating elements fail or
because the units are of insufficient wattage to generate an adequate
steam supply. Similar difficulties may occur with gas-fired steam
generators that are poorly adjusted or that are equipped with jets not
designed for use with the commercial gas available in the community.
Autoclaves must receive periodic inspection and preventive mainte-
nance. Drains in the autoclave chamber can become clogged from spills
and boil-over of materials during sterilization. The drain should have a
screen cover to retain coagulated wastes that block liquids. Gaskets
around the door crystallize and crack with age, and temperature and
pressure dials can have broken protective dial faces and damaged instru-
ment pointers. Some laboratories have been found using ancient auto-
claves that are no longer manufactured. Replacement parts for these
deteriorating units are not always available, and substitute parts may or
may not be adequate for the specific unit. In the event an older unit or a
unit of unknown manufacture cannot be properly brought up to accepta-
ble safety standards, a new autoclave should be purchased. Serious
accidents have occurred from malfunctioning autoclaves exploding and
from ruptured steam fittings.
LABORATORY THERMOMETERS
The accuracy of all thermometers routinely used to monitor tempera-
tures in incubators, water baths, hot-air sterilizing ovens, and autoclaves
must be verified by comparing their readings with readings of a National
Bureau of Standards (NBS) certified thermometer or one of equivalent
accuracy. Preferably, every laboratory should own an NBS certified
thermometer set because of the importance of exact temperature control.
Certified thermometers are expensive items that must be carefully
protected during use or while in storage to avoid breakage or separation of
the mercury column. Each certified unit has its plot of accuracy enclosed
with the NBS certificate of acceptance; this information is critical for use
in establishing precise temperature measurements and calibration of
routine thermometers under test. If the certification sheet with a plot of
calibration corrections has been lost, it will be necessary to request a
reissue of the certification plot for that specific thermometer from the
NBS or to submit a set of selected thermometers to that organization for
calibration at temperatures commonly used in the laboratory. When this
latter service is requested, selected calibration points should include
temperatures most commonly used, such as 5°C, 20°C, 35°C, 44.5°C,
121°C, and 170°C. Thermometer stem length is important in a calibration
thermometer so that divisions of 0.1°C can be easily read. However, there
is one disadvantage to long-stem thermometers in that any irregularities in
34 Evaluating Water Bacteriology Laboratories/Geldreich
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the mercury column bore will be reflected in drift from precise measure-
ments. Therefore, when temperatures of a wide range of values must be
calibrated, it may be more desirable to have several calibrated ther-
mometers of limited overall range rather than one unit to cover a wide
range of values.
Occasionally, in every laboratory, thermometers break and must be
replaced with new units. Replacement thermometers should be verified
for accuracy within the minimum and maximum range of intended use
since thermometer accuracy is not uniform over the entire stem length.
All "in-use" thermometers should be rechecked periodically for de-
velopment of hairline breaks in mercury columns that decrease measuring
accuracy. Air space separations can be eliminated by carefully submers-
ing the thermometer in high- and low-temperature water baths, taking
care that the maximum temperature does not exceed the thermometer
range. Thermometers with poorly legible graduation marks should be
discarded.
pH METER
Laboratory pH measurements must be made with an electronic instru-
ment capable of direct readings within ± 0.1 pH units. Models with tube
circuits are subject to occasional service problems related to tube failure.
The problems range from poor electronic emission, gas build-up, and
internal noise to heater element failures. Preventive maintenance should
include a periodic check of tube characteristics with the use of a mutual
conductance tube tester if available; otherwise, new tube substitution
should be made when the pH meter response becomes questionable.
Newer models of pH meters are built with solid state devices that are
more reliable than tube circuits but that require professional electronic
repair service if they become faulty. The problem frequently relates to
defective electrolytic condensers or resistors that change values and that
may, in turn, affect the operational characteristics of transistors and
result in transistor breakdown.
Electrodes may also become defective at the thin-walled tip and cause
erratic performance; therefore, a spare replacement electrode should
always be available. The calomel electrode must be maintained with a full
reservoir of saturated potassium chloride solution at all times so that pH
standardization and subsequent meter readings do not become erratic.
When not in use, electrode tips should be immersed in a small beaker of
distilled water to prevent them from becoming dry and caked with potas-
sium chloride crystals. Loss of potassium chloride in the electrode
chamber can be controlled during storage by inserting the rubber plug at
the filling port and using the rubber cap over the electrode tip to retard the
slow bleeding of saturated potassium chloride through the fiber element in
the tip. Of course, during periods of operation, it will be necessary to
remove both the rubber cap and plug from the electrode to permit test
solution contact and to equalize liquid pressures. The same general pre-
cautions described above apply to pH meters using combination elec-
trodes.
If erratic meter readings are observed when the hand is held near the
electrode, check the electrical grounding system for the instrument. Poor
LABORATORY APPARATUS 35
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grounding or the lack of instrument grounding will cause instability be-
cause of a hand capacitance effect on the instrument. Placing pH meters
on metal table tops can also cause a similar inductive capacitance inter-
ference. Although placing the instrument on a thick nonmetal stand above
the metal surface may help, it is generally more desirable to move the
instrument to another table with a nonmetal working surface.
Colorimetric pH methods are not acceptable in the bacteriological
laboratory because it is impossible to make pH determinations of strongly
colored solutions such as brilliant green lactose bile (BGLB) broth or
M-Endo MF medium.
BALANCE
Media preparation requires a balance capable of weighing several
hundred grams or more. For this purpose, each laboratory should have a
torsion type balance or trip pan balance with a sensitivity of better than 2
grams per 150 gram load. Such balances may have all or part of the
weights built into the system or weights may be added separately in a
counterbalance pan. Balance weights should be kept in a protective box
when not in use, free from chemical spills, and handled only by the
forceps supplied to ensure continued weighing accuracy through years of
usage.
Care should be taken to avoid sudden jolts or jarring during weighing
procedures to protect the delicate knife edge on the balance point. Always
lock the balance before moving it to some new operating position, use a
cover where possible to protect the instrument from dust, and avoid
spilling dehydrated media on the mechanism. Many of the dehydrated
bacteriological media are very hydroscopic and can cause erratic dam-
pening of the balance point during zero balance or weighing operations.
An analytical balance with 1-mg sensitivity at 10-gram load is used for
weighing media additives, reagents, dyes, etc., which are added in
amounts less than 2 grams. This type of sensitive balance must be pro-
tected from vibrations, dust, and wind currents generated by heating/
cooling ventilation systems, or areas of busy laboratory traffic. Because
this is a very delicate instrument, actual use of the analytical balance
should be limited to staff members who have demonstrated a thorough
knowledge of its proper operation and care. An annual preventive
maintenance program of balance adjustment, cleaning, and repair by a
qualified instrumentation-service organization should be established by
every laboratory.
MICROSCOPE AND LIGHT SOURCE
MF colonies are best counted using 10 x to 15 x magnification. A
binocular, wide-field dissecting microscope is recommended as the best
optical system. Use of a reading lens for this purpose is ineffective
because the low magnification power does endanger properly detecting
small colonies and defining numbers of differentiated colonies occurring
in clumps of confluent growth. Examination of MF total coliform cultures
with the unaided eye is not recommended because small sheen colonies or
those with a faint or atypical sheen may go undetected.
The golden metallic luster of coliform colonies, the blue colonies of
36 Evaluating Water Bacteriology LaboratoriesIGeldreich
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fecal coliforms, the red colonies of fecal streptococci, and various other
differentiated colonies on other selective media are best observed with
diffused daylight developed from cool-white fluorescent lamps, with the
light source adjusted to an angle of 60° to 80° above the MF culture (17).
Low-angle lighting must be used on MF cultures growing on nonspecific
growth media without indicator systems. On these general growth-type
media, nonpigmented colonies appear gray-white and require shadow-
contrasting to aid their detection on the gray-white MF surface.
A fluorescent light source consisting of two 4-watt daylight tubes
mounted on a flexible arm attached to a heavy cast base is recommended
for MF colony illumination. High-intensity incandescent illumination
commonly used with oil immersion microscopes or the low-intensity
incandescent light produced by an illuminating flashlight magnifier are
not adequate for colony sheen observations on Endo-type media. Confu-
sion over colony appearance may lead to errors in differentiated colony
counts.
COLONY COUNTER
Accurate and standardized counting of colonies on pour plates requires
a special device with adequate back lighting. Some colonies are difficult
to detect when viewed by top lighting but are readily seen when illumi-
nated by a uniform intensity, transmitted light. A large-diameter mag-
nifier of approximately 2 power is necessary not only to see the smallest
colonies but also to distinguish pin-point colonies from particles of dis-
solved medium or precipitated matter in the agar. A Wolfhiigel guide plate
or other grid plate of crisscross lines is essential for guiding the eye in
scanning an agar plate culture and for ensuring systematic coverage
without inducing overlapping colony counts. These requirements are met
by the Quebec colony counter, preferably the dark-field model that re-
veals colonies of bacteria clearly against a dark background.
INOCULATING EQUIPMENT
Transfer of bacteriological growth from broth, agar, and MF cultures to
some secondary medium or to a microscope slide requires the use of
several different types of inoculating aids. In the multiple tube confirmed
test, culture transfers from positive presumptive tubes are usually per-
formed with an American Wire Gauge (AWG) number 22 to 24 wire loop
made of chromel, nichrome, tungsten, or platinum-iridium. The single-
loop diameter should be 4 mm or greater, preferably between 6 and 7 mm,
to provide adequate transfer of broth without accidental spillage of con-
tents. The standard loop used to obtain 0.001-ml sample volumes in milk
examinations is too small (being only 1.45 mm in diameter) for the transfer
of growth from positive presumptive tubes to the confirmatory broth. The
wire shank on all transfer loops should be between 7 and 8 cm long to
reach the culture broth without contaminating the tube with the inoculat-
ing loop holder.
Wire loops made of approximately 85 percent platinum and 15 percent
iridium (or rhodium) alloy with an AWG number 22 thickness are prefer-
red in many laboratories because of their fast cooling after flame steriliza-
tion. Nichrome wire is less expensive and is stiffer but does not cool as
LABORATORY APPARATUS 37
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quickly. When ordering nichrome wire, it is advisable to choose AWG
number 24 thickness because of the greater stiffness of this alloy com-
pared with platinum-rhodium.
For laboratories using the multiple tube procedures for fecal strep-
tococcus detection, a triple loop should be available for confirming posi-
tive azide dextrose broth cultures to ethyl violet azide medium. This
confirmatory medium requires a larger inoculum because of the growth
suppressive agents incorporated in its formulation to reduce false positive
reactions. The triple loop can be constructed from any of the previous
alloys by twisting a single length of wire into a chain of three individual
loops at the free end of the wire shank.
Alternatives to the flame-sterilized wire loop for culture transfer in-
clude single-service transfer loops of aluminum or stainless steel (18).
Quantities of these transfer loops may be placed in a modified, short-
length, stainless-steel pipette container or in a large-diameter, glass test
tube with a protective, metal-foil cover and sterilized either by dry heat or
steam. After using a single transfer loop, it should be placed in a beaker
containing a suitable germicide. Occasionally stainless-steel loops be-
come tarnished from exposure to concentrated germicides or from char-
red materials accumulated in the dry heat sterilization process. Tarnish
may be removed from stainless-steel loops by placing them in a glass
cylinder and very carefully adding boiling sulfuric acid. After 5 or 10
minutes in the cleaning solution, the acid solution is very carefully
drained into another acid-resistant container. Slowly add tap water to the
cylinder of loops to rinse the residual acid from the stainless steel loops.
Repeat the rinse several times, and then remove the transfer loops. The
black film remaining on the loops can now be easily removed by polishing
with sandsoap or household scouring powder.
Disposable, single-service, hardwood applicator sticks that have been
sterilized by dry heat may also be used for transferring broth cultures (19).
Steam sterilization must not be used because wood distillate products
may be generated that are toxic to bacteria in the transfer procedure.
Hardwood applicators (1/12 to 1/8 inches in diameter) must be long
enough to reach the bottom of the culture tube with at least 1 inch
extending out of the tube for manipulation. Single-service hardwood
applicators used for culture transfer are a convenience in field and mobile
laboratories. Flame sterilization is not required, and there is adequate
inoculum pick-up from the presumptive tube to inoculate a BGLB broth
tube and EC broth tube without recharging the applicator. These sterile
applicators may also be used to transfer growth from a coliform colony on
M-Endo MF to lauryl tryptose broth in the initial verification step.
The use of glass straws (Pasteur pipettes) is not a recommended culture
transfer practice because of the excessive quantity of inoculum intro-
duced into the BGLB broth. This heavy inoculum may introduce suffi-
cient densities of noncoliform flora that suppressive agents (brilliant
green dye and bile salts) in the medium may be inadequate. The net result
could be a failure to eliminate false positive fermentation reactions from
the confirmation of lactose gas positive cultures in the presumptive test.
Inoculating needles are commonly used to transfer growth from MF
cultures, agar plates, or pure culture slants for further purification,
38 Evaluating Water Bacteriology LaboratoriesIGeldreich
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biochemical tests, or serological slide agglutination procedures. The
inoculating needle may be made from any of the aforementioned alloys
and should be sufficiently long to avoid contaminating the lip of a culture
tube during transfer. Inoculating needles used for streaking plates should
have a smooth tip to prevent tearing the agar surface. If a microwelder or
similar heat source is available, the needle tip of some metal alloys may be
made into a smooth ball by momentary application of heat. Specify an
alloy wire gauge size that will provide the necessary stiffness for making
agar stab inoculations or for picking subsurface colonies for transfer to
other media.
MEMBRANE FILTRATION (MF) UNITS
Filtration assemblies for the MF procedure consist of two parts: the
funnel and a funnel receptacle. The receptacle that supports the MF on a
porous metal screen or glass frit is generally mounted in a suction flask or
a special drain system with a No. 8 rubber stopper. A funnel is clamped or
twist-locked to the receptacle during filtration and directs the flow of
water over the effective filtration area of the MF. Reusable filtration
assemblies may be constructed of autoclavable plastic, borosilicate glass,
spun stainless steel, or metal plate materials. Funnels manufactured of
stainless steel are less subject to corrosion and are very durable under
field use. Glass and plastic funnels are graduated for direct measuring,
and unless subjected to frequent breakage, they cost less.
Filtration assemblies should not leak during the filtering procedure.
Worn lock wheels on the funnel-locking ring assembly of metal units or
improper seating of the membrane on glass filter units frequently cause
leaking. Inspection of the narrow neck of the funnel sometimes reveals
worn areas in the metal plating that expose the brass base material. Since
brass is toxic to bacteria, such worn funnels should not be used. All
surfaces of the filtration assemblies in contact with the water sample
before its passage through the MF should be uniformly smooth and free
from corrugations, seams, or other surface irregularities that may retain
bacteria.
It is recommended that the funnel portions of each filtration unit be
washed at least once each week in a mild detergent solution to prevent the
accumulation of a dirt film or water hardness spots on the funnel walls.
Grease and soil deposits can become areas that block the free-flowing
funnel rinsing action required after each filtration. As an added precau-
tion, these units may be coated with a silicone preparation such as
"Desicote." This hydrophobic coating prevents the metal or glass from
being wetted and minimizes sample retention on surfaces of the funnel.
Silicone coatings on filtration equipment will withstand repeated auto-
clave sterilization. When equipment is used daily, the silicone coating
should be renewed monthly.
FORCEPS
Sterile forceps (alcohol flamed) are necessary in the manipulation of
MF's, both for placing them on the filtration apparatus and for transfer-
ring filters to broth saturated pad or agar media. Forceps should be
constructed with smooth, spade-shaped ends similar to forceps used in
LABORATORY APPARATUS 39
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stamp collecting. Sharply pointed forceps or forceps with knurled inner
surfaces on the ends should not be used because of the risk of puncturing
or tearing the membrane. Use a metal file to modify such forceps for a
more blunt, rounded end with smooth inner surfaces. Forceps with a
slightly curved tip for better manipulation around the curvature of the
culture dish are acceptable.
REFERENCES
I. Clark, H. F., and Kabler, P. W. The Physiology of the Coliform Group. Chapter II. In:
Principles and Applications in Aquatic Microbiology. H. Heukelekian and N. C. Don-
dero, Editors. John Wiley & Sons, New York. p. 202-229 (1964).
2. Geldreich, E. E. Origins of Microbial Pollution in Streams. In: Transmission of Viruses
by the Water Route. G. Berg, Editor. Wiley Interscience (John Wiley & Sons), New
York. p. 355-361 (1967).
3. Wolf, H. W. The Coliform Count as a Measure of Water Quality. Chapter 14. In: Water
Pollution Microbiology. R. Mitchell, Editor. Wiley Interscience (John Wiley & Sons),
New York. p. 333-345 (1972).
4. Prescott, S. C., Winslow, C. E. A., and McCrady, M. Water Bacteriology. 6th Edition.
John Wiley & Sons, New York. 368 p. (1947).
5. Rogers, L. A., Clark, W. M., and Evans, A. C. The Characteristics of Bacteria of the
Colon Type Found Occurring on Grains. Jour. Infect. Des. 17:135-137 (1915).
6. Browne, W. W., and Ackman, B. The Fallacy of Refined Readings of Gas Percentages
in the Fermentation of Lactose Peptone Bile Lactose Broth. Jour. Bacteriol. 2:249-261
(1917).
7. Allen, L. A., and Harrison, J. The Characters of Some Coliform Bacteria Isolated from
Grass and Grass Silage. Ann. Appl. Biol. 23:538-545 (1936).
8. Bardsley, D. A. A Comparison of Two Methods for Assessing the Numbers of Diffe-
rent Types of Coliform Organisms in Water. Jour. Hyg. 38:309-324 (1938).
9. Thomas, S. B., and Hobson, P. M. Coli-aerogens Bacteria Isolated from Ears and
Panicles of Cereal Crops. Jour. Appl. Bacteriol. 18:1-8 (1955).
10. Thomas, S. B., Jones, G. E., and Franklin, P. M. The Classification of Cqli-aerogenes
Bacteria Isolated from Farm Water Supplies. Proc. Soc. Appl. Bacteriol. 14:45-61
(1951).
11. Thomas, S. B., Hobson, P. M., and Druce, R. G. Coli-aerogenes Bacteria in Farm
Water Supplies. Jour. Appl. Bacteriol. 22:32-45 (1959).
12. Taguchi, K. Experimental Studies on the Examination of Coliform Organisms in Wa-
ter. I. Fundamental Studies on Incubation Temperatures. Bull. Inst. Pub. Health
(Japan) 9:165-175 (1960).
13. Krog, A. J. Roccal in.the Dairy Pasteurizing Plant. Jour. Milk Technol. 5:343-347
(1942).
14. Beck, W. J. Methodology for Testing for Fecal Coliform Organisms from the Marine
Environment. California State Health Dept. Symposium on Fecal Coliform Organisms
from the Marine Environment. Berkeley, Calif, p. 22-37 (May 21, 1968).
15. Brewer, J. H., Heer, A. A., and McLaughlin, C. B. The Control of Sterilization
Procedures with Thermophilic Spore-formers. Bacteriol. Proc., Soc. Amer. Bacteriol.
p. 61 (1956).
16. Brewer, J. H., and McLaughlin, C. B. Dehydrated Sterilizer Controls Containing
Bacterial Spores and Culture Media. Jour. Pharm. Sci. 50:171-172 (1961).
17. Geldreich, E. E., Jeter, H. L., and Winter, J. A. Technical Considerations in Applying
the Membrane Filter Procedure. Health Lab. Sci. 4:113-125 (1967).
18. Connors, J. J. Presterilized Liquid Transfer Loops in Water Bacteriology. Jour. Amer.
Water Works Assoc. 55:200-204 (1963).
19. McGurre, O. E. Wood Applicators for the Confirmatory Test in the Bacteriological
Analysis of Water. Pub. Health Repts. 79:810-814 (1964).
40 Evaluating Water Bacteriology Laboratories/Geldreich
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GUIDELINES ON LABORATORY APPARATUS
Incubator
Manufacturer Model
Sufficiently sized for daily work load
Uniform temperature maintained in all parts (± 0.5°C)
Thermometer accurately calibrated, with bulb immersed in water on
top and bottom shelves
Temperature recorded daily or recording thermometer sensitive to
± 0.5°C change used
Incubator not subjected to excessive room temperatures—variations
beyond a range of 65° to 80°F (18° to 27°C)
Incubator Room (Optional)
Manufacturer Model
Well insulated, equipped with properly distributed heating and
humidifying units for optimum environmental control
Shelf areas used for incubation conformed to 35°C ± 0.5°C
temperature requirement
Thermometers accurately calibrated with bulb immersed in water
Temperature at selected areas recorded daily or recording thermometer
sensitive to ± 0.5°C changes used
Water Bath
Manufacturer Model
Sufficiently sized for fecal coliform tests
Uniform temperature of 44.5°C ± 0.2°C maintained
Thermometer accurately calibrated, immersed in water bath
Temperature recorded daily or recording thermometer sensitive to
± 0.2°C changes used
Hot-Air Sterilizing Oven
Manufacturer Model
Sufficiently sized to prevent crowding of interior
Construction ensured a stable sterilizing temperature
Thermometer accurately calibrated in range of 160° to 180°C or equipped
with recording thermometer
Autoclave
Manufacturer Model
Sufficiently sized to prevent crowding of interior
Construction provided uniform temperature up to and including 121°C . . .
Thermometer accurately calibrated with bulb properly located to register
minimal temperature within chamber
Pressure gage and operational safety valve provided
Steam source provided from saturated steam line or from gas or
electrically heated steam generator
Sterilization temperature reached in 30 minutes
If pressure cooker used, provided with a pressure gage and thermometer
with bulb 1 inch above water level
Thermometers
Accuracy checked against a thermometer certified by National Bureau of
Standards or one of equivalent accuracy
Liquid column had no discontinuous sections; graduation marks legible ...
LABORATORY APPARATUS 41
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pH Meter, Electronic
Manufacturer
Accuracy calibrated to 0.1 pH units
Balance
For general media preparations, Type .—. balance used,
with 2-gram sensitivity at 150-gram load
For weighing quantities less than 2 gram, Type
analytical balance used, with 1 mg sensitivity at 10 gram load
Appropriate weights of good quality provided for each balance
Microscope and Lamp
The preferred binocular, wide field, type used; 10 to 15 diameters
magnification for MF colony counts, Type ....
Fluorescent light source provided
Colony Count
Preferred Quebec colony counter, dark-field model for standard
plate counts used
Inoculating Equipment
Wire loop of 22- or 24-gage chromel, nichrome, or platinum-indium,
sterilized by flame, used
Single-service transfer loops of aluminum or stainless steel, presterilized
by dry heat or steam, used
Disposable single service hardwood applicators, presterilized by
dry heat only, used
Membrane Filtration Units
Manufacturer Model
Leak proof during filtration
Metal plating not worn to expose base metal
Forceps
The preferred round tip without corrugations used
Forceps alcohol flamed for use in MF procedure
Evaluating Water Bacteriology LaboralorieslGeldrelch
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CHAPTER IV
GLASSWARE, METAL UTENSILS,
AND PLASTIC ITEMS
Glassware items used during the daily operations of a laboratory are
repeatedly subjected to a variety of corrosive materials in testing proce-
dures, high temperature during sterilization, vigorous cleaning schedules,
and careless handling; all of these speed glassware to ultimate discard and
replacement. Technological improvements have introduced disposable
hard-glass (borosilicate) items, an extensive choice of plastic substitutes,
and some stainless-steel vessels for use in the once exclusive domain of
laboratory glassware. However, substitution with disposable or reusable
plastic items must be fully evaluated in terms of labor costs, possible
reassignment of some nontechnical preparation room personnel to other
responsibilities, suitability of reuse plastic items, and a continued availa-
bility of selected stock items from the supplier. Plastic materials used in a
bacteriological laboratory must be free from toxic residual lubricants
used in the molding process, exhibit clarity, have accurate calibration
marks for volume measurements, and withstand repeated autoclaving if
the items are to be reused.
MEDIA PREPARATION UTENSILS
Utensils made of borosilicate glass or other suitable noncorrosive
material, such as stainless steel or enamel, are recommended for use in
preparing media. If enamelware is used, it must be free of chips in the
procelain-like glaze that expose the base metal to corrosion and to in-
teraction with media preparations. Utensils made of aluminum, copper,
or zinc alloys should not be used because these metals also react with
media solutions and introduce metal ions that are toxic to bacterial
growth.
Utensils for media preparation must be thoroughly cleaned to prevent
carry-over of foreign residues or dried medium. When metal utensils are
used, care must be taken to clean crevices around handle rivets or other
attachments that might harbor caked deposits of previously prepared
media. Magnetic stirrers that are inserted in large glass Erlenmeyers to
aid in a more rapid solution of the dehydrated media must also be
thoroughly cleaned.
SAMPLE BOTTLE SPECIFICATIONS
Wide-mouth sample bottles should be used for all water collections
because they permit sample collection with less chance of accidental
contamination at the water tap or other outlet port. Glass sample bottles
should be made of borosilicate or other noncorrosive glass, preferably
with metal or plastic screw-cap closures that incorporate a nontoxic,
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 43
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leakproof liner. Screw caps require no protective dust cover since the
design of the closure affords adequate protection during normal storage
and sampling procedures.
New plastic screw caps on glass sample bottles should be checked for
bacterial toxicity by using a modification of the distilled-water suitability
test. A minimum of 10 sterile plastic caps should be soaked in 100 ml
sterile distilled water for 24 hours at room temperature. This water is then
examined for toxic residuals with the use of the distilled-water suitability
test. The plastic caps that have toxic residuals, as reflected by the results
of the rinse water examination, should not be used until free of these toxic
properties. In most instances, these unsatisfactory plastic caps can be
detoxified of phenol residuals after six successive autoclavings in re-
peated changes of distilled water.
Ground-glass stopper closures are acceptable if they are covered be-
fore sterilization with a metal foil, rubberized cloth, or heavy imperme-
able paper that extends from the cap to the shoulder area of the bottle.
Paper or cloth covers must be held in place by string or tape that can
withstand sterilization temperatures. Foil covers are preferred and can be
held in place by pressing the foil around the narrow portion of the bottle
neck. This requirement protects the inner portion of the cap and bottle top
from contamination during the storing, handling, and transporting to or
from sample collections. Always keep the cover over the ground-glass
cap while handling, and once the sample is collected, replace the cap with
its cover pressed over the bottle.
The rising cost of shipping samples by mail has prompted replacing
glass sample bottles with plastic containers that can withstand autoclave
sterilization for 15 minutes at 121°C. These plastic sample bottles are
available with wide mouth openings and screw-cap closures. Some diffi-
culty with autoclavable plastic bottles may be related to the purchase of
polyethylene bottles that are not as rigid a plastic as is the polypropylene
or polycarbonate type. In either case, plastic bottles should not have the
screw caps tightly closed during sterilization, so that changes in air
pressure and elevated temperatures will not cause some of these bottles to
exhibit a partial or complete collapse of the side walls. Sample bottles
made of linear polyethylene with a polypropylene screw closure should
not be used because leakage can occur when samples are held at refrigera-
tion temperatures. Apparently the difference in the coefficient of expan-
sion rate for these two different plastic materials is the source of this
problem. Therefore, specifications for plastic sample bottles should re-
quire the bottle and screw closure to be of the same autoclavable plastic
material.
Plastic bottles for bacteriological samples offer advantages of low cost,
light weight, and resistance to breakage. However, they must not contain
toxic substances or organic matter that originates from the/plasticizer or
mold release agents. The presence of adverse substances can be deter-
mined by using the procedure previously described for plastic screw caps.
Sterile plastic bags ("Whirl-Pak" type) may be useful for limited
sample collections involving unchlorinated waters. Problems associated
with preventing contamination, with leakage, and with' aseptically adding
a dechlorinating agent restricts using these plastic bags when collecting
44 Evaluating Water Bacteriology LaboratorieslGeldreich
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chlorinated water. Attempts have been made to inject the dechlorinating
agent into each bag and cover the puncture with water-proof tape. How-
ever, leakage may occur at the puncture point if the tape is not completely
water resistant and firmly attached.
Stream samples may be shipped in these plastic bags provided the filled
bags are properly folded for closure and then reinforced with freezer tape
for a positive seal to prevent leakage. Following these precautions, water
samples in plastic bags can be transported either in boxes or heavy paper
envelopes ("Jiffy" or equivalent) without leakage. Tests for residual
toxicity indicate that after prolonged storage (over several months) toxic
substances can leach into the water samples, presumably because of
leaching of plasticizers. For the time limits established for transporting
bacteriological samples, however, this low toxicity level is insignificant.
PIPETS
Pipets may be of any convenient size, provided they deliver the re-
quired volume quickly and accurately within a 2.5 percent tolerance.
Pipets that are graduated to the tip should be discarded if the tip is broken
since the measurement of a sample will not meet the required calibration
tolerances. Tip-delivery, 10-ml pipets with narrow openings are undesir-
able because of the slow flow of measured 10-ml portions. The tips of such
pipets should not be cut to increase the flow rate because of the reduced
accuracy in measured volumes.
Graduation marks must be legible and permanently bonded to the glass.
Pipets made of glass formulations other than borosilicate are often more
susceptable to etching during cleaning procedures. Even pipets con-
structed of borosilicate glass will become frosted if allowed to stand for
extended periods (overnight) in a caustic detergent solution. Pipets that
become badly etched should be discarded because of poor visibility of the
fluid meniscus. Disposable plastic pipets must not only be sterile but also
must meet the required tolerance for calibration accuracy and legibility
and be free of toxic residues introduced during manufacture and commer-
cial sterilization.
A cotton plug may be inserted into the mouth end of each pipet as a
safety measure to prevent the technician from accidentally ingesting
caustics, volatile solvents, or other dangerous agents including pathogens
in sewage and industrial wastes. The use of cotton-plugged pipets is
optional, but when employed, the cotton plug should not be so tight fitting
that it obstructs drawing quantities into the measured length of the pipet
nor so loose as to fall out of the mouth end before or during use. Optional-
ly, a rubber bulb or mechanical pipetting aid may be used.
PIPET CONTAINERS
Metal boxes or cans used for sterilization and storage of sterile pipets
should not be constructed of copper since this metal is very toxic to
bacteria. The high temperatures required for sterilization of pipets can
oxidize copper particles and cause them to flake off and be transferred
into the culture media when these pipets are used to deliver measured
sample portions. Therefore, it is recommended that all copper pipet
containers be replaced with stainless-steel containers that resist heat
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 45
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deterioration. Aluminum pipet containers are acceptable but generally
less durable than stainless-steel units. Also, individual pipets may be
wrapped in good quality paper that will resist charring and brittleness
caused by sterilization temperatures. Because of the large number of
pipets used, wrapping pipets in paper for sterilization and storage is
impractical in most laboratories. Metal boxes or cans permit easy access
to the pipets as well as convenient storage for large numbers of pipets
during high-volume work periods.
A pad of nonabsorbent cotton, glass wool, Teflon, or silicone rubber
placed in the bottom of the pipet can is occasionally used as a protective
cushion to reduce breakage of pipet tips. Although this practice affords
some measure of protection for tip-delivery pipets, the cotton or glass-
wool padding may become a source of debris, which can then become
trapped on the MF surface during sample pipetting. Repeated exposure of
these protective pads to high sterilization temperatures causes the pad-
ding to become brittle and small pieces are easily picked-up on the tips of
pipets stored in these cans. When such protective pads are used, it is
necessary to replace them whenever deterioration is observed.
PETRI DISHES
Petri dishes are essential laboratory items for standard plate count
determinations, MF cultures, and streak plate isolation of bacterial cul-
tures. Where these culture dishes are used for pour plates and pure
culture isolations, the size is usually 100 mm x 15 mm. Special studies
requiring the examination of more than 2- to 3-ml volumes by the pour
plate procedure necessitate a larger volume of agar to solidify the in-
creased sample volume and, therefore, a larger diameter Petri dish. Since
the MF procedure is standardized on 47-mm diameter membranes, the
tight fitting 50- x 12-mm Petri dish is generally used for this technique,
although other sizes can be used if desired.
Although glass Petri dishes have long been used in the laboratory, the
use of disposable plastic Petri dishes is increasing because of their overall
lower cost and the elimination of washing and sterilization procedures
and risk of breakage. Regardless of the material (glass or plastic), these
culture dishes must be completely transparent for optimum visibility of
colonies, have flat bottoms to eliminate uneven dispersion of suspended
bacterial cells in the pour plate technique, and be free from bubbles and
scratches that impair observation of deep colonies. Plastic dishes with
tight fitting covers, in contrast to the loose-fitting standard Petri dish
covers, are preferred for MF cultures because they retard evaporation
loss from broth or agar media and they help maintain a humid atmosphere
in the culture dish.
PETRI DISH CONTAINERS
Metal containers (stainless steel or aluminum) are essential for properly
sterilizing and storing glass Petri dishes since they have loose fitting tops
that could allow dust to contaminate the sterile inner portions of the dish.
Copper containers should not be used since copper readily oxidizes or
flakes off after repeated exposure to dry-heat sterilization temperatures.
Such particles are toxic and might be introduced into the Petri dishes and
46 Evaluating Water Bacteriology LaboratoriesIGeldreich
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medium additions. Since Petri dish containers for sterilizing the 60-mm-
size glass-type Petri dish are not readily available as a manufactured item,
heavy metal foil can be used to roll wrap approximately 6 to 10 dishes for
sterilization. The heavy metal foil, folded at top and bottom, holds firmly
without additional support. Char-resistant paper sacks or wrapping paper
may also be used to prepare Petri dishes for sterilization.
Plastic, disposable Petri dishes are packaged, presterilized, in plastic
bags as a protection against airborne contamin;xjion. It is desirable to
open one plastic pack at a time to minimize chance contamination. Some
disposable Petri dishes used for MF cultures are packaged in small
cardboard boxes, which are also useful as protective storage containers
for the dishes in the laboratory. In fact, if the small plastic dishes are
sterilized for reuse (see subsection on Plastic Culture Dish Reuse in
Chapter V), they may be stored in the same boxes, or in plastic boxes with
tight fitting covers commonly used for refrigerated food storage.
CULTURE TUBES AND CLOSURES
Cultures tubes are used for a variety of purposes, including multiple
tube procedures, biochemcial tests for bacterial identification, and stock
culture collections. These tubes must be of a sufficient size to contain the
culture medium, as well as the sample portions employed, without being
overly full. When culture tubes are too small, cultures are more subject to
contamination and may become the source of contamination during trans-
fer by spilling, splashing, or generating aerosols.
Since observation of gas production is essential to multiple tube proce-
dures and various biochemical test reactions, an inverted vial (fermenta-
tion or gas vial) must be inserted into culture tubes being prepared for
fermentation tests. The length and bore of the inverted vial should be
related to the culture tube size and volume of medium. The medium
volume should be sufficient to ensure complete filling of the inverted vial
during sterilization and to partially submerge the fermentation tube at
least half-way. The diameter of the inner tube should not be less than 40
percent of the diameter of the culture tube with which it will be used. A
common practice is to use 16- or 18-mm x 150-mm culture tubes with 10-
x 75-mm fermentation tubes for biochemical fermentation tests and
multiple tube procedures involving sample portions of 1-ml or less. Where
10-ml sample portions are needed, larger culture tubes of 25-mm x 150- or
200-mm size must be used. However, the same size (10- x 75-mm)
fermentation tube inserts are permissible. The use of smaller fermenta-
tion vial inserts make early observation of gas bubbles more uncertain.
Snug-fitting stainless-steel or plastic caps (2), or loose fitting aluminum
caps, are the recommended closures for culture tubes used in
the multiple tube procedure. Since these closures cover the lip and upper
inch of the culture tube, flaming the tube opening is not necessary when
pipetting or transferring a culture with an inoculating loop or needle.
Because metal caps are more durable than plastic or cotton plugs, they are
more economical over a long period or for indefinite reuse.
Although nonabsorbent cotton plugs may be used as tube closures,
much time is required to prepare them satisfactorily. Cotton plugs should
extend 20 to 30 mm into the tube and approximately 30 mm out from the
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 47
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tube opening for proper handling during sample pipetting or culture
transfer. When cotton plugs are used, the culture-tube capacity should be
large enough to adequately contain the desired medium and sample vol-
umes without wetting the plug during sterilization or sample processing.
Once a cotton plug is wet, it loses its effectiveness as a barrier. Since these
plugs do not protect the upper edges of the tube opening, this area must be
flamed to reduce the risk of contamination. Because polyurethane foam
test tube plugs may inhibit microbial growth by release of volatile fatty
amines to the growth medium during autoclaving (3), do not use any
polymeric material unless toxicity tests demonstrate it to be inert.
Culture tubes with screw-cap closures are preferred for use when
preparing media for biochemical tests and agar slants for stock culture
collections. With the tighter fitting screw closure, broth and agar prepara-
tions can be stored for longer time periods without excessive media loss
through evaporation. Of several sizes of screw-cap culture tubes availa-
ble, the 16- x 150-mm size is frequently employed in biochemical tests
and the 16- x 125-mm size is preferred for agar slants used in stock culture
maintenance.
All culture tubes must be made of borosilicate glass or other corrosion
resistant glass. Whenever these tubes become frosted from the corrosive
action of improper cleaning or chemical reagents or become excessively
scratched from use to the point that visibility is impaired, they must be
discarded. Disposable culture tubes are generally made of soda-lime glass
(soft glass); these are not recommended for bacteriological use because of
interaction of glass and media during storage. Another disadvantage of
soda-lime glass is its susceptibility to etching during routine glassware
cleaning. These limitations mitigate against the use of most single-service
culture tubes in the bacteriological laboratory.
DILUTION BOTTLES OR TUBES
Examination of bacterial populations by the multiple tube test, MF
procedure, and pour plate technique requires preparation of accurate
sample dilutions. Dilution water blanks are prepared in either screw-cap
culture tubes containing 9 ml of diluent for 1:10 dilutions or in dilution
bottles that have a capacity for 99 ml diluent. This latter approach is more
common since it permits both 1:10 and 1:100 dilutions to be prepared from
the same suspension.
These glassware items must be made of borosilicate or other corrosion
resistant glass with a graduation level for 9 ml (tube) or 99 ml (bottle)
permanently marked on the glass wall. This mark will assist the bac-
teriologist to detect occasional dilution blanks that may contain improper
volumes of dilution water, thereby necessitating their rejection for use in
preparing serial dilutions. Because a source of screw-cap culture tubes
with a permanent 9-ml mark may not be readily available from most
commercial suppliers, a quantity of appropriate borosilicate glass culture
tubes must be calibrated at the 9-ml level with a diamond marking pencil
or other glass marking tool. These special culture tubes, like all other
dilution bottles, should be restricted to preparation of dilution water
blanks and not be mixed with other glassware collections for general
laboratory use.
48 Evaluating Water Bacteriology LaboratorieslGeldreich
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Closures for dilution bottles and tubes must prevent leakage of the
contents during vigorous shaking or mixing to obtain uniform suspen-
sions. Therefore, closures must be ground-glass stoppers, rubber stop-
pers (Escher type), or screw caps. Cotton plugs or metal or plastic caps
are completely unsuitable. Each dilution bottle employing either a
ground-glass stopper or rubber stopper must be covered before steriliza-
tion with metal foil, rubberized cloth, or an impermeable paper cap to
minimize contamination of the lip of the bottle while in storage and during
hand manipulaiton of the closure during use. Screw-cap closures are
preferred because they afford a protective shield over bottle openings and
eliminate the need for additional cover.
New plastic screw-cap closures should be checked for bacterial toxic-
ity since some lots have been found to have a phenol-type residual due to
toxic substances carried over from the molding process. Six successive
autoclavings in repeated changes of distilled water are needed to remove
the toxic material.
The toxicity of screw caps to bacteria can be checked by soaking 10
new screw caps in 100 ml sterile distilled water for 24 hours at room
temperature, then performing a suitability test on the distilled water (rinse
water) used to soak these plastic caps. Those caps that have toxic residu-
als (reflected by poor bacterial recovery in the suitability test), should be
put through the leaching procedure previously described and then re-
tested for toxicity.
Dilution bottles that become chipped or cracked around the neck or
have defective liners should be discarded. In addition, bottles with mis-
matched ground-glass stoppers should also be discarded. In all of these
cases, leaky bottles may result in hazardous aerosols that can contami-
nate the laboratory and expose personnel to an unnecessary risk.
MEMBRANE FILTER QUALITY FOR MICROBIOLOGY
Commercial brands of MF's may vary in performance as a result of
manufacturing technology, materials, and degree of quality control exer-
cised. For microbiological applications, there must be a complete reten-
tion of organisms on the surface of a nontoxic, inert matrix that permits a
continuous contact with nutrients from a medium held in a substrate
below the membrane. These basic conditions place demanding require-
ments on the quality of every membrane used in the laboratory. Basic
difficulties encountered with MF's generally relate to pore distribution,
nonwetting filter areas, grid-line ink restriction, membrane materials,
sterilization practices, and poor storage characteristics that cause in-
creased filter brittleness and surface warping (4-15).
MF pores should be uniformly distributed and have a diameter of 0.45
micron (± 0.02 micron) for routine bacteriological techniques. Pores of
some commercial lots of MF's have been found to be so small in some
areas of the filter that serious local reduction in the flow rate occurs. The
filter should be free of visible nonporous areas that prevent the diffusion
of nutrients to the upper surface of the membrane. Any bacterial cells
entrapped on such surfaces will not develop into visible colonies because
of lack of nutrients. When M-Endo is used in a test of diffusibility,
nonwetting areas on the filter will remain white and dry. Such observa-
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 49
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tions should not be confused with air bubbles, which can be removed by
reseating the membrane over the medium-saturated pad or agar base. At
the other extreme, pores larger than 0.70 micron will not retain organisms
associated with indicator groups. For complete bacterial separation from
liquids, MF porosity of 0.22 micron is required to ensure retention of the
smallest bacteria through physical impingement or electrostatic entrap-
ment.
The ink used to imprint the grid system on the MF should be nontoxic to
all bacteria cultivated on the filter surface (6). Some inks have been found
to be bacteriostatic or bactericidal. Such effects can be recognized
through restrictive colony development adjacent to the imprinted lines.
These growth restrictions may not only be caused by inhibition from toxic
inks, but also from thick ink imprints that "wall-in" grid squares and
hydrophobic inks that prevent nutrient diffusion to sites in the ink im-
print. As an additional characteristic, inks selected for grid imprinting
should not "bleed" across the membrane surface after a 24-hour contact
with any medium normally used at 44.5°C incubation. Heavy imprinting
of the grid system can also result in a network of "canal-like" indenta-
tions that frequently become filled with confluent growth.
The physical structure of the MF material should be such that it pro-
vides an optimum retention of bacteria on or near the upper surface with
little migration to areas within the pore matrix. Where subsurface pene-
tration occurs, growth should not be obscured from visual recognition
during the colony-counting procedure.
Chemical composition of MF's has largely been limited to polymerized
cellulose esters, since MF technology initially developed in this direction.
Conventional media designed for selective recovery of bacterial indicator
groups or pathogens using agar pour plates, streak plates, or broth cul-
tures had to be redesigned to compensate for the physical-chemical
properties characteristic of nitrocellulose materials (5,15,16). For exam-
ple, the selective adsorption of dyes excluded the use of acid to neutral
dyes as indicator systems and necessitated the use of increased amounts
of brilliant green as a suppressive agent in Kaufmann's brilliant green agar
to obtain the desired suppression of some of the unwanted bacterial
population. Similarly, when more refined peptones such as tryptone,
polypeptone, and proteose peptone No. 3 were added to MF media, they
were found to be superior to crude peptones added to the original media.
The result has been the creation of a family of media designed specifically
for use with nitrocellulose MF products. With these experiences in mind,
manufacturers should be careful about revising the Goetz MF process.
Changes involve the risk that recommended media may suddenly become
less sensitive or less selective. Some compounds introduced to the MF
may improve flexibility or flow rate, or stabilize porosity. However, these
substances should not become a source of fermentable carbohydrates
that cause false colony differentiation, create pH shifts in the indicator
systems, are selectively toxic for specific organisms, or adversely de-
press the selective action of differential media by providing the bacteria
with a highly nutritive organic compound. In essence, MF's should re-
main inert to bacterial reaction and unchanged in those physical-chemical
characteristics that affect media selectivity and sensitivity.
50 Evaluating Water Bacteriology Laboratories/Geldreich
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Since the bacteriologist is working with aqueous solutions, a test for
extractables must be based on water as the solvent. Testing procedures
for aqueous extractables should include examination of extractables from
the MF's.
Extractable Test
Soak MF's in a double distilled water or high quality water produced in
a reverse osmosis system, for 24 hours at 50°C. Decant this water and
perform a water suitability test (see current Standard Methods) using the
original high-quality water as a control. Nutritive extractables will pro-
duce a significant growth response in this test whereas toxic extractables
will result in substantial reduction of bacterial recovery compared with
that of the control.
Membrane Response
In a fecal coliform test using a natural sample, compare the presoaked
membranes from the extractables test with MF's not presoaked and of the
same lot. Choose a sample such as stormwater runoff, farm pond, or
sewage lagoon to obtain a water flora with a high nonfecal coliform flora
that might appear as a background growth in this test. Check MF cultures
for significant increases in density of nonfecal coliforms (that could
interfere with fecal coliform detection), blue colbr development of fecal
coliform, and fecal coliform recovery. Nutritive additions could affect
differential characteristics of the test to produce excessive background
growth. These additives may also affect medium pH, which in turn could
be responsible for poor indicator color. Of course, toxic additives will
cause reduced fecal coliform recovery.
Membrane Filter Reuse
In an emergency, MF's may be reused several times, provided these
filters are used only in the same medium cultivations. For reuse, dis-
carded filters are washed in three successive changes of gently boiling
water. Damaged membranes are removed, and the remaining filters are
boiled in 3 percent hydrochloric acid for several minutes. The acid solu-
tion is then discarded and the MF's are washed in at least three changes of
gently boiling distilled water. A trace of bromocresol purple pH indicator
solution and sufficient sodium bicarbonate to neutralize any residual
acidity is added to the final rinse water. Following a 5-minute boil in this
final rinse water, the MF's are ready for reuse (18). The pink color on
MF's acquired from use of an Endo-type medium may be removed by
presoaking in a 10 percent sodium sulfite solution (19) before proceeding
to the acid and neutralized rinsing procedure.
ABSORBENT PADS
Bacteria retained on the MF surface may receive nutrients
from a broth-saturated absorbent pad or from an agar-based medium.
When a liquid culture medium is preferred, the absorbent pad substrate
material must be of high quality paper fibers, uniformly absorbent, and
free of sulfites, acids, or other substances that could inhibit bacterial
growth. When the quality of the absorbent pads is suspected of contributing
to erratic bacterial growth, the following tests are recommended:
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 51
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Absorption Capacity
Place an absorbent pad in a culture dish. Slowly add 1.8 ml of M-Endo
broth to the pad and allow to stand 10 minutes. Repeat this procedure
using a second pad in another culture dish and add 2.2 ml of M-Endo
broth. After 10 minutes, the first pad should have absorbed all 1.8 ml of
broth whereas the second culture dish should have some excess liquid
remaining that was not absorbed. When the absorbent pads saturated
with medium are observed visually, they should not exhibit nonabsorbent
spots.
Total Acidity
Soak 10 sterile absorbent pads in 100 ml of distilled water overnight.
Test the leachate water for total acidity; acidity should be less than 1 mg
when the leachate water is titrated to the phenolphthalein endpoint pH 8.3
with the use of 0.02 sodium hydroxide. Also, include a control test for the
pH of distilled water used in this test of total acidity in absorbent pads.
Toxic Residuals
Soak 10 sterile absorbent pads in 100 ml of distilled water for 24 hours at
35°C. Perform a suitability test on the distilled water (rinse water) used to
leach any soluble substances in the pads. Any test lots of absorbent pads
that are found to contain toxic substances that will leach out, as de-
monstrated by the suitability test, should not be used unless pretreated to
improve quality. The pretreatment process for removing toxic materials,
such as bleaching agents, consists of soaking pads in distilled water held
at 121°C for 15 minutes in the autoclave, decanting the rinse water, and
repackaging pads in large Petri dishes for sterilization at 121°C for 15
minutes, using rapid exhaust to quick-dry the pads (17).
The alternative approach is to prepare all MF broths with the addition
of 1.5 percent agar. Note, however, that these agar preparations must be
carefully added to culture dishes so as to create a smooth, moist surface
free of pock marks caused by foam and rapid mixing of air bubbles in the
liquid agar preparation. Agar preparations may be used immediately or
stored in a cool, dark place and used any time within 30 days, provided no
dehydration occurs.
REFERENCES
1. Barkworth, H., and Irwin, J. O. The Effect of the Shape of Container and Size of Gas
Tube in the Presumptive Coliform Test. Jour. Hyg. 41:180-1% (1941).
2. Morton, H. E. Stainless-Steel Closures for Replacement of Cotton Plugs in Culture
Tubes. Science 126:1248 (1957).
3. Bach, J. A., Wnuk, R. J., and Martin, D. G. Inhibition of Microbial Growth by Fatty
Amine Catalysts from Polyurethane Foam Test Tube Plugs. Appl. Microbiol. 29:615-
620(1975).
4. Geldreich, E. E., Jeter, H. L., and Winter, J. A. Technical Considerations in Applying
the Membrane Filter Procedure. Health Lab. Sci. 4:113-125 (1967).
5. Clark, H. F., Jeter, H. L., Geldreich, E. E., and Kabler, P. W. Domestic and European
Molecular Filter Membranes. Jour. Amer. Water Works Assoc. 44:1052-1056 (1952).
6. Caspar, A. J., and Leise, J. M. Inhibitory Effect of Grid Imprints on Growth of
Pasteurella tularensis on Membrane Filters. Jour. Bac. 71:728-731 (1956).
Loesche, W. J., and Socransky, S. S. Defect in Small Millipore Filters Disclosed by
New Technique for Isolating Oral Treponemes. Science 138:139-140 (Oct. 12, 1962).
-1 ' !f,USS' ^V and Hess' W" C- RaP'd Coliform Organism Determination
°or-T^?u"- Poli" Contr' Fed' 33:1021-1037 (1961).
7^35^4^97°) EsCher'chia COli °" Cellulose Acetate Membrane Filters.
Evaluating Water Bacteriology Laboratories/Geldreich
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10. Presswood, W. C., and Brown, L. R. Comparison of Gelman and Millipore Membrane
Filters for Enumerating Fecal Coliform Bacteria. Appl. Microbiol. 26:332-336 (1973).
11. Hufman, J. B. Evaluating the Membrane Fecal Coliform Test by Using Escherichia coli
as the Indicator Organism. Appl. Microbiol. 27:771-776 (1974).
12. Dutka, B. J., Jackson, M. J., and Bell, J. B. Comparison of Autoclave and Ethylene-
Oxide-Sterilized Membrane Filters Used in Water Quality Studies. Appl. Microbiol.
28:474-480 (1974).
13. Schaeffer, D. J., Long, M. C., and Janardan, K. G. Statistical Analysis of the Recovery
of Coliform Organisms on Gelman and Millipore Membrane Filters. Appl. Microbiol.
28:605-607 (1974).
14. Alico, R. K., and Palenchar, A. C. A Comparison of Different Brands of Membrane
Filters for Enumerating Staphvlococcus aureus. Appl. Microbiol. (in press).
15. Kabler, P. W., and Clark, H. F. The Use of Differential Media with the Membrane
Filter. Amer. Jour. Pub. Health. 42:390-392 (1952).
16. Burman, N. P. Developments in Membrane Filtration Techniques. 1. Coliform
Counts on MacConky Broth. Proc. Soc. Water Treat. Exam. 9:60-71 (1960).
17 Clark, H.F.,Geldreich,E. E., Jeter, H. L., and Kabler, P. W. The Membrane Filter in
Sanitary Bacteriology. Pub. Health Repts. 66:951-977 (1951).
18. Department of Health and Social Security, Welsh Office. Reports on Public Health and
Medical Subjects, No. 71. The Bacteriological Examination of Water Supplies. 4th ed.
Ministry of Housing and Local Government, Her Majesty's Stationary Office, London.
52 p. (1969).
19. Deak, S. Unpublished Laboratory Procedures. Department of Water Hygiene, State
Institute of Hygiene, Budapest, Hungary.
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 53
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GUIDELINES ON GLASSWARE, METAL UTENSILS,
AND PLASTIC ITEMS
Media Preparation Utensils
Borosilicate glass —
Stainless steel —
Utensils clean and free from foreign residues or dried medium —
Sample Bottles
Wide-mouth, glass or plastic bottles used; capacity .
Sample bottle closure:
Glass-stoppered bottles protected with metal foil, rubberized cloth,
or kraft type paper
Metal or plastic screw-cap, nontoxic and with leakproof liner
Plastic bottles used that can withstand sterilization (15 minutes at 121°C).
Sterile plastic bags ("Whirl-Pak" type) available for unchlorinated
stream samples
Pipets
Brand Type
Calibration error less than 2.5 percent
Tips unbroken, graduation distinctly marked
Delivered accurately and quickly
Mouth end plugged with cotton (optional)
Pipets Containers
Boxed in aluminum or stainless steel
Paper wrapping of good quality sulfite paper (optional)
Disposable pipet sterile packs unopened till needed
Petri Dishes
Brand Type
100 x 15 mm dishes used for pour plates
50 x 12 mm tight-fitting dishes (preferred type) used for MF cultures
Clear, flat bottom, free from bubbles and scratches
Petri Dish Containers
Aluminum or stainless-steel cans with covers, or heavy metal foil, or
char-resistant paper sacks or wrappings
Disposable plastic dishes protected from direct contamination
Culture Tubes and Closures
Sufficiently sized for total volume of medium and sample portions
Borosilicate glass or other corrosive resistant glass
Metal or plastic caps; plastic (nontoxic) or cotton plugs
Dilution Bottles or Tubes
Borosilicate or other corrosive resistant glass
Dilution bottles free of chips and cracks around the neck
Graduation level indelibly marked on side of bottle or tube
Screw cap with leak-proof liner
Plastic screw caps tested for freedom from toxic substances on sterilization
If rubber stoppers (Escher type) or ground-glass stoppers used, the
required metal foil, rubber cloth, or paper cap provided
54 Evaluating Water Bacteriology Laboratories/Geldreich
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Membrane Filters
Manufacturer Type_
Full bacteria] retention, satisfactory filtration speed
Stable in use, free of nutritive or toxic additives
Grid marked with nontoxic ink
Membrane Filter Reuse
Used only in emergency
Used only on same medium
Used only after proper cleaning
Absorbent Pads
Manufacturer Type.
Filter paper free from growth inhibitory substances
Uniform thickness permitting 1.8 to 2.2 ml medium absorption
Filter Funnels
Manufacturer Type
Leak during use
Badly scratched, scored, or corroded
Properly sterilized
GLASSWARE, METAL UTENSILS, AND PLASTIC ITEMS 55
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CHAPTER V
LABORATORY MATERIALS PREPARATION
Careful preparation of media, thorough cleaning of glassware, and
proper sterilization of media and equipment are hallmarks of a properly
functioning laboratory support unit. Quality control of these processes
involves maintenance of records on media pH and sterilization tempera-
ture, toxic residual test on detergent used in the glassware cleaning
procedure, suitability test on distilled water, and protective storage of
reagents, sterile media, and clean glassware items. Without careful atten-
tion to these services, the quality of laboratory data will be compromised
both in test sensitivity and reproducibility.
CLEANING GLASSWARE
The high rate of glassware turnover in large laboratory operations
requires prompt recycling of dirty, used glassware through the cleaning
procedure to produce chemically clean items for reuse in the laboratory
with minimum breakage loss. The cleaning operations in large
laboratories involve processing 10,000 or more pieces of glassware daily,
including test tubes, flasks, beakers, sample bottles, graduated cylinders,
pipets, Petri dishes, filter funnels, and some bulky specialized items such
as carboys.
Mechanical glassware washing equipment can rapidly clean a large
volume and variety of laboratory items without the need for a large staff
for this essential service. Mechanical washers must be equipped with
high-pressure, directional jet streams to break up and remove stubborn
deposits such as microbiological growth films, autoclaved proteins, agar,
sediments, sludges, chemicals, and wax markings. Washers must be easy
to load (preferably front loading at waist height for operator convenience)
and have accessory racks that can accommodate a variety of commonly
used laboratory glassware items. For operator protection, the washer
should have a built-in safety switch that automatically shuts the washer
off if the door is opened during operation. Wash, drain, and rinse cycles
must have separate adjustments for cycle time and cycle programming
and be automatic in selected sequences for use of 160°F (71.1°C) detergent
wash water, a clean water rinse at 180°F (82.2°C) and a final rinse in
distilled water or equivalent. The best cleaning cycle is one that will
produce sparkling clean glassware, free from acidity, alkalinity, and toxic
residues that could suppress the growth of microorganisms (1).
The bacteriologist is responsible for demonstrating that washed
glassware is free of toxic or inhibitory residues resulting from the deter-
gent used in the washing procedure. The test for detergent suitability
should be performed with glass Petri dishes as follows:
1. Wash and rinse some glass Petri dishes according to the usual
procedure.
LABORATORY MATERIALS PREPARATION 57
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2. Rinse another group with six successive rinses of distilled water.
3. Wash some with detergent wash water (in-use concentration) and
drain dry without rinsing.
4. Sterilize all three groups.
5. Using standard plate count agar, pour duplicate or triplicate plates
with the same water sample (to yield 20 to 60 colonies per plate) on
Petri dish sets cleaned as in step 1, 2, and 3. Incubate the pour
plates at 35°C for 48 hours.
6. If the unrinsed plates (step 3) have a lower bacterial count (15
percent or more) than the well-rinsed plates (step 2), the detergent
contains bacterio-static substances and another detergent should
be selected.
7. If the plates in group 1 have bacterial counts lower (15 percent or
more) than the well-rinsed plates (step 2), toxic residues remain
on glassware from routine washing procedures, and a nontoxic
detergent must be substituted for the one in use and a longer rinse
cycle must be established.
Since many laboratories now use plastic Petri dishes exclusively, test-
ing the suitability of detergent to clean glassware items should be mod-
ified for application to culture tubes or dilution bottles as follows:
1. Wash and rinse some culture tubes or dilution bottles in the usual
cleaning procedure.
2. Rinse another group with six successive rinses of distilled water.
3. Wash some of these culture tubes or dilution bottles with deter-
gent wash water (in-use concentration), and drain dry without
rinsing.
4. Dispense 20 ml of nutrient broth in each set of tubes or dilution
bottles, and autoclave at 121°C for 15 minutes.
5. Inoculate each tube or dilution bottle with 1 ml of the same water
sample used for the standard plate count determination.
6. Incubate all tubes or dilution-bottle cultures at 35°C for 24 hours.
7. Prepare appropriate dilutions of these cultures (10"»; 10'5; 10-6;10"7
ml) and pour duplicate or triplicate plates using standard plate
count agar; incubate for 48 hours at 35°C.
8. If plates from unrinsed tubes or bottles (step 3) show a lower
bacterial count (15 percent or more) than the well-rinsed tubes
(step 2), the detergent contains bacteriostatic substances and
another detergent should be selected.
9. If plates from tubes or bottles (step 1) washed and rinsed in usual
manner show a lower bacterial count (15 percent or more) than the
well-rinsed tubes or bottles, toxic residues remain on glassware.
These results indicate a nontoxic detergent must be substituted
for the one in use and a longer rinse cycle must be established.
In laboratories where mechanical glassware washers are not available
or if glassware items are not cleaned properly by mechanical methods,
hand washing must be employed. Hand washing requires the Use of
detergent formulas specifically developed for laboratory use rather than
the mild compounds commonly used in home dishwashing. Wash water
must be hot (160° to 170°F) and items should be vigorously brushed with
appropriately sized laboratory brushes to ensure removal of normal film
Evaluating Water Bacteriology LaboratoriesIGeldreich
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deposits and residual deposits of all dried materials. These deposits must
be removed from fermentation tubes, culture flasks, and sample bottles to
ensure that these residuals do not contribute contaminating material to
new media or to cultures when glassware items are returned to laboratory
use. The washing procedure must be followed by a hot water rinse and a
final distilled water rinse to ensure complete removal of the washing
detergent and any chemical deposits.
All glassware items must be inspected after air drying for sparkling
clarity. Fogging and etching of glassware may be caused by corrosive
reagents, culture byproducts, aging of glass material, excessive concen-
trations of alkaline detergents or abrasions from handling and from hand
cleaning with worn test tube brushes. Glass fogging may also result from
adding detergent to dirty tubes before sterilizing the contaminated dis-
cards or by reusing soft glass items such as "Dura-Glass" or disposable
flint glass. Film deposits may result from using a wash water cooler than
160° to 170°F. Washing glassware in wash water below 160° to 170°F will
not remove various residues associated with industrial waste, dairy, and
food samples.
Sample bottles used to collect potable water should not be excluded
from an adequate wash in detergent solution. In one laboratory, such
sample bottles were given only a hand rinse in demineralized water before
adding the dechlorinating agent and sterilizing with hot air. This practice
resulted in the gradual buildup of a residual deposit inside the bottom third
of each bottle that eventually hardened through repeated high-
temperature dry-heat sterilizations and left a permanent dark-brown
stain. Although this stained material in the bottle may not have contribut-
ed toxic material to the water sample since it was essentially baked into
the glass, it did present an unsightly appearance that would give the
general public an impression that potable water samples were collected in
undesirable containers.
Glassware items that have a persistent dirt film may be cleaned by
soaking in an organic acid detergent such as "Kleenz-Air" or "Nu-
Kleen" (Klenzade Products, Beloit, Wisconsin) or other equivalent
products. A suitable method utilizes a 10 percent solution of one of these
cleaning aids, including soaking overnight at 140°F (60°C) if possible,
rinsing, and then cleaning by the regular automatic washing procedure.
For a preliminary cleaning of grease, fat, and oil from pipets and other
glassware, the use of 50 percent ethanol, followed by a tap water rinse and
a final rinse in 95 percent ethanol, might prove useful. Experience with
the problem of removing stubborn dirt films from glassware indicates that
the organic detergent procedure will remove most of these deposits; those
that remain are permanently etched in the glass. These permanently
stained glassware items should be discarded.
STERILIZATION PROCEDURES
Various sterilization procedures are employed in the laboratory. The
choice of method depends on the stability of media, reagents, or materials
to be sterilized. Common sterilization practices involve: moist heat
(steam or hot water), dry heat, complete incineration, gas sterilization,
filtration, or UV radiation. In some cases, intermittent exposure to flow-
LABORATORY MATERIALS PREPARATION 59
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ing steam is used to sterilize materials that cannot be autoclaved, gas
sterilized, or filtered.
Media and Reagents
Tube media and specified reagents should be autoclaved at 121°C,
preferably for 10 to 12 minutes and not exceeding 15 minutes, unless there
are specific directions for another temperature or time. Tubes must be
packed loosely in baskets for uniform heating and cooling. Timing of the
sterilization period starts when the autoclave reaches 121°C. The
maximum elapsed time for exposing carbohydrate broths to any heat
(from the time the autoclave door is closed until the medium is removed
from the autoclave) is 45 minutes; this time should be kept to the absolute
minimum necessary to achieve sterility. Excessive exposure of sugars,
especially lactose, to heat may result in hydrolysis and/or carmelization
that, in turn, will give false-positive reactions with some noncoliform
bacteria. Additionally, in media containing carbohydrates, amino acids,
and peptides, other products may be formed that are toxic to bacteria.
Media preparations for MF procedures are generally not subjected to
autoclaving for several reasons, including destruction of sodium sulfite in
Endo-type media, instability of some suppressive agents in other media
formulations, and the small volumes of media needed on a daily basis.
Some exposure to heat is necessary, however, to ensure complete disso-
lution of all active media ingredients. Therefore, MF media should be
heated just to the initial boiling point and then cooled to room tempera-
ture. This heating procedure is best accomplished by placing the flask of
medium in a boiling-water bath for 5 minutes. As medium temperatures
reach an approximate peak of 97°C during this period, the preparation
becomes essentially sanitized. Direct heating of the medium on a hot plate
is not desirable since the medium must be frequently swirled and im-
mediately removed when the boiling point is reached. Subjecting a flask
of medium to the intense pin-point heat of a Bunsen flame is also not
recommended because of the rapid temperature increase to boiling and
the probability of medium destruction.
Reagents added to various media including antibiotics, sugar solutions,
and stock buffer water are frequently sterilized by membrane filtration
because these solutions may be heat sensitive or become chemically
contaminated when exposed to live steam. In the filter sterilization pro-
cedure, only clear solutions can be processed because paniculate matter
will rapidly clog the MF pores. Bacteria and larger microorganisms will be
separated from liquids by 0.22-micron-size MF's. Sterile filtrates should
be collected in appropriately sized, sterile, screw-capped or ground-
glass-stoppered containers and stored at 4° to 10°C.
Membrane Filters and Absorbent Pads
Sterilization of the MF is essential to all applications involving filtration
of liquids for bacterial removal or for use in bacterial cultivation. Before
the development of the Goetz MF process, membrane filters were
sterilized in the laboratory by gently boiling them in distilled water for 20
minutes and repeating the procedure a second time with fresh distilled
water. This procedure served the double purpose of sterilizing the mem-
60
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brane and of extracting any residual toxic substances. In retrospect, the
continued use of this leaching and sterilization procedure would have
avoided many of the variations in MF performance now evident. How-
ever, the procedure does take more time to execute and is a recognized
inconvenience in busy laboratories examining 50 to 200 samples per day.
MF's may be purchased in resealable kraft envelopes also containing 10
absorbent pads. These units are packaged for autoclaving or are pre-
sterilized. If not presterilized, packets of MF's and absorbent pads must
be sterilized before use by autoclaving at 121°C for 10 minutes. Im-
mediately following the 10-minute period, the autoclave should be rapidly
exhausted to atmospheric pressure and the membranes promptly re-
moved from the autoclave to minimize heat exposure. Excessive expo-
sure to sterilization temperatures may cause MF pores to seal, creating
uneven flow-through during filtration, or cause membranes to become
brittle and distorted. This problem is also aggravated by sterilization of
MF stocks held in storage for periods beyond 18 months. Rapidly
exhausting the autoclave also reduces the amount of water condensate
retained by the absorbent pads. Moisture retained in the absorbent pads
not only reduces their absorption capacity but also alters the final medium
concentration.
Commercial presterilization of MF's may be done by autoclaving,
gamma radiation, or exposure to ethylene oxide. A comparative study of
presterilized membranes has suggested that there are significant in-
creases in bacterial recovery rates for steam-sterilized MF's compared
with those sterilized with ethylene oxide (2). Therefore, for those
laboratories that are using supplies of membranes sterilized with ethylene
oxide, it may be desirable to submit several packs to steam sterilization
(12TC for 10 minutes with rapid steam exhaust) to further flush out latent
toxicities. These membranes should then be compared with other mem-
branes from the same lot of ethylene-oxide-treated membranes in a pure
culture recovery experiment. Some residual toxic effect might possibly
persist from ethylene oxide reaction products.
Despite manufacturing claims to the contrary, nitrocellulose MF's do
undergo some change in their physical characteristics during storage.
Upon aging, MF's may lose their flexibility and break apart at pressure
points created during manipulation. During filtration, surface warping
often occurs and a complete contact with the medium substrate becomes
impossible. The solution to this problem is not to stockpile MF supplies
beyond the estimated need for a 12-month period.
MF Filtration Equipment
The equipment used for the MF funnel and membrane holder can be
constructed from stainless steel, glass, polycarbonate, or polypropylene
plastic materials. This equipment should be sterilized by autoclaving at
121°C for 15 minutes, after having been cleaned and wrapped in kraft
paper to maintain sterility during laboratory storage. To sterilize at the
laboratory bench between filtrations, expose the filter funnel, with
cleaned surfaces, and the membrane holder to UV light for 2 minutes (3).
Take appropriate measures, however, to screen stray UV light from the
operator's eyes and skin and from MF cultures being processed adjacent
LABORATORY MATERIALS PREPARATION 61
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to the sterilization unit. Operator protection from skin burns is best
provided by placing the UV unit in an enclosed cabinet or bench drawer
so the unit can be activated only after the cabinet or drawer is closed. If an
open cabinet is used, coat the interior walls with a black paint to reduce
the incidence of light bounce out of the UV unit.
Although the average life of the UV lamp may be 5000 hours, the
practical lamp life depends primarily on characteristics of the individual
lamp and the number of times it is used. Therefore, maintaining a log on
the number of hours of operation and relating this to manufacturer's
recommended time limit for germicidal capabilities is of questionable
value. Bacteriological tests of the germicidal effectiveness of a given UV
source should be conducted periodically (4).
A suitable measurement of the effectiveness of UV exposure consists
of preparing a coliform pure culture suspension in buffered dilution water
so that 1 ml of diluent contains approximately 200 to 250 organisms and
exposing the suspension to UV light for measured time periods. Pipet 1 ml
of this suspension into each of two sterile Petri dishes. The suspension in
one open Petri dish is exposed to the UV radiation for 2 minutes and the
control suspension in the other Petri dish is exposed only to the lighting in
the laboratory for 2 minutes. After the 2-minute exposure, pour plates of
these two cultures, using standard plate count agar, are prepared and
incubated at 35°C for 48 hours. Comparative colony counts on plates from
the UV-exposed and unexposed suspensions must indicate that UV ex-
posure is producing a 99 percent kill of the bacterial suspension. This
bacteriological procedure should be carried out at regular intervals so that
a general pattern of lamp life under normal laboratory use can be estab-
lished. Once the life expectancy of the lamp is established, a reasonable
time pattern for routine replacement can be determined.
Although glass funnels can be sterilized by immersing in a boiling-water
bath for not less than 5 minutes, this is a hazardous practice that can lead
to serious burns as a result of accidental splashes and spills. An additional
disadvantage occurs in humidity buildup from flowing steam vapor escap-
ing into the surrounding working area.
Dry heat sterilization (170°C for 1 hour) can be used for glass filter
assemblies if the rubber stopper on the receptacle is removed before heat
exposure. This approach is not acceptable for sterilizing either metal or
plastic units, however. Neoprene or nylon lock wheels on metal funnels
undergo rapid deterioration and plastic filter assemblies become distorted
due to the high temperature and long-time exposure with the dry heat
sterilization procedure.
Sample Bottle Sterilization
The sterilization procedure for sample bottles depends on whether the
bottles are plastic or glass. Plastic bottles for sampling or for laboratory
use may be polyolefms (including conventional polyethylene, linear
polyethylene, polypropylene, polyallomer, and "TPX" polymethylpen-
tene), polycarbonate, or Teflon. Among this group, polypropylene,
polycarbonate, "TPX" polymethylpentene, polyallomer, and Teflon
FEP may be autoclaved repeatedly at 121°C for 15 minutes. To allow
pressure equalization and prevent the plastic bottles from collapsing
62 Evaluating Water Bacteriology LaboratoriesIGeldreich
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during autoclave sterilization, the screw caps should not be tightly closed.
Glass sample bottles with plastic screw caps must also be autoclaved at
121°C for 15 minutes since plastic materials used in the screw cap and liner
may not withstand the high temperatures of dry heat sterilization. Glass
sample bottles with ground-glass covers should be sterilized by dry heat
(2 hours at 170°C); this method ensures complete drying of the de-
chlorinating agent solution added to each bottle before sterilization. The
thin film of dechlorinating agent thus formed cannot be accidentally
spilled when the open sample bottle is manipulated during sample collec-
tion.
Individual Glassware Items
Many glassware items (flasks, beakers, graduated cylinders, etc.)
commonly used in the bacteriological laboratory require sterilization
before use. Since contact with steam during autoclaving may introduce
chemical contamination from boiler water to carefully washed glassware
items, dry heat sterilization (1-hour exposure to 170°C) is recommended.
Metal foil or paper covers of durable material (kraft paper or equivalent
parchment type) must be secured over open ends of these items to
maintain sterility when the items are removed from the sterilizer and
during storage before use. Precautions for dry heat sterilization include
the following: (a) glassware must be completely dry; (b) the oven must be
cool when these items are inserted, and (c) the oven should be allowed to
cool to near room temperature before removing glassware because sud-
den or uneven cooling may cause glassware to fracture.
Glassware and Inoculating Equipment in Metal Containers
Glass pipets, Petri dishes, and single service inoculating equipment are
generally stored in stainless steel or aluminum containers suitable for dry
heat sterilization. To ensure adequate heat penetration for sterilization of
these glassware items and single-service transfer loops or applicator
sticks, 2-hour exposure to dry heat at 170°C is required. Metal containers
of stainless steel resist heat damage and last longer than those constructed
of aluminum although either is acceptable.
Disposable, single-service hardwood applicators should only be dry
heat sterilized because steam sterilization may generate wood distillate
products that may be toxic to bacteria.
Dilution Water Blanks
Dilution water blanks are sterilized by autoclaving at 121°C for 15
minutes. Trays of these blanks should be packed loosely to permit even
exposure to flowing steam and to ensure that those blanks in the center of
the load reach sterilization temperature. Screw caps or rubber stopper
closures should be slightly loosened to permit pressure equalization dur-
ing autoclaving. Some loss of dilution water volume may result from
either evaporation or boil-over when steam pressure is rapidly reduced
during the autoclave exhaust cycle. Adjusting the timing of the steam
exhaust cycle should correct this problem, but consistent volume losses
of the dilution blank that are greater than 2 percent will require dispensing
101- or 102-ml volumes of dilution water to compensate for the approxi-
LABORATORY MATERIALS PREPARATION 63
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mate 1- to 2-ml water loss during autoclaving. Adjusting the volumes of
the dilution blanks before sterilization will eliminate the need for the
laboratory staff to adjust the final volume to 99 ml by pipetting sterile
dilution water into each of the deficient water blanks after autoclaving.
Plastic Culture Dish Resue
Shortages of plastic culture (Petri) dishes used in the MF tests, which
are generally considered to be a disposable item, may, at times, make it
necessary to consider their reuse when no substitute glass Petri dishes are
available. The procedure for reuse consists of discarding old cultures and
hand cleaning the top and bottom sections in a mild household dish
detergent. Following a rinse and air-drying, the dish sections are ready for
sterilization. Since this plastic material cannot withstand heat exposure
during autoclaving, other sterilization methods must be used. Plastic
culture dishes may be sterilized by soaking individual top and bottom
sections in 70 percent ethanol for 30 minutes, then placing these parts on a
clean towel to drain and air dry before reassembly. A more convenient
approach is to expose the interior portion of these dishes to UV light for 5
minutes and reassemble for storage or immediate reuse.
Plastic culture dishes may also be subjected to gas sterilization in a
Cryotherm chamber with 12 percent ethylene oxide at 120°C for a 4-hour
contact period. As a safety precaution relative to the explosive nature of
pure ethylene oxide in air at certain concentrations, a mixture of ethylene
oxide and carbon dioxide of decreased explosive and flammable proper-
ties must be used. Controls must be established to ensure the adequacy of
the flushing procedure to remove traces of ethylene oxide from the
culture dishes. Such a test for sterility would be:
1. Prepare a known coliform suspension of approximately 100 to 150
organisms per 1 ml in buffered dilution water for test use within 20
minutes. Prepare five replicate pour plates immediately, using
1-ml aliquots of the test suspension.
2. Place 1-ml aliquots of the suspension in each of five plastic culture
dishes sterilized by the ethylene oxide procedure and hold for 10
minutes.
3. Place 1-ml aliquots of the suspension in each of five glass culture
dishes sterilized by dry heat and hold for 10 minutes.
4. After 10 minutes add plate count agar, swirl to mix, and allow to
solidify.
5. Incubate 48 hours at 35°C, then determine densities.
6. Counts between cell suspensions held in the two sets of culture
dishes should be within 15 percent of the initial dilution and within
10 percent of each other.
When these sterilization procedures are used, it will be necessary to
select one plate from each batch sterilized for use as a sterilization
control. Standard plate count agar is added to the dish, mixed by gentle
rotation, solidified, then incubated at 35°C for 48 hours. No bacterial
growth should appear on the control plate if sterilization was ac-
complished with the procedure chosen.
Evaluating Water Bacteriology Laboratories/Geldreich
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Flame Sterilization
Wire inoculating loops and needles are sterilized by heating in an
ordinary Bunsen burner flame until the wire glows red hot. When steriliz-
ing wire loops, take care to avoid creating a hazardous aerosol that can
result from splattering of residual culture broth. Gradually draw the
inoculating wire through the burner flame, and thus allow the broth to
evaporate to dryness before the loop is actually in the flame. Immediately
before using loops and needles, allow them to cool to near room tempera-
ture to avoid heat killing the bacterial cells during transfer of growth from
broth, agar, or the MF surfaces.
Forceps and spatulas are generally surface sterilized by dipping in
alcohol and then burning off the residual alcohol to incinerate any at-
tached bacteria. Direct heating of forceps and spatulas until red hot
destroys the temper of the metal and may brand the MF during manipula-
tion.
Laboratory Water Quality
Laboratory water should be free of toxic or nutritive substances that
could influence survival or growth of bacteria and viruses. This special
water supply should, in addition, be free of microorganisms that might
contribute inhibitory substances to dilution water and media, pyrogens
that are deleterious in animal injections, and virus tissue cultures and
substances that interfere with sensitive chemical measurements. Many
factors may influence the quality of a laboratory distilled water supply: (a)
design of the distillation apparatus; (b) source of raw water; (c) condition
of the deionizing column, if used; (d) state of the carbon filter; (e) storage
chamber for reserve supply; (f) temperature of stored supply; and (g)
duration of storage before use. These factors may contribute contaminat-
ing substances to the distilled water including metal ions from the dis-
tribution system; ammonium hydroxide, hydrochloric acid, and other
fumes from the laboratory; chlorine from the tap water supply; and
carbon dioxide from the air. Therefore, distilled water pH may vary.
The processes used to produce distilled water evolved through the
years on an empirical basis. As a result, little attention has been directed
toward proper engineering of a system to yield a product that is com-
pletely satisfactory for biological applications. This problem is common
to both public health laboratory distilled water systems and to a large
number of water stills used by commercial suppliers of bottled distilled
water.
The best distilled water system utilizes stainless-steel construction, but
adequate systems may also be built from quartz, vicor, or Pyrex glass, in
that order of preference. A tin-lined system is the least desirable because
it requires periodic maintenance to replace hardware sections that have
lost tin plating and, thereby, expose copper or other base metal to contact
with the distilled water. All connecting plumbing should be stainless steel,
Pyrex, or special plastic pipes made of polytetrafluoroethylene (PTFE)
material (5). Polyvinyl chloride (PVC) is a major contaminant in high-
quality laboratory water systems and should not be used for connecting
plumbing (6). Storage tanks should be stainless steel, fiberglass,or suita-
ble plastic (PTFE), and protected from dust contamination.
LABORATORY MATERIALS PREPARATION 65
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The ideal conventional distilled water system should be regulated to
divert the first 10 percent of the initial daily output to waste, the middle
portion to a storage tank for high-quality distilled water requirements, and
the remaining portion to another storage tank for general distilled water
uses. Careful control of the distillation process should be maintained to
minimize splash-over and flash-over of undistilled water or volatile con-
taminants.
The input source water should be passed through a deionizing column
and a carbon filter before distillation. With careful maintenance of these
two columns, much of the inorganic and organic constituents of tap water
will be removed. However, not maintaining these columns can actually
result in a lower quality input water than that from the original tap water
source. Charcoal filters have been found to support the growth of bacteria
to alarmingly high counts. These charcoal beds concentrate both bacteria
and organic nutrients present from source water at low concentrations
(7). Therefore, a quality check should be made once a month to monitor
the general bacterial population level for excessive growth. Such growth
necessitates appropriate treatment or reactivation of the carbon column
to control any buildup of heat stable, antibiotic substances. Use of a
disposable in-line MF cartridge would alleviate this problem and ensure a
higher quality input water.
Recharge or regeneration of deionizers must receive prompt attention
whenever the water quality shows either a loss of chemical suitability or a
sudden decrease in bacterial quality as measured by a standard plate
count (35°C incubation for 48 hours on standard plate count agar). The
general bacterial population in a city water supply used as source water
contributes a variety of organisms to the resin beds. In such an environ-
ment, a bacterial population can quickly develop to densities ranging from
6,000 to 1,000,000 organisms per ml (8) because of the accumulation of
organic and inorganic material, adequate moisture, and large surface area
for attachment.
Limiting bacterial discharge from the resin bed is a partial benefit
derived from a commercial system that uses disposable cartridges for
prefiltering the source water, followed by organic adsorption, deioniza-
tion, and finally membrane filtration. Municipal tap water can be proc-
essed at a rate of 20 gallons per hour, and the deionized water produced
will be in the 10 megohm conductivity range, with no particulate matter
larger than 0.45 micron. Although this type of membrane filtration unit
will limit the passage of bacteria and particles larger than 0.45-micron
size, smaller microbial forms and waste products (dissolved metabolites)
produced by the bacterial populations in the resin beds pass through the
filter into the product water.
Distilled water can be contaminated by nutrients derived from many
sources. Some common causes include organic flash-over during distilla-
tion, continued use of exhausted carbon filter beds, deionizing columns in
need of recharging, dust contamination and chemical fumes entering the
stored supply, and the storage of distilled water in glass bottles not
thoroughly cleaned before use. Laboratory supplies of high quality dis-
tilled or deionized water should be protected from strong sunlight to
prevent algal growth capable of producing organic nutrients or antibacte-
rial metabolites.
66 Evaluating Water Bacteriology LaboratoriesIGeldreich
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Excellent quality water can also be produced by a reverse osmosis
system used in conjunction with a series-connected deionizing column.
The quality improves as the number of deionizer columns incorporated in
the system is increased. Water having a resistivity of 4.5 megohm-cm can
be routinely produced when one deionizer is used; adding a second unit in
series will increase the resistivity to 10 megohm-cm, or better. (The lower
the concentration of ionic contaminants in the water, the higher its resis-
tivity.) To maintain this high quality water, the first deionizer should be
recharged once each month and the second unit, once each year. The
favorable rate of recharge is possible only because the reverse osmosis
process removes approximately 90 percent of the ions. The reverse
osmosis membrane may require changing only once each year depending
on the quality of the input water. Water produced by this system should
be stored in either fiber glass or stainless steel tanks.
CHEMICAL QUALITY CONTROL FOR DISTILLED
AND DEIONIZED WATERS
Various physical and chemical parameters must be monitored at
scheduled intervals to ensure the continued production of high-quality
distilled or deionized water. One essential laboratory water quality mea-
surement is conductivity, particularly when conductivity measurements
are made at various points in the system train. Resistivity measurements
reflect the presence of ionized material (inorganic metals, salts, and
bases) but do not distinguish between the presence of toxic or nontoxic
metallic ions. This measurement also does not reveal any organic contam-
inants that may be present. The specific resistivity of freshly prepared,
good quality water should exceed 0.5 megohm-cm at 25°C (equivalent
to electrical conductivity of 1.0 ppm as NaCl) or 2 rnicrohms-cm.
Since most source waters used for the production of distilled water are
city water supplies, the distillate may show increased concentration of
ammonia and chloramines (9). Removal of free chlorine by distillation of
municipal water may be difficult because it apparently forms an azeotrope
with water at pH values greater than 5.5. As a result, flash-over of
chloramines is frequently a serious problem in water plant laboratories
where freshly chlorinated water is used for distillation. When this prob-
lem is encountered, suitable dechlorination procedures for the laboratory
water supply must be instituted. In other instances, trace concentrations
of volatile, short-chain fatty acids have been found in distilled water (10).
Additional chemical tests and use of an AutoAnalyzer will yield supple-
mental information for routine quality monitoring on the chemical im-
purities of a high quality laboratory water supply. Although such proce-
dures may detect various undesirable impurities, they provide no mea-
sure of the relative biological toxicity of the impurities.
BIOLOGICAL SUITABILITY TEST FOR DISTILLED
AND DEIONIZED WATER
Biological toxicity or nutritive releases from distilled and deionized
water supplies can be measured by a suitability test (11) that compares the
growth response of Enterobacter aerogenes in a minimal growth medium pre-
LABORATORY MATERIALS PREPARATION 67
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pared with the test water and the growth response of the organism in a
high quality water control. This test, described in Standard Methods (12),
is useful in evaluating the quality of distilled water from newly installed or
repaired water distillation systems and as a periodic check on the condi-
tion of existing stills, storage tanks, and laboratory water distribution
systems. The microbiological quality of laboratory water should be
evaluated at a frequency that will ensure the continued production of a
high-quality product. Experience indicates that the suitability test should
be performed annually, with additional tests following line alterations,
equipment repairs, or cleaning of the distribution network to individual
laboratory areas. (For a description of medium, see Chapter 6.)
Some state laboratory systems find it impractical to require small
laboratories to perform this quality control test and, therefore, offer this
service through the central state laboratory. This approach has produced
greater data reliability in monitoring the microbiological quality of all
laboratory water supplies within the state network of certified
laboratories. When conducting the distilled water suitability test, several
samples can be evaluated at the same time with little additional work since
a large portion of the time for this test involves reagent and culture
preparation. When this service is offered, the sampling schedule should
be timed so that a series of test samples are examined on a given day to
obtain maximum laboratory efficiency. Test samples over 48 hours old
should not be examined to avoid possible leaching of impurities from
plastic sample containers or from the cap liner. Used plastic bottles are
not recommended for shipment of laboratory water samples because of
low-level chemical residuals from previous bottle uses that might affect
test results. Clean borosilicate glass bottles are the preferred sample
container.
When toxic or nutritive organic complexes are present in distilled
water, the first indication may be erratic replicate results for pour plate or
membrane filter counts and irregular growth in certain minimal nutrient
culture media. Erratic plate counts may also result from improper wash-
ing procedures that leave toxic detergent residues on glassware items.
Erratic MF counts for a replicate series may also be due to poor quality
MF's or absorbent pads used in the experiment. If the washing procedure
and detergent are proven satisfactory or the MF products are of accepta-
ble quality, then the distilled water supply becomes a prime suspect and
should be investigated.
Enterobacter aerogenes is the test organism because it can grow in
minimal nutrients and does not require complex amino acids or other
additives necessary for Escherichia coli or Streptococcus faecalis.
Pseudomonas aeruginosa and other pseudomonads can also grow in the
presence of minimal nutrients and could be insensitive to inhibitory
factors produced by resident pseudomonads already present in the un-
known distilled water.
The minimal medium requirements to support a moderate growth of
Enterobacter aerogenes include: carbon source (citrate), nitrogen source
(ammonium sulfate), salt mixture (magnesium, calcium, iron, and
sodium), and a buffer (phosphate) solution to maintain a favorable
medium PH. All chemicals used in preparation of nutrient stock solutions
should be analytical reagent (AR) grade. This is particularly important
fiR
Evaluating Water Bacteriology LaboratorieslGeldreich
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in preparing potassium dihydrogen phosphate (KH2PO4) since some
brands have significant amounts of chemical impurities.
Only borosilicate glassware may be used in this test and all items must
receive a final rinse in freshly redistilled water from a glass still before dry
heat sterilization. This is necessary because the sensitivity of the test
depends upon the cleanliness of all items used (sample containers, flasks,
tubes, and pipets).
All stock solutions must be boiled 1 to 2 minutes to kill vegetative
bacterial cells (12). The stock solutions can then be stored in sterilized
glass-stoppered bottles at refrigerator temperature (5°C) for a maximum
period of 1 month. The inorganic salt stock solution will develop a slight
turbidity within 3 to 5 days as ferrous salt oxidizes to the ferric salt. Stock
solutions that develop heavy chemical turbidity or bacterial contamina-
tion should be discarded and a new stock solution prepared. The buffer
solution may also develop turbidity because of bacterial contamination;
when this occurs, it should likewise be discarded. The distilled water test
sample should be filtered through a 0.22-micron porosity MF or, alterna-
tively, boiled for 1 minute to kill vegetative bacterial cells. Longer boiling
time should be avoided to prevent changing the chemical composition of
impurities in the unknown sample.
An appropriate aliquot of an Enterobacter aerogenes suspension is
added to each flask so that the final cell concentration will be 30 to 80
bacterial cells per ml. Bacterial densities below 30 cells per ml produce
ratios that are not consistent, whereas densities greater than 100 cells per
ml result in decreased sensitivity to impurities in the test water. An initial
bacterial count is made by plating 1 ml of each culture flask in standard
plate count agar to verify the cell density range and to check for gross
contamination of the sample or media. The culture flasks and pour plates
are incubated at 35°C for 24 ± 2 hours. After incubation, the initial plate
counts are recorded and final plate counts are prepared from each flask;
dilutions of 1, 0.1, 0.01, 0.001, and 0.0001 ml are used. After incubating
the final set of pour plates for 24 ± 2 hours, these cultures are examined
and those plates having 30 to 300 colonies are counted.
After the bacterial density for each flask is determined from a selection
of plate counts within the 30 to 300 colony range, a series of ratios are
calculated to evaluate the growth results. The ratio for growth-inhibiting
substances is:
Colony count per ml, Flask B
Colony count per ml, Flask A
Ratio values between 0.8 and 1.2 indicate that toxic substances are not
present; whereas values less than 0.8 are positive indication of bacterial
toxicity. Since the test is also sensitive to the presence of nutritive
contaminants, ratios up to 3.0 are permissible because no significant
unstabilizing growth effects are created in buffered dilution water.
When the suitability test results indicate that contamination of the
laboratory water has reached atoxic level, the distillation system must be
disassembled, cleaned, and carefully inspected. Hardware sections
where tin plating has been lost can result in distilled water being exposed
to copper or other base metal used in the manufacture of the equipment.
LABORATORY MATERIALS PREPARATION 69
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All connecting plumbing should be stainless steel, Pyrex, or special
plastic pipes made of PTFE material. Use of dissimilar metal connections
can cause electrolysis and corrosion, which can result in metal ion toxici-
ty. Inspection of stills may indicate that there is a need for more frequent
still "clean-up" to minimize chemical residue buildup.
Before scheduling a shut-down for still maintenance and clean up,
provisions must be made for a reserve supply of distilled water to supple-
ment storage tank capacity. This may necessitate purchasing an addi-
tional storage tank to be incorporated into the system for emergency use
during repair and routine maintenance of laboratory water systems. More
uniform quality of laboratory water is ensured if a central supply of
distilled or deionized water is used rather than water from several stills in
different laboratories. The key to successful maintenance of high quality
laboratory water is having a staff microbiologist or chemist assigned the
task of routine surveillance of the system for quality control and adequate
production. This responsibility should include: daily checks of conductiv-
ity; chemical analysis for selected chemical impurities that are related to
source water quality; periodic recharge of the demineralizer; establish-
ment of production capacity that will ensure a stand-by reserve supply;
yearly inspection of valves, electrical heating elements, storage tank, and
distribution lines for defects; and finally, a yearly distilled water suitabil-
ity test to confirm the suitability of the laboratory water supply.
DILUTION WATER
Bacteriological examination of polluted waters necessitates the usage
of serial dilutions of the water samples to obtain a bacterial density range
within the statistical limits of any quantitative procedure. In the multiple
tube concept, the sample must be proportionally diluted so that a series of
positive and negative culture reactions is obtained. Colony counts on
MF's or in agar pour plates must also be limited in density because of
restricted surface area; this also necessitates appropriate dilution of
high-density samples to achieve a suitable bacterial population that may
be more accurately counted. In addition, the MF and agar pour plate
procedures demand particulate-free diluent so that discrete colony
growth and visibility are not impaired. Particulate matter in the agar pour
plate procedure may contribute significantly to counting error.
The ideal diluent is one that causes no change in the bacterial density
and does not depress the recovery of attenuated organisms. Many dilu-
ents have been proposed—some recommended for selected organisms
and others specifically recommended for use with water, food, or medical
specimens. The major reasons for divergent opinions on the proper
choice of diluent generally relate to the physiological state of the microor-
ganisms that must be recovered from a given sample. Thus, evaluation of
a suitable diluent for water samples must be related to the condition of
bacteria in natural water samples, not to the response of pure cultures of
bacteria or to results obtained on food products or medical specimens.
The chemical content of water varies from trace concentrations of
nutritive or toxic substances in some groundwater or in high mountain
streams, to the high nutrient concentrations found in food processing
wastes and m industrial effluents. Therefore, microbial survival in a
Evaluating Water Bacteriology Laboratories/Geldreich
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selected diluent can be quite variable and is influenced by suspension
time, temperature, pH, osmotic gradient, buffering, chelating capacity,
and trace concentrations of magnesium, calcium, and iron ions in the
diluent formulation.
Distilled water is not recommended for water sample dilution because it
is deficient in essential trace metal ions and in buffering and chelating
capacities (13,14). Tap water modified in various ways (charcoal filtered
or containing 0.1 percent sodium thiosulfate) has been used but the results
have drawn divergent interpretation because the inorganic salt content
and the effect of water treatment varies widely from one public water
supply to another (15,16). Sterile sea water used as a diluent is also
suspect because of the chance occurrence of heat stable antagonistic
agents. Physiological saline (0.85 percent sodium chloride in distilled
water) may preserve the viability of some species of bacteria (including
organisms damaged by phenol) but has been reported to be bactericidal to
Escherichia coli, Salmonella typhimurium, Staphylococcus aureus, and
Streptococcus pyogenes (16,17). Minimal nutrient water, generally pre-
pared as a 0.1 or 0.05 percent peptone solution in distilled water, has also
been used as a diluent; it is particularly useful in the recovery of at-
tenuated organisms from food products (18). Results from the investiga-
tion of peptone water as a diluent for water samples showed that at room
temperature bacterial multiplication could occur when the time between
sample dilution and plating exceeded 40 minutes (Table 1). For this
reason, using 0.1 percent peptone as a diluent requires that the 30-minute
limit on processing serial dilutions be closely followed. The 0.1 percent
peptone water diluent may be superior to phosphate dilution water in the
recovery of attenuated organisms from industrial wastes or from stream
samples that have high concentrations of heavy metal ions. The pH of
peptone water diluent should be adjusted to pH 6.8.
If bacterial growth with minimal lag is to be achieved in the bacteriolog-
ical examination of high quality natural waters, some degree of minerali-
zation, corresponding to that of natural water, is necessary. Phosphate-
buffered dilution water comes close to fulfilling this requirement, as
shown by the data in Table 2. Sterilized source waters were used as
diluents and compared with phosphate-buffered dilution water used in
this study. These data and those presented in Table 1 illustrate the need
for prompt sample processing through serial dilutions within 30 minutes
so as to reduce significant changes in the bacterial density at room
temperatures. When longer contact times are necessary for special re-
search studies, loss of viable cells in diluent suspensions can be suppress-
ed for periods up to approximately 2 hours by packing the inoculated
dilution blank in ice.
Stock potassium phosphate buffer solution (34.0 grams KH2PO4 per
liter distilled water) should be adj jsted to pH 7.2. After the addition of
1.25 ml stock buffer and 5.0 ml magnesium sulfate solution (50 grams
MgSO4 • 7 H2O per liter distilled water) to 1 liter of distilled water, the final
pH after autoclaving should be 7.2 ± 0.1. The addition of magnesium
sulfate to phosphate buffer dilution water improves the recovery of or-
ganisms with metabolic injury induced by high-quality water or by waters
containing significant concentrations of heavy metal ions (14). Since
LABORATORY MATERIALS PREPARATION 71
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TABLE 1. SURVIVAL OF BACTERIA IN VARIOUS DILUENTS
STORED AT ROOM TEMPERATURE
Initial
Sample Type of no. of
diluent bacteria*
Ohio River 0.05% Peptone 110
(Water 0.1% Peptone 100
intake) Phosphate buffered 100
Ohio River 0.05% Peptone 110
(Public 0.1% Peptone 90
Landing) Phosphate buffered 70
Pure cultures, coliform IMViC types:
+ + - - 0.05% Peptone 120
0.1% Peptone 140
Phosphate buffered 1 10
- - + + 0.05% Peptone 1 10
0.1% Peptone 110
Phosphate buffered 130
- + - + 0.05% Peptone 90
0.1% Peptone 90
Phosphate buffered 70
Streptococcus 0.05% Peptone 55
faecalis 0. 1% Peptone 60
Phosphate buffered 53
Streptococcus 0.05% Peptone 55
durans 0.1% Peptone 63
Phosphate buffered 55
Staphylococcus 0.05% Peptone 56
aureus 0.1% Peptone 58
Phosphate buffered 52
Percent change in no. of bacteria
20
min
+ 11
0
-22
+ 2
+ 19
-10
+ 3
-20
+ 13
+ 4
+ 5
-15
- 7
-17
+ 16
- 4
-18
+ 8
-22
-30
-20
-11
- 4
+23
40
min
-23
+26
+ 11
0
+ 18
-11
- 8
-13
+25
- 6
+22
-39
-11
-20
+ 6
+ 11
-20
-11
-15
-22
-26
+ 13
- 4
-23
1 hr
- 2
+ 7
+35
-14
+ 16
-44
+ 3
-13
+ 16
+ 16
+ 16
- 1
-11
-16
+23
+ 7
- 8
+ 2
+ 2
-22
- 2
+ 2
- 2
+ 12
2hr
+ 11
+ 48
- 13
+ 18
+ 106
- 39
+ 19
+ 3
+ 2
+ 5
+ 24
- 20
+ 21
+ 4
+ 49
- 7
+ 2
0
0
- 10
- 51
+ 11
+ 16
- 62
3hr
+ 36
+ 83
+ 67
+ 170
+214
+ 4
+ 79
+ 48
+ 11
+ 86
+218
- 33
+210
+ 141
+ 36
+ 13
+ 8
+ 4
+ 6
+ 6
- 93
+ 7
+ 19
- 90
*Standard plate counts per 1 ml (35°C incubation for 24 hours).
dilution water is generally recognized to be a harsh environment for
survival of attenuated bacteria found in chlorinated waters and sewage
effluents, the addition of magnesium sulfate should alleviate this problem.
When buffered dilution water is prepared in dilution bottles or culture
tubes of poor quality glass, the pH after sterilization may become more
alkaline (pH 7.5 or higher) because of substances leaching out of the glass.
Such glass containers must be removed from service and replaced with a
high-quality glassware (borosilicate formulation or equivalent) since in-
creased alkalinity of dilution water has a bactericidal effect on cell sus-
pensions.
72
Evaluating Water Bacteriology LaboratoriesIGeldreich
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TABLE 2. BACTERIAL POPULATION SURVIVAL IN AUTO-
CLAVED SOURCE WATER AND BUFFERED
DILUTION WATER*
Autoclaved source water Buffered dilution water
Plate Plate
Sample source count. Percent change count, Percent change
per mlt 15 min 30 min per mlt 15 min 30 min
White Clay Creek, S.D.
Lake Michigan, 111.
Goose Creek, S.C.
Kansas River, Kan.
Saugus River, Mass.
Sangamon River, 111.
Ohio River, Ohio
208
124
152
151
388
213
27
- 4
+ 35
- 3
-13
- 1
+ 5
- 7
+ 8
+ 37
- 2
-19
+ 5
+ 6
- 4
220
137
146
140
382
201
30
-11
-14
_ T
- 7
+ 7
+ 14
_ i
-14
-16
- 4
-15
+ 1
+ 9
-13
*Selected data from Butterfield (15).
tPlate counts incubated 37°C for 24 hours.
When turbidity due to microbial contamination is observed in the stock
buffer, fresh stock buffer solution should be prepared. Such turbidity may
be caused by many different kinds of organisms (bacteria, yeast, fungi).
These organisms are capable of survival and growth in the presence of the
minimal concentrations of nutrients present in buffered dilution water.
Microbiological analysis of contaminated stock buffer solution generally
shows large numbers ofPseudomonas undAchromobacter species. Once
species ofPseudomonas have become established in dilution water, their
antagonistic action toward other organisms may adversely affect test
results (19).
Place 25- to 30-ml portions of freshly prepared, sterilized (by MF
filtration) stock buffer solution into previously sterilized screw-cap test
tubes; or place the same amount of buffer solution in screw-cap test tubes
and autoclave the solution and tubes for 15 minutes at 121°C. Store the
sterilized tubes and solution at 5° to 10°C. Sterile stock buffer is then
available in small volumes as needed and if chance contamination should
occur during the removal of stock buffer, only a small volume of stock
buffer solution from a single tube needs to be discarded. A similar ap-
proach can be used to store the stock magnesium sulfate solution used in
conjunction with stock buffer and distilled water to make buffered dilu-
tion water.
REFERENCES
1. Wilson, S. R., and Cauffman H. Design for Microbiological Glassware Service. Appl.
Microbiol. 16: 950-953 (1968).
2. Dutka, B. J., Jackson, M. J., and Bell, J. B. Comparison of Autoclave and Ethylene-
Oxide-Sterilized Membrane Filters Used in Water Quality Studies. Appl. Microbiol.
28:474-480 (1974).
3. Rhines, C. E., and Cheevers, W. P. Decontamination of Membrane Filter Holders by
Ultraviolet Light. Jour. Amer. Water Works Assoc. 57:500-504 (1965).
4. Minkin, J. L., and Kellerman, A. S. A Bacteriological Method of Estimating Effective-
ness of UV Germicidal Lamps. Pub. Health Repts. 81:875-884 (1966).
LABORATORY MATERIALS PREPARATION 73
-------�
5. Karamian, N. A. Polytetrafluoroethylene Tubing for Transporting High Purity Water.
Amer. Lab. 5:11-14(1973).
6. Bangham, A. D., and Hill, M. W. Distillation and Storage of Water. Nature 237:408
(1972).
7. Wallis, C., Stagg, C. H., and Melnick, J. L. The Hazards of Incorporating Charcoal
Filters into Domestic Water Systems. Water Research 8:111-113 (1974).
8. Eisman, P. C., Kull, F. C., and Mayer, R. L. The Bacteriological Aspects of Deionized
Water. Jour. Amer. Pharm. Assoc. 38:88-91 (1949).
9. Morgan, G. B., and Gubbins, P. Occurrence of Chloramines in Buffered Bacterial
Dilution Water. Health Lab. Sci. 2:6 (1965).
10. Price, S. A.,andGare, L. A Source of Error in Microbiological Assays Attributable to a
Bacterial Inhibitor. Nature 183:838-840 (1959). .
11. Geldreich, E. E., and Clark, H. F. Distilled Water Suitability for Microbiological
Applications, tour. Milk & Food Techno!. 28:351-355 (1965).
12. American Public Health Association, American Water Works Association, Water
Pollution Control Federation. Standard Methods for the Examination of Water and
Wastewater. 14th Edition. American Public Health Association, Washington, D.C. p.
646-649 (1975) (in press).
13. Garvie, E. I. The Growth of Escherichia coli in Buffer Substrate and Distilled Water.
Jour. Bacteriol. 69:393-398 (1955).
14. MacLeod, R. A., Kuo, S. C., and Gelinas, R. Metabolic Injury to Bacteria. II.
Metabolic Injury Induced by Distilled Water or Cu++ in the Plating Diluent. Jour.
Bacteriol. 93:961-969 (1967).
15. Butterfield, C. T. The Selection of a Dilution Water for Bacteriological Examinations.
Jour. Bacteriol. 23:355-368 (1932).
16. King, W. L., and Hurst, A. A Note on the Survival of Some Bacteria in Different
Diluents. Jour. Appl. Bacteriol. 26:504-506 (1963).
17. Jayne-Williams, D. J. Report of a Discussion of the Effect of the Diluent on the
Recovery of Bacteria. Jour. Appl. Bacteriol. 26:398-404 (1963).
18. Straka, R. P., and Stokes, J. L. Rapid Destruction of Bacteria in Commonly Used
Diluents and Its Elimination. Appl. Microbiol. 5:21-25 (1957).
19. Waksman, S. A. Antagonistic Relations of Microorganisms. Bacteriol. Reviews 5:231-
291 (1941).
74 Evaluating Water Bacteriology LaboratorieslGeldreich
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GUIDELINES ON LABORATORY MATERIALS PREPARATION
Cleaning Glassware
Dishwasher Manufacturer Model
Thoroughly washed in detergent at 160°F, cycle time
Rinsed in clean water at 180°F, cycle time
Final rinse in distilled water, cycle time
Detergent brand
Washing procedure leaves no toxic residue
Glassware free from acidity or alkalinity
Glassware clean, free of film deposits
Sterilization Procedures
Tube media and reagents sterilized 121°C for 12 to 15 minutes
Tubes packed loosely in baskets for uniform heating and cooling
Timing began when autoclave reached 121°C
Total exposure of carbohydrate media to heat not over 45 minutes
Media removed and cooled as soon as possible after sterilization
MF media parboiled for 5 minutes
Reagents and media additions sterilized by MF filtration
MF presterilized or 12TC for 10 minutes, then exhaust
MF filtration equipment sterilized at: 12TC for 15 minutes; UV for 2
minutes, or in boiling water
Individual glassware items sterilized 1 hour at 170°C (dry heat)
Pipets, Petri dishes, inoculating loops in boxes, sterilized 170°C for 2 hours
Dilution water blanks sterilized 121°C for 15 minutes
Wire loops, needles, forceps, and spatulas flame sterilized
Quality of Laboratory Water
System analysis:
Still manufacturer Construction material
Demineralizer Recharge frequency
Protected storage tank Construction material
Supply adequate for all laboratory needs
Chemical quality control:
Resistivity exceeded 0.5 megohms-cm at 25°C pH _
Free from traces of heavy metals and chlorine
Free from organics
Biological suitability:
Free from bactericidal compounds as measured by bacteriological
suitability test Test ratio .
Bacteriological quality of water measured once each year by suitability
test; sooner, if necessary
Systems maintenance:
Inspected, repaired, cleaned out
Reservoir stand-by supply provided
Adequate surveillance program
Dilution Water
pH of stock phosphate buffer solution 7.2
Fresh stock buffer prepared when turbidity appeared
Stock buffer autoclaved and stored at 5° to 10°C
1.25 ml stock potassium phosphate buffer solution and 5.0 ml magnesium
sulfate solution added per 1 liter distilled water
Dispensed to give 99 ± 2 ml or 9 ± 0.2 ml after autoclaving
pH of sterile phosphate buffered water 7.2 + 0.1
LABORATORY MATERIALS PREPARATION 75
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CHAPTER VI
CULTURE MEDIA SPECIFICATIONS
The preparation of culture media for laboratory use has undergone
considerable advancement from the early, laborious art of processing
crude animal and plant materials into peptones, suppressing agents, and
agar substrates plus the further refining of textile dyestuffs into usable
indicator agents. Various commercial suppliers now manufacture a wide
variety of the basic ingredients for culture media formulations. However,
because of convenience and labor-saving advantages, most laboratories
use commercially prepared dehydrated media for large-volume, routine,
bacteriological procedures. The need for small quantities of biochemical
test media on an infrequent basis or the limited staff and media prepara-
tion facilities of small laboratories may justify the use of sterile tubes or
culture plates of prepared media available from commercial outlets even
though the cost per test is higher. Ampuled media or preweighed vials of
dehydrated media may be used for convenience in a laboratory perform-
ing only few tests and also in conjunction with portable MF kits because
of convenience and compact storage and because less preparation is
needed in the field.
MEDIA PREPARATION
Dehydrated culture media are available as finely ground powders,
granules, or tablets (1-3). The choice is largely dictated by cost, availabili-
ty, and convenience; however, finely ground powders are most fre-
quently used. These preparations dissolve quickly, but because they are
hygroscopic, long-term storage must be avoided in humid environments.
Media processed into granules may have a better shelf life because they
are relatively less hygroscopic. Using prepared media tablets permits the
easy preparation of small fixed volume batches of media, but the tabula-
tion process must not use any binding substances not specified in the
basic formula.
Regardless of the commercial processing method, these products are
best reconstituted by slowly adding the appropriate weighed quantities to
approximately half of the total volume of distilled water. Freshly distilled
or boiled distilled water, or equivalent, should be used because old
supplies of distilled water absorb sufficient gases to alter the final medium
pH. Only chemically clean glassware or stainless steel utensils should be
used to prepare and dispense media into culture tubes or bottles. The
mixture of distilled water and medium should be gently agitated by hand
or by magnetic stirrers to ensure rapid dissolution. Dissolution is also
aided by preheating the distilled water to approximately 45° to 50°C. After
thorough mixing, the container is rotated and the remaining volume of
distilled water is added slowly to wash residual powder from the inner
CULTURE MEDIA SPECIFICATIONS 77
-------�
walls of the container. Most reconstituted culture broths will go into
complete solution with careful mixing. Some media preparations, how-
ever, may have a normal turbidity resulting from insoluble materials in
indicator dyes, low solubility of selective agents (tetrathionate), or crea-
tion of colloidal particles in agar preparations.
When a medium formulation includes agar, gelatin, or cystine, the
water-medium mixture should be allowed to soak for about 5 minutes to
obtain a more uniform suspension. Follow this by applying heat to bring
about complete solution and to permit the medium to be dispensed in
culture tubes or bottles. Finally, sterilize. Agar may be dissolved in
several ways; the easiest is to place the flask containing the ingredients in
a boiling water bath to dissolve the agar medium into a uniform solution.
Large quantities of agar medium may be more effectively dissolved by 15
to 20 minute's exposure to flowing steam in an autoclave, set to operate
without pressure buildup, or in a steamer. Gelatin media are best dissolv-
ed by heating in a boiling water bath. Agar and gelatin media must be in
complete solution before being dispensed into culture tubes or bottles and
then sterilized. If the agar is not in complete solution before being dis-
pensed into individual tubes or bottles, it will not be distributed uniformly
and, in some cases, the agar concentration may be so low that the medium
will fail to solidify after cooling to room temperature.
DISPENSING CULTURE MEDIA
Once a medium is dissolved, it should be dispensed into appropriate
culture tubes or bottles and promptly sterilized by appropriate proce-
dures (4). To avoid bacterial growth in this material, which can alter
medium pH and introduce toxic metabolic byproducts, the total time from
media preparation to sterilization should not exceed 2 hours. Refrigerat-
ing unsterilized prepared media overnight before sterilization is undesira-
ble because bacterial activity will not be completely suppressed.
Broth or melted agar medium is generally dispensed into culture tubes
or bottles by means of an automatic pipetting machine set to deliver the
appropriate volume. Such equipment must be thoroughly rinsed im-
mediately after use to avoid carry-over of dyes, carbohydrates, and
selective inhibitory chemicals to subsequent medium dispensed by this
system. When an agar medium is dispensed, its temperature should be
maintained above 60°C so that the agar remains fluid long enough to be
passed through the system and be adequately flushed out before it solidi-
fies in the pipetter.
Culture tubes and bottles should be covered with metal caps, plastic
plugs, or screw-cap closures, as required, immediately after dispensing
the medium. Screw-cap closures should be loosely fitted until after auto-
claving so that the pressure within the culture tube or bottle equilibrates
to the autoclave pressure during sterilization. Large bottles, in particular,
may crack when removed from the autoclave if the caps are completely
tightened.
MEDIA pH MEASUREMENTS
The electronic pH meter available for use in media preparations must
be calibrated in the range of intended use by means of a precision buffer
78 Evaluating Water Bacteriology LaboratoriesIGeldreich
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standard. Do not assume that the pH meter scales are linear throughout
their total pH range. As an illustration, a pH meter calibrated with pH 9.0
buffer may read low by 0.4 pH unit when used to measure a solution at or
near pH 7.0. Since most bacteriological media used in the water laborato-
ry are near pH 7.0, the standard buffer chosen to calibrate the pH meter at
daily intervals should be pH 7.0. Colorimetric methods or pH paper strips
impregnated with indicator dyes are not acceptable because color
changes are masked by dyes in the media such as BGLB broth, eosin
methylene blue agar, M-Endo broth, M-FC broth, and other selective
media formulations.
When media pH deviates from the established tolerance of ± 0.1 pH
units, immediately check the pH meter calibration for drift. If the meter is
functional, check for preparation and sterilization errors. If the problem is
not due to the factors above, then poor quality distilled water or a poor
quality commercial medium should be suspected.
Adjustment of the medium pH before sterilization requires the use of
small volumes of either a base (1 N sodium hydroxide) to shift the pH
higher or an acid (1 N hydrochloric acid) to shift the pH lower. Allowance
must also be made for a shift in pH (usually 0.1 to 0.2 pH unit lower)
during autoclaving, so that the final pH value will meet the recommended
values.
MEDIA STORAGE
Supplies of commercial dehydrated media do not remain stable indefi-
nitely. Certain constituents will decompose and create byproducts that
adversely affect the sensitivity and selectivity of differential media. If
heavier components sift to the lower depths of finely divided powder
batches, it may result in a nonhomogeneous mixture. Imperfect bottle
seals may allow moisture to be taken up by dehydrated media powders
that are very hygroscopic. In laboratories that are not equipped with air
conditioning, bottles of dehydrated media should be stored upside down.
Containers stored this way have a self-sealing effect around the screw-cap
liner that will retard media decomposition. Once sufficient moisture gains
entry, the powder becomes caked into a hard mass or, in some cases,
develops a viscous consistency. In either case, such products undergo
changes that can alter their usefulness in culturing bacterial strains and
may alter the biochemical responses expected.
As new supplies are received, each container should be dated and older
packages used first. Laboratory personnel should inventory stock
supplies every 3 months. At the time of inspection, those supplies af-
fected by moisture contamination should be discarded. Media supplies
used most frequently should be purchased in quantities estimated to last
no longer than 1 year, preferably purchased on a 6-month basis. Those
media that are used infrequently or in very small quantities daily or those
that are very hygroscopic should be purchased in quarter-pound sizes
rather than in 1- or 5-pound (454 or 2270 gram) quantities. Despite the
lower cost per unit when purchased in bulk quantities, open or unsealed
packages of media with slow turn-over may deteriorate before substantial
amounts are used. Discarding partially used bulk packages represents a
CULTURE MEDIA SPECIFICATIONS 79
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greater economic loss than would have occurred if small size packages of
the specific medium were bought.
Prepared culture media should be stored in an area that affords protec-
tion from direct sunlight, contamination, and excessive evaporation.
Prepared media may be stored in cold rooms, if sealed in plastic bags or
other sealed containers, or at ambient temperature. Frost-free re-
frigerators may cause excessive media evaporation on storage beyond 1
week. Cold storage areas must not contain volatile solvents whose ab-
sorption into media may be toxic to bacteria. After storage at low temper-
atures, prepared tubes of fermentation media must first be held overnight
at room or incubator temperature to check for microbial contamination
before being inoculated. Equilibration of media to room temperature after
cold storage will also reduce erroneous results due to absorbed atmos-
pheric gases. These gases would otherwise be released during test incuba-
tion and could mask the detection of gas produced by bacterial fermenta-
tion (5). All media showing turbidity or gas bubbles after wanning up from
cold storage temperature should be discarded.
Culture media stored at ambient laboratory temperature must be pro-
tected from strong light. If media containing light sensitive dye sub-
stances (BGLB broth, M-Endo broth, M-FC medium, etc.) are not pro-
tected from direct sunlight, or fluorescent light decomposition of the dye
substances in these media will result in a significant reduction in their
suppressive action on noncoliform organisms.
Extended storage of sterile media will increase the risk of contamina-
tion, fading of indicator color intensity, precipitation or excessive evap-
oration all of which can drastically alter performance of these prepara-
tions. Agar slants and pour plate preparations of selective media may
begin to lose moisture in storage. This can result in the creation of dry or
rough surfaces that are undesirable for optimum microbial growth. Media
evaporation and contamination develop more quickly using loose-fitting
caps, cotton plugs, and Petri dish containers. Therefore, unless screw cap
culture tubes or tight fitting culture dishes are used, limit media produc-
tion to quantities calculated to be used within a 1-week period.
MEDIA QUALITY CONTROL
In general, using commercially prepared dehydrated media is prefera-
ble to preparing media for routine use from basic ingredients; commercial
products are less subject to the minor variations in chemical composition
that may be introduced when weighing individual components. This
simplified, single weighing of a preformulated medium should produce
greater uniformity in composition and also reduce preparation time.
Although commercial dehydrated media are generally acknowledged to
be more desirable than laboratory preparations, the manufacturer may
substitute ingredients such as peptones of different composition from
those originally used or include a bile complex or other material that is not
of equivalent selectivity to the one recommended by the medium de-
veloper (6-7). This problem can be further complicated where the medium
tormulation must include some biological dyes (basic fuchsin, brilliant
green, analine blue, rosalic acid, etc.) that are technical grade products
Having varying percentages of active dye and "inert" material.
80
Evaluating Water Bacteriology Laboratories/Geldreich
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Media manufacturers attempt, through their quality control programs, to
evaluate the differences in ingredients and select from among their own
products those components that give the best equivalence to the original
formulation. As new lots of each medium are produced, they should be
submitted to an adequate quality control testing program by the manufac-
turer to ensure optimum recovery and colony differentiation. Failure to
meet specifications for sensitivity, selectivity, and colony differentiation
(where applicable) should be sufficient reason to prevent a specific batch
of medium from being released through commercial outlets for laboratory
use. However, media quality control may represent a substantial part of
operational costs. Attempts to reduce this essential function result in
inadequate or ineffective quality control and may result in an increased
risk that batches of substandard media will be released for laboratory use.
Although a quality check is made of these commercial products (8,9), it
appears to be inadequate, at times. Poor quality total coliform sheen
development and significant reductions in coliform recovery on M-Endo
medium have been observed by several laboratories in recent years.
Apparently, the use of poor grades of basic fuchsin and inadequate
dye-sulfite balance in the medium are responsible. Basic fuchsin may
differ in dye content, both from lot to lot and from manufacturer to
manufacturer; this makes it essential to standardize the fuchsin-sulfite
proportion used each time a new lot of dye is employed. Variations in in-
tensity of the blue color of fecal coliform colonies on M-FC medium
may be caused by residual acidity in absorbent pads or MF's and also
from unsatisfactory lots of aniline blue used in the commercial prepara-
tion of this medium. The intensity and structure of bile salt crystals that
precipitate on fecal coliform colonies relate to the type of bile salts
complex incorporated in the medium. Formulations of commercial media
containing sodium azide (M-Enterococcus, KF, and PSE agars) have an
approximate shelf life of 2 years after production, because of the deleteri-
ous effects created by the slow decomposition of the azide compound.
For these reasons, it is desirable for the laboratory to establish a quality
control analysis on each new lot of medium purchased—to compare it
with a lot of the same medium known to be satisfactory in terms of
differential qualities and sensitivity.
MEDIA EVALUATION
The analysis of a medium for selectivity and adequate quantitative
recovery must be based on appropriate water samples, which can be
altered by dilution or by dosing with selected organisms. The use of pure
cultures suspended in buffered dilution water does have some value in
determining recovery rates for those particular strains, but provides no
information on the interaction effects of a mixed bacterial flora and of the
water chemistry on test medium performance. Choose an appropriate
well water or lake sample or dose a potable water sample so that the
colifrom density ranges from 5 to 10 organisms per 100 ml and the
standard plate count (35°C for 48 hours) ranges from 1,000 to 10,000
organisms per ml. Many poorly treated, marginal, public, and private
potable water supplies meet these sample specifications. Bottled waters
dosed with 5 to 10 coliforms per 100 ml may be another suitable sample
CULTURE MEDIA SPECIFICATIONS 81
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source since a standard plate count of these waters frequently dem-
onstrates a high general bacterial population but few or less than one
coliform per 100 ml.
1. Prepare a batch of test medium appropriate to the testing proce-
dure (fermentation tube media for the MPN or a broth or equiva:
lent agar for the MF procedure).
2a. When evaluating a multiple tube test medium, examine the
selected water sample (containing 5 to 10 coliforms per 100 ml)
by inoculating 25 tubes of the double-strength test medium lot
(lactose broth or lauryl tryptose broth) with 10 ml sample
aliquots and a second set of tubes prepared from a known satis-
factory lot of the same type of medium. Incubate at 35°C for 24 to
48 hours, and confirm all positive tubes from each set using
brilliant green lactose bile broth (incubated at 35°C for 24 to 48
hours) or EC broth (incubated at 44.5°C for 24 hours). If the
medium being tested is brilliant green lactose bile or EC broth,
prepare two sets of presumptive positive tubes and confirm using
the unknown and known lots of the same confirmatory medium.
Record all positive confirmed test results for each set. Satisfac-
tory results for the test medium lot should be within ± 1 positive
tube of the control medium lot.
2b. When evaluating a MF test medium, examine the selected water
sample (containing 5 to 10 total coliforms or fecal coliforms per
100 ml) by incubating one set of 10 replicate 100-ml sample
filtrations on the test medium (M-Endo or M-FC) and a second
set of 10 replicate 100-ml sample portions on a known satisfac-
tory lot of the same medium. Incubate at the appropriate tem-
perature for the test and count total coliform or fecal coliform
colonies on all membranes in each set. Verify all coliform col-
onies by transferring individual colonies to lactose or lauryl
tryptose broth for gas production at 35°C, then confirm in BGLB
broth at 35°C or EC broth at 44.5°C. Total all verified coliform
counts for each set of 10 replicates. For a satisfactory test
medium, the total verified coliform or fecal coliform colonies on
the 10 membrane replicates should be within ± 5 colonies of the
total colonies verified from the known medium lot (10). Poor
verification obtained on the test medium lot when compared
with the reference medium may indicate that traces of other
fermentable carbohydrates have contaminated the formulation
during manufacture or that overheating the medium during prep-
aration caused lactose hydrolysis.
2c. When evaluating standard pour plate agar (SPC agar), prepare
one set of 20 replicate pour plates using the unknown medium lot
and another set of 20 replicate pour plates using a known satis-
factory lot of SPC agar. Select a water sample containing a
bacterial population, either undiluted or diluted, of 100 to 150
organisms per ml. Avoid pipetting 0.1 ml sample portions to
minimize pipetting errors (11). Incubate all pour plates at 35°C
for 48 hours if the sample is from municipal drinking water
supplies or 35°C for 72 hours if bottled water samples are used.
82 Evaluating Water Bacteriology Laboratories/Geldreich
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Following incubation, determine colony counts for each set of
pour plates, then calculate the geometric mean value for each set
of 20 replicate counts. Colony counts on a satisfactory test
medium lot should be within ± 10 percent of the counts obtained
on a known reference medium lot.
MEDIA pH RECORDS
The pH of all batches of culture media should be checked after steriliza-
tion and the pH of each batch recorded with the date and medium lot
(control) number. As an absolute minimal requirement, the pH of at least
one batch of sterilized medium from each new bottle of commercial
medium must be determined to ensure its quality. By monitoring final
medium pH, a check can be made on possible errors in weighing, exces-
sive heating, and sterilization resulting in lactose hydrolysis, chemical
contamination, or deterioration of ingredients that might occur during
storage after stock packages are opened.
GENERAL CHEMICALS
All chemicals used in the preparation of culture media must be ACS
(American Chemical Society) or AR grade. This is particularly important
since some chemical impurities found in commercial and other lower
grades of chemicals can be present in large enough concentrations to
suppress or inhibit bacterial growth.
BACTERIOLOGICAL DYES
Dyes may differ in biological activity from lot to lot and from manufac-
turer to manufacturer. Information on dye technology indicates that
differences between lots of a given dye are related to the dye content
produced, the dye complex mixture present, and the amount of inert,
insoluble residues remaining in the product. Therefore, it is important
that all dyes used in the preparation of culture media be purchased from
lots certified by the Biological Stain Commission for bacteriological use.
STANDARD CULTURAL MEDIA SPECIFICATIONS
Media described in this section have been recognized as essential to the
measurement of total coliform and fecal coliform populations. The stand-
ard plate count is included because of its application to monitoring the
general bacterial quality of drinking water in distribution systems and in
bottled water supplies.
Lactose Broth (12)
Beef extract 3.0 gram
Peptone 5.0 gram
Lactose 5.0 gram
Distilled water 1,000 ml
Final pH after sterilizing (121°C for 12-15 min):
Single strength pH 6.9 ± 0.1
Double strength pH 6.7 ± 0.1
Single strength dehydrated medium, 13.0 grams per liter
The final concentration of ingredients in lactose broth after the addition
of the water sample must equal normal-strength broth. This presents no
CULTURE MEDIA SPECIFICATIONS 83
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problem when water-sample volumes of 1 ml or less are added to 10 ml of
single-strength broth. When 10 ml volumes of a water sample are
examined, however, the lactose broth must be double strength so that the
dilution of broth by the 10 ml sample will result in single-strength broth.
Thus, each milliliter in the planted tube contains the equivalent of 0.013
gram of dehydrated medium. A more dilute lactose-broth concentration
may result in a significant reduction in the recovery of attenuated coliform
organisms and a concurrent increase in slow fermentation reactions. The
net result is a reduced sensitivity for coliform detection.
Do not dispense medium volumes that are less than 10 ml into the larger
culture tubes (25- x 150-mm) used for examining 10-ml sample portions.
Such a practice would make these broth preparations subject to air
entrapment during handling or as the result of the rapid pipetting of 10-ml
sample volumes into the broth tube. Air entrapment creates a false
judgment that gas entrapment from bacterial fermentation has occurred.
Where irregular volumes are used, the quantity of dehyrated lactose
medium needed (grams per liter) may be calculated as follows:
(X) (ml broth) _
T.V.
where:
X = number of grams per liter in lactose broth
ml broth = milliliters of broth per sterile tube
T.V. = total volume of sterile broth plus water sample
added per tube, or
x = (13) (T.V.)
ml sterile lactose broth per tube
Therefore, lactose broth with 35 ml of broth and 100 ml of water sample
should contain 50.1 grams dehydrated lactose medium per liter. Table 3
illustrates the number of grams per liter of dehydrated medium required to
maintain a final single-strength concentration of lactose broth when used
with 1-, 10-, or 100-ml sample test portions.
TABLE 3. CONCENTRATIONS OF DEHYDRATED
LACTOSE BROTH REQUIRED TO MAINTAIN
THE PROPER CONCENTRATION OF
INGREDIENTS
Inoculum,
ml
1
10
10
100
100
100
Amount medium
10
30
20
50
35
20
in tube,
ml
or more
Vol. medium
and inoculum,
ml
1 1 or more
40
30
150
135
120
Dehydrated-lactose
broth required,
gram/liter
13
17.3
19.5
39.0
50.1
78.0
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Lauryl Tryptose Broth (13)
Tryptose 20 gram
Lactose 5 gram
Dipotassium hydrogen phosphate (K2HPO.,) 2.75 gram
Potassium dihydrogen phosphate (KH2POj) 2.75 gram
Sodium chloride 5 gram
Sodium lauryl sulfate 0.1 gram
Distilled water 1,000 ml
Final pH after sterilizing (121°C for 12-15 min):
Single strength pH 6.8 ± 0.1
Double strength pH 6.7 ± 0.1
Single strength dehydrated medium, 35.6 grams per liter
The final concentration of ingredients in lauryl tryptose broth, after the
additon of the water sample, must equal normal strength broth. When
10-ml volumes of a water sample are examined, lauryl tryptose broth must
be double strength so that the dilution of the broth by the 10-ml sample
will result in single-strength broth. Thus, each milliliter in the planted tube
contains the equivalent of 0.0356 gram per ml of dehydrated medium.
More dilute lauryl tryptose broth concentrations may result in significant
reduction in the recovery of attenuated coliform organisms and a signifi-
cant increase in slow fermentation reactions. The net result is a reduced
sensitivity for coliform detection.
Do not dispense medium volumes that are less than 10 ml into the larger
culture tubes (25- x 150-mm) used for examining 10-ml sample portions.
Such a practice would make these broth preparations subject to air
entrapment during handling or as the result of the rapid pipetting of 10-ml
sample volumes into the broth tube. Air entrapment creates a false
judgment that gas entrapment from bacterial fermentation has occurred.
Where irregular volumes are used, the quantity of dehydrated lauryl
tryptose broth needed (grams/liter) may be calculated as follows:
(X) (ml broth)
T.V.
where:
X = number of grams per liter in lauryl tryptose broth
ml broth = milliters of broth per sterile tube
T.V. = total volume of sterile broth plus water sample
added per tube, or
Y (35.6) (T.V.)
A =
ml lauryl tryptose broth per tube
Table 4 illustrates the number of grams per liter of dehydrated lauryl
tryptose broth required to maintain a single strength concentration of
lauryl tryptose broth when used with 1-, 10-, or 100-ml sample test
portions.
CULTURE MEDIA SPECIFICATIONS 85
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TABLE 4. CONCENTRATION OF DEHYDRATED LAURYL
TRYPTOSE BROTH REQUIRED TO MAINTAIN
THE PROPER CONCENTRATION
OF INGREDIENTS
Inoculum,
ml
1
10
10
100
100
Amount medium
in tube,
ml
10
20
30
50
35
Vol. medium
and inoculum,
ml
10
30
40
150
135
Dehydrated lauryl
tryptose broth required,
grams/liter
35.6
53.4
47.3
106.8
137.1
Brilliant Green Lactose Bile Broth (14)
Peptone 10 gram
Lactose 10 gram
Dehydrated Oxgall 20 gram
Brilliant green 0.0133 gram
Distilled water 1,000 ml
Final pH 7.2 ± 0.2 after sterilizing (12TC for 12-15 min)
Single strength dehydrated medium, 40 grams per liter
Dispense brilliant green lactose bile broth in no less than 10-ml volumes
per tube to ensure complete filling of the fermentation vial and to partially
submerge this vial at least halfway.
EC Medium(l5)
Tryptose or Trypticase 20 gram
Lactose 5 gram
Bile Salts mixture or Bile Salts No. 3 1.5 gram
Dipotassium hydrogen phosphate (K2HPO4) 4 gram
Potassium dihydrogen phosphate (KH2PO4) 1.5 gram
Sodium chloride 5 gram
Distilled water 1,000 ml
Final pH 6.9 ± 0.1 after sterilizing (121°C for 12-15 min)
Single strength dehydrated medium, 37 grams per liter
Dispense EC medium in no less than 10-ml volumes per tube to ensure
complete filling of the fermentation vial and to partially submerge this vial
at least halfway.
Eosin Methylene Blue Agar(l6)
Peptone ." 10 gram
Lactose 10 gram
Dipotassium hydrogen phosphate (K2HPO4) 2 gram
Agar 15 gram
Eosin Y 0.4 gram
Methylene blue 0.065 gram
Distilled water 1,000 ml
Final pH 7.1 ±0.1 after sterilizing (121°C for 12-15 min)
Single strength dehydrated medium, 37.5 grams per liter
R/i
Evaluating Water Bacteriology Laboratories/Geldreich
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The eosin methylene blue (EMB) agar of Holt-Harris and Teague, used
for isolation of intestinal pathogenic bacteria, should not be used in the
total coliform MPN completed test procedure. This medium contains
saccharose in addition to lactose; the saccharose can result in a significant
increase in noncoliform organisms appearing as coliform colonies on this
formulation of EMB agar. Levine EMB agar is recommended for confir-
mation or isolation of coliform bacteria from positive broth cultures as an
essential screening and purification step in the MPN completed test.
Endo Agar (17)
Peptone 10 gram
Lactose 10 gram
Dipotassium hydrogen phosphate (K2HPO4) 3.5 gram
Agar 15 gram
Sodium sulfite 2.5 gram
Basic fuchsin 0.4 gram
Distilled water 1,000 ml
Final pH 7.4 ± 0.1 (no autoclaving)
Single strength dehydrated medium, 41.5 grams per liter
Sterilization of the complete Endo agar at 121°C for 15 minutes is not
recommended. Excessive heat destroys the sodium sulfite; this destruc-
tion results in poor sheen development on coliform colonies. Therefore,
dissolve the agar preparation in a boiling water bath, cool to 45°C, and
pour the necessary plates. When this medium is properly prepared, all
coliform colonies growing on the surface from streak inoculation will
have a golden metallic sheen.
Another approach to the preparation of an excellent streak plate Endo
agar requires adding 1.5 percent agar to M-Endo medium. The medium is
then heated in a boiling water bath to dissolve the agar completely, and
pour plates are prepared with the usual precautions against contamination
and allowed to harden.
M-Endo Medium (18)
Tryptone or polypeptone 10 gram
Thiopeptone or thiotone 5 gram
Casitone or trypticase 5 gram
Yeast extract 1.5 gram
Lactose 12.5 gram
Sodium chloride 5 gram
Dipotassium hydrogen phosphate (K2HPO4) 4.375 gram
Potassium dihydrogen phosphate (KH2PO4) 1.375 gram
Sodium lauryl sulfate 0.05 gram
Sodium desoxycholate 0.1 gram
Sodium sulfite 2.1 gram
Basic fuchsin 1.05 gram
Distilled water containing 20 ml of ethanol 1,000 ml
Final pH 7.2 ± 0.1 (no autoclaving)
Single strength dehydrated medium, 48 grams per liter
The addition of pure grain ethanol to a final concentration of 2 percent
(V/V) to form alcohol esters is essential for the development of coliform
colonies with a maximum sheen and with less tendency toward confluent
CULTURE MEDIA SPECIFICATIONS 87
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growth. These esters tend to suppress significant numbers of noncoliform
organisms that could otherwise develop on the medium. Denatured
ethanol commonly available in the laboratory must not be used since the
denaturant commonly employed is either methanol or propanol, both of
which are toxic to coliforms.
When state laws or laboratory directives severely restrict the availabil-
ity of pure ethanol, a stock supply of ethanol for use in the MF procedure
may be technically denatured by adding a few grains of M-Endo powder.
The trace amount of basic fuchsin present in the small amount of dehy-
drated powder turns the ethanol pink, does not adversely affect the
M-Endo medium formulation, and nullifies the illegal use of the product
for human consumption.
Excessive heating of M-Endo medium destroys or reduces its specifici-
ty. Therefore, the medium is heated only to the boiling point (as described
in the section on Sterilization Procedures). As a general practice, only
enough M-Endo medium is prepared to meet anticipated daily needs.
However, surplus medium may be saved for use within a 96-hour period
provided the medium is stored in the dark at 2° to 10°C. Protected storage
in the dark is essential since M-Endo medium is sensitive to strong
artificial light or to direct sunlight.
One formulation of Endo medium known as LES Endo agar may be
prepared by adding 1.5 percent agar to 75 percent of the recommended
grams of M-Endo powder per 100 ml of distilled water. The mixture is
then heated in a boiling water bath to completely dissolve the agar and
poured in plates (60-mm Petri dishes) for use with a MF procedure.
M-FC Broth (19)
Tryptose or biosate 10 gram
Proteose peptone No. 3 or polypeptone 5 gram
Yeast extract 3 gram
Sodium chloride 5 gram
Lactose 12.5 gram
Bile salts No. 3 or bile salts mixture 1.5 gram
Aniline blue 0.1 gram
Distilled water containing 10 ml
of 1% rosolic acid salt reagent 1,000 ml
Final pH 7.4 ± 0.1 (no autoclaving)
Single strength dehydrated medium, 37 grams per liter
After the medium ingredients are in solution, 1 ml of a 1 percent rosolic
acid salt reagent is added and the medium is heated to the boiling point (as
described in the section on Sterilization Procedures). As a general prac-
tice, only enough M-FC broth is prepared to meet daily needs. However,
surplus medium may be saved for use within a 96-hour period provided
the medium is stored in the dark at 2° to 10°C.
The 1 percent rosolic acid salt reagent is prepared by dissolving 1 gram
of rosolic acid in 100 ml of 0.2 N sodium hydroxide (0.8 gram NaOH in 100
ml distilled water). Do not autoclave this solution. Rosolic acid salt
reagent should be stored at 2° to 10°C in the dark and must be discarded
after 2 weeks or sooner if the solution changes color from dark fed to
muddy brown or if, after the addition of the rosolic acid, the prepared
88 Evaluating Water Bacteriology LaboratorieslGeldreich
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medium is not the proper color. Background color on the MF will vary
from a yellowish cream to faint blue, depending on the age of the reagent.
When rosolic acid salt has been prepared within an hour or two of its
addition to the medium, it does have a differential effect on some of the
nonfecal coliform colonies. This phenomenon has been shown by the
development of yellow and red nonfecal coliform colonies from samples
of canal waters in the Chicago area. What the organisms were is not
known, but the important point is that only blue colonies verified as fecal
coliforms.
In M-FC broth, aniline blue is the indicator system used to detect
lactose fermentation, and development of the blue colony color does not
depend upon the addition of the rosolic acid salt reagent. The sodium salt
of rosolic acid is added to the medium to supress a variety of nonfecal
coliform organisms, which may grow at the elevated temperature and
which are common to some specific source waters and the first flush of
stormwater runoff. Without the inhibitory effect of the rosolic acid salt, a
substantial background growth of white- to gray-colored colonies may
develop and cause interference with the discrete growth of the blue-
colored fecal coliform colonies.
M-VFC Holding Medium (20)
Vitamin-free casitone 0.2 gram
Sodium benzoate 4.0 gram
Sulfanilamide 0.5 gram
Ethanol (95%) 10.0 ml
Distilled water 1,000 ml
Final pH 6.7 ± 0.1 (no autoclaving)
Single strength dehydrated medium, 4.7 grams per liter
Warm to dissolve all ingredients, then sterilize the medium by filtration
through an 0.22-micron MF. If only 100 ml of the medium are prepared, it
is easier to add the vitamin-free casitone as 2 ml of a 1:100 aqueous
solution. Store the finished medium at 2° to 10°C, and discard any unused
portions after 1 month's storage.
M-7-Hour Agar (21)
Proteose peptone No. 3 or polypeptone 5.0 gram
Yeast extract 3.0 gram
Lactose 10.0 gram
Mannitol 5.0 gram
Sodium chloride 7.5 gram
Sodium lauryl sulfate 0.2 gram
Sodium desoxycholate 0.1 gram
Brom cresol purple 0.35 gram
Phenol red 0.3 gram
Agar 15.0 gram
Distilled water 1,000 ml
Adjust final pH to 7.3 ± 0.1; approximately 0.35 ml of 0.1 N NaOH
is required (no autoclaving).
Single strength dehydrated medium, 41.45 grams per liter
Heat the medium in a boiling water bath to dissolve the agar. After
solution is complete, heat for an additional 5 minutes and then place in a
CULTURE MEDIA SPECIFICATIONS 89
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44.5°C water bath to temper heat before pouring the plates. Dispense 4 to
5 ml of the agar into 50- x 3 i-mm tight-fitting culture dishes, and allow to
solidify. The medium may be stored at 2° to .1 CC for periods up to 30 days
before use.
M-PA Agar Base (22)
L-lysine hydrochloride 5-° eram
Sodium chloride 5-° 8ram
Yeast extract 2.0 g""am
Xylose 2.5 gram
Sucrose 1-25 gram
Lactose 1-25 gram
Phenol red 0.08 gram
Ferric ammonium citrate 0-8 gram
Sodium thiosulfate 6.8 gram
Agar 15.0 gram
Distilled water 1,000 ml
Autoclave at 121°Cfor 15 minutes; cool mixture to between 55° to 60°C;
adjust pH to 7.2 ±0.1; and add the following dry antibiotics:
Sulfapyridine 176.0 mg
Kanamycin 8.5 mg
Nalidixic acid 37.0 mg
Cycloheximide (Actidione) 150.0 mg
M-PA agar base 1,000 ml
Dispense medium in 3-ml quantities to 50- x 12-mm Petri plates. Poured
plates of the medium can be stored at 2° to 10°C for 1 month.
KF Streptococcus Agar (23)
Proteose peptone No. 3 or polypeptone 10.0 gram
Yeast extract 10.0 gram
Sodium chloride 5.0 gram
Sodium glycerophosphate 10.0 gram
Maltose 20.0 gram
Lactose 1.0 gram
Sodium azide 0.4 gram
Brom cresol purple 0.015 gram
Agar 20.0 gram
Distilled water 1,000 ml
Final pH 7.2 ± 0.1 (no autoclaving)
Single strength dehydrated medium, 76.4 grams per liter
Heat the medium in a boiling water bath to dissolve the agar. After
solution is complete, continue heating for an additional 5 minutes. Cool
medium to between 50° and 60°C and add 1 ml of sterile aqueous 1 percent
solution of 2, 3, 5-triphenyltetrazolium chloride (available from either
Difco or BBL) per each 100 ml of medium. Adjust the pH of the final
medium to 7.2 with 10 percent sodium carbonate, if necessary. The fluid
medium may be stored up to 4 hours in a water bath at 45° to 48°C before
preparing plates.
For use with the MF technique, dispense 4 to 5 ml of the agar into 50- x
12-mm tight-fitting culture dishes, and allow to solidify. KF Streptococ-
cus agar may be used immediately or stored in a cool, dark place and used
any time within 2 weeks provided no dehydration has occurred.
90
Evaluating Water Bacteriology LaboratoriesIGeldreich
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Pfizer Selective Enterococcus (PSE) Agar (24)
Peptone C 17.0 gram
Peptone D 3.0 gram
Yeast extract 5.0 gram
Bacteriological bile 10.0 gram
Sodium chloride 5.0 gram
Sodium citrate 1.0 gram
Esculin 1.0 gram
Ferric ammonium citrate 0.5 gram
Sodium azide 0.25 gram
Agar 15.0 gram
Distilled water 1,000 ml
Final pH 7.1 ± 0.1 after sterilizing (121°C for 12-15 min)
Heat the PSE agar suspension to boiling; stir frequently to dissolve the
medium completely. After solution, sterilize medium at 121°C for 15
minutes. The medium may be held at 45° to 50°C for up to 4 hours before
preparing pour plates.
Plate Count Agar (Tryptone Glucose Yeast Agar)
' (25)
Tryptone 5 gram
Yeast extract 2.5 gram
Glucose 1 gram
Agar 15 gram
Distilled water 1,000 ml
Final pH 7.0 ± 0.1 after sterilizing (121°C for 12-15 min)
Single strength dehydrated medium, 23.5 grams per liter
Melt sterile supplies of plate count agar in a boiling water bath, and hold
at 45°C until needed in the pour plate procedure. Remelting the plate
count agar a second time or holding liquid supplies of this sterile agar for
periods longer than 3 hours is undesirable because chemical precipitates
may form and interfere with discernment of colony development.
Minimal Growth Medium for Suitability Test (26)
Sodium citrate (Na3C6H5O7 • 2H2O) 0.005 gram
Ammonium sulfate 0.010 gram
Magnesium sulfate (MgSO4 7H2O) 0.004 gram
Calcium chloride (CaCl2 • 2H2O) 0.003 gram
Ferrous sulfate (FeSO4 • 7HZO) 0.004 gram
Sodium chloride 0.042 gram
Potassium dihydrogen phosphate 0.340 gram
Distilled water or test water 100 ml
Final pH 7.0 ± 0.2 (pH may vary as a reflection of test water)
Prepare the medium with high-purity chemicals. Sterilize medium by
boiling 1 to 2 minutes or by MF filtration (0.22-micron pore size). Steam
generated in autoclaving will introduce varying trace chemical impurities
to this minimal growth medium for Enterobacter aerogenes. The medium
may be prepared as per Standard Methods for the distilled water suitabil-
ity test or as a complete medium for use in testing plastic items that might
be releasing toxic substances.
REFERENCES
1. Difco Laboratories. General Conditions Pertaining to the Cultivation of Micro-
organisms; and, Preparation of Media from Dehydrated Culture Media. Difco Manual.
9th Edition. Difco Laboratories, Detroit, Mich. p. 16-22 (1953).
CULTURE MEDIA SPECIFICATIONS 91
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2. Baltimore Biological Laboratories. General Suggestions for Use of Media:
Dehydrated-Prepared. BBL Manual of Products and Laboratory Procedures. 5th ed.
BBL, Division of Becton Dickinson and Co., Cockeysville, Md. p. 88 (1968).
3. Oxoid, Ltd. General Guide to the Use of Oxoid Products. The Oxoid Manual of Culture
Media, Ingredients and Other Laboratory Services. 3rd ed. Oxoid Limited, London p.
13-18 (1971).
4. Elliott, E. C., and Georgala, D. L. Sources, Handling and Storage of Media and
Equipment, Chapter I. In: Methods in Microbiology, Vol. I. J. R. Morris and D. W.
Ribbons, Eds. Academic Press, Inc., New York p. 1-20 (1969).
5. Archambault, J., and McCrady, M. H. Dissolved Air as a Source of Error in Fermenta-
tion Tube Results. Amer. Jour. Pub. Health 32:1164-1168 (1942).
6. Bridson, E. Y., and Brecker, A. Design and Formulation of Microbial Culture Media.
Chapter III. In: Methods in Microbiology, Vol. 3A. J. R. Morris and D. W. Ribbons,
Eds. Academic Press Inc., New York p. 229-295 (1970).
7. Karlstrom, A., Brandon, G. R., and Levin, W. Some Observations on the Use of
Dehydrated Culture Media. Pub. Health Lab. 15:175-177 (1957).
8. Vera, H. D. Quality Control in Diagnostic Microbiology. Health Lab. Sci. 8: 176-189
(1971).
9. Difco Laboratories. Quality Control of Culture Media 40 p. Detroit, Mich. (February
1975).
10. McCarthy, J. A., Thomas, H. A., Jr., and Delaney, J. E. Evaluation of the Reliability of
Coliform Density Tests. Amer. Jour. Pub. Health 48:1628-1635 (1958).
11. Pessin, V., and Black, L. A. A Comparative Study of Six Agars Proposed for Bacterial
Plate Counts of Milk. Jour. Milk & Food Technol. 14:98-102 (1951).
12. Butterfield, C. T. Experimental Studies of Natural Purification in Polluted Waters. Part
III. A Note on the Relation Between Food Concentration in Liquid Media and Bacterial
Growth. Pub. Health Repts. 44:2865-2872 (1929).
13. Mallmann, W. L., and Darby, C. W. Uses of aLauryl Sulphate Tryptose Broth for the
Detection of Coliform Organisms. Amer. Jour. Pub. Health 31:127-134 (1941).
14. McCrady, M. H. A Practical Study of Procedures for the Detection of the Presence of
Coliform Organisms in Water. Amer. Jour. Pub. Health 27:1243-1258 (1937).
15. Hajna, A. A., and Perry, C. A. Comparative Study of Presumptive and Confirmative
Media for Bacteria of the Coliform Group and for Fecal Streptococci. Amer. Jour. Pub.
Health 33:550-556 (1943).
16. Levine, M. Further Observations on the Eosin-Methylene Blue Agar. Jour. Amer.
Water Works Assoc. 8:151-156 (1921).
17. Levine, M. A Simplified Fuchsin Sulphite (Endo) Agar. Amer. Jour. Pub. Health
8:864-865 (1918).
18. Fifield, C. W. and Schaufus, C. P. Improved Membrane Filter Medium for the Detec-
tion of Coliform Organisms. Jour. Amer. Water Works Assoc. 50:193-196 (1958).
19. Geldreich, E. E., Clark, H. F., Huff, C. B., and Best, L. C. Fecal Coliform Organism
Medium for the Membrane Filter Technique. Jour. Amer. Water Works Assoc. 57:208-
214 (1965).
20. Taylor, R. H., Bordner, R. H., and Scarpino, P. V. Delayed Incubation Membrane
Filter Test for Fecal Coliforms. Appl. Microbiol. 25:363-368 (1973).
21. Geldreich, E. E., Blannon, J., and Reasoner, D. J. A Rapid (7 hour) Membrane Filter
Fecal Coliform Test for Monitoring Recreational Water and Water Supplies During
Emergencies (in preparation).
22. Levin, M. A., and Cabelli, V. J. Membrane Filter Technique for Enumeration of
Pseudomonas aeruginosa. Appl. Microbiol. 24:864-870 (1972).
23. Kenner, B. A., Clark, H. F., and Kabler, P. W. Fecal Streptococci. Cultivation and
Enumeration of Streptococci in Surface Waters. Appl. Microbiol. 9:15-20 (1961).
24. Isenberg, H. D., Goldberg, D., and Sampson, J. Laboratory Studies with a Selective
Enterococcus Medium. Appl. Microbiol. 20:433-436 (1970).
25. Buchbinder, L., Boris, Y., and Goldstein, L. Further Studies on New Milk Free Media
for the Standard Plate Count of Dairy Products. Amer. Jour. Pub. Health 43:869-872
26. Geldreich, E. E., and Clark, H. F. Distilled Water Suitability for Microbiological
Applications. Jour. Milk & Food Technol. 28:351-355 (1965).
92
Evaluating Water Bacteriology LaboratorieslGeldreich
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GUIDELINES ON CULTURE MEDIA SPECIFICATIONS
Media Preparation
Chemically clean glassware or stainless-steel utensils used
Freshly distilled or boiled distilled water used in media preparation
Complete solution obtained before dispensing to culture tubes or bottles . .
Total time from media preparation to sterilization less than 2 hours
Media pH Measurements
Electronic pH meter calibrated against appropriate standard buffer
Standard buffer brand pH
pH of each sterile medium batch checked
A pH record of each sterile batch, the date, and lot number maintained . ..
Causes for deviations beyond ± 0.1 pH unit investigated and
corrective action taken
Media Storage
Dehydrated media bottle kept tightly closed and protected from dust and
excessive humidity in storage areas
Dehydrated media discarded if discolored or caked
Dehydrated supplies dated Shelf life not to exceed 1 year
Sterile batches not in tubes or bottles with screw-caps used in less than 1 week
All media protected from sunlight
Media stored at low temperatures is incubated overnight and tubes with
air bubbles discarded
Media Quality Control
Media for detecting total coliforms, fecal coliforms, and standard plate
count quality tested
Media performance measured by natural water samples
MPN — comparative results of positive tubes
MF — comparative coliform colony count
Standard plate count — comparative replicate pour plates
Laboratory chemicals of analytical reagent grade
Bacteriological dyes certified for bacteriological use
Lactose Broth
Manufacturer Lot No..
Single strength composition, 13 grams per liter distilled water
Single strength, pH 6.9 ±0.1; double strength, pH 6.7 ± 0.1
Not less than 10 ml medium per tube
Medium, after 10-ml sample is added, contained 0.013 gram per
ml dry ingredients
Lauryl Tryptose Broth
Manufacturer Lot No..
Single strength composition, 35.6 grams per liter distilled water ....
Single strength pH, 6.8 ±0.1; double strength pH, 6.7 ± 0.1
Not less than 10 ml medium per tube
Medium, after 10-ml sample is added, contained 0.0356 gram per
ml of dry ingredients
Brilliant Green Lactose Bile Broth
Manufacturer Lot No..
Medium composition 40 grams per liter distilled water
Final pH, 6.9 ± 0.2
Not less than 10 ml medium per tube
MULTIPLE TUBE COLIFORM PROCEDURES 93
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EC Medium
Manufacturer Lot No-
Medium composition, 37 grams per liter distilled water
Final pH, 6.9 ± 0.1
Not less than 10 ml medium per tube
Eosin Methylene Blue Agar
Manufacturer . Lot No-
Medium contains no sucrose; Cat. No.
Medium composition, 37.5 grams per liter distilled water
Final pH, 7.1 ±0.1
Not less than 10 ml medium per standard Petri dish
Endo Agar
Manufacturer Lot No._
Medium composition, 41.5 grams per liter distilled water
Medium sterilized 10 minutes at 121°C or melted in boiling water bath
without further heating
Agar prepared from M-Endo plus 1.5 percent agar
Final pH, 7.3 ±0.1
Not less than 10 ml medium per standard Petri dish
M-Endo ME Medium
Manufacturer Lot No._
Medium composition, 48.0 grams per liter distilled water
Reconstituted in distilled water containing 2 percent ethanol
Pure ethanol used (not denatured)
Heated to boiling point, promptly removed and cooled
Final pH, 7.2 ± 0.1
Stored in dark at 2° to 10°C
Unused medium discarded after 96 hours
M-FC Broth
Manufacturer Lot No._
Medium composition, 37.0 grams per liter distilled water
Reconstituted in 100 ml distilled water containing 1 ml of a 1 percent
rosolic acid reagent
Stock solution of rosolic acid discarded after 2 weeks or when red color
changed to muddy brown
Heated to boiling point, promptly removed, and cooled
Final pH, 7.4 ±0.1
Stored in dark at 2° to 10°C
Unused medium discarded after 96 hours
M-VFC Holding Medium
Manufacturer.^ Lot No._
Medium composition, 4.7 grams per liter distilled water
Reconstituted in distilled water containing 1 percent ethanol
Final pH, 6.7 ± 0.1
Stored in dark at 2° to 10°C
Unused medium discarded after 30 days
M-7-Hour Agar
Manufacturer Lot No
Medium composition, 41.45 grams per liter distilled water
Final pH adjusted to 7.3 ± 0.1
94
Evaluating Water Bacteriology LaboratoriesIGeldreich
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Heated in boiling water bath to dissolve agar
Four to five ml dispensed into tight fitting culture dishes (50- x 12-mm)
Stored in dark at 2° to 10°C
Unused medium discarded after 30 days
M-PA Agar
Manufacturer Lot No._
Medium base composition, 39.68 grams per liter distilled water
Sulfapyridine (176.0 mg); Kanamycin (8.5 mg); nalidixic acid (37.0 mg);
and Actidione (150.0 mg) added per liter of M-PA agar base
Final pH, 7.2 ± 0.1
Four to five ml dispensed into tight fitting culture dishes (50- x 12-mm)
Stored in dark at 2° to 10°C
Unused medium discarded after 30 days
KF Streptococcus Agar
Manufacturer Lot No
Medium composition, 76.4 grams per liter distilled water
Heated in boiling water bath to dissolve agar
Cooled to 50° to 60°C and 2,3,5 triphenyltetrazolium chloride added
Final pH, 7.2 ± 0.1
Placed in holding bath at 50° to 60°C for no more than 4 hours
before pouring plates
Four to five ml dispensed into tight fitting culture dishes
(50- x 12-mm) for MF use
Stored in dark at 2° to 10°C
Unused medium discarded after 30 days
PSE Agar
Manufacturer Lot No._
Medium composition, 57.75 grams per liter distilled water
Heated to boiling to dissolve the medium completely
Sterilized at 12TC for 15 minutes
Final pH, 7.1 ± 0.1
Remelted in boiling water bath and placed in holding bath at 50° to 60°C
for no more than 4 hours before pouring plates
Plate Count Agar
Manufacturer Lot No._
Medium composition, 23.5 grams per liter
Final pH, 7.0 ± 0.1
Free from precipitates
Sterile medium not remelted a second time after sterilization
Placed in holding bath at 50° to 60°C for no more than 4 hours
before pouring plates
_Broth
Manufacturer Lot No._
Correct composition and pH
Purpose
-Agar
Manufacturer Lot No._
Correct composition and pH
Purpose
MULTIPLE TUBE COLIFORM PROCEDURES 95
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CHAPTER VII
MULTIPLE TUBE COLIFORM PROCEDURES
The multiple tube coliform test has been a standard method for deter-
mining coliform quantification since 1936 (1). In this procedure, replicate
tubes of lactose broth orlauryl tryptose broth are inoculated with decimal
dilutions of a water sample. The coliform density is then calculated from
probability formulas that predict the most probable number of coliforms
necessary to produce certain combinations of gas-positive and gas-
negative tubes in replicate decimal dilutions. McCrady first introduced
the Most Probable Number (MPN) concept for estimating bacteria in 1915
(2), and this principle was later refined by Hoskins through the develop-
ment of MPN tables (3).
TOTAL COLIFORM MPN PROCEDURE
During the evolution of the multiple tube procedure for the determina-
tion of total coliform density, it became apparent that three distinct test
stages must be considered: the presumptive test, confirmed test, and
completed test. In the presumptive test, the metabolic activity of at-
tenuated bacteria are stimulated to greater vigor and a gross selection for
lactose-utilizing organisms occurs. After incubation at 35°C, culture from
each gas-positive presumptive tube is transferred into a tube of medium
for the confirmed test. The confirmed test reduces the possibility of false
gas-positive results occurring because of the metabolic activity of spore
formers or the synergistic production of gas by some bacterial strains
that, individually, cannot produce gas from lactose fermentation. To
verify that the confirmed test does selectively eliminate all false positive
tube results, it will occasionally be necessary to isolate these gas-
producing bacteria and identify them as coliforms by the completed test
procedure. The demonstration that the gas-producing isolates are gram
negative, non-spore-forming, rod-shaped bacteria capable of gas produc-
tion in a secondary lactose broth tube is conclusive evidence of the
presence of coliforms and substantiates the reliability of the confirmed
test.
CHOICE OF MULTIPLE DILUTIONS
Analysis of potable water by the multiple tube test consists of inoculat-
ing five tubes of presumptive medium with either 10-ml or 100-ml sample
portions. In most cases, the inoculation of single-strength presumptive
medium with 1.0- and 0.1-ml volumes of a potable water sample is of little
additional value since the expected coliform density should be less than
10 organisms per 100 ml and is most often less than 2 coliforms per 100 ml.
When the multiple tube test is used for surface water quality studies, a
minimum of three decimal dilutions must be used to ensure that quantita-
MULTIPLE TUBE COLIFORM PROCEDURES 97
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tive data are obtained. In the absence of previous bacteriological data on
the sample, it is necessary to use a five-decimal-dilution multiple tube
test, to provide reasonable certainty of obtaining a break point between
gas-positive and gas-negative tubes. Test results in which tubes at all
dilutions are positive indicate only that the coliform density was greater
than the upper limit of the test dilutions used and, therefore, are of no
value in subsequent statistical analysis.
Decisions concerning choice of dilutions to be used in the multiple tube
test must relate to information supplied with the sample. Suggested
starting dilutions for a variety of samples are given in Table 5. When the
water samples are part of a pollution survey or monitoring program,
repeated sampling from the same locations may indicate the need to
adjust the multiple tube decimal dilution series to obtain a more even split
of positive and negative tube results. Repeated sampling will also estab-
lish an expected coliform range for each sample. This range may be fairly
constant or may fluctuate with stormwater runoff, sudden discharge of
industrial wastes, or sewage treatment bypass. In situations where the
coliform density fluctuates widely, five decimal dilutions are necessary to
prevent overruns of all positive tube results and loss of meaningful data.
Samples that have more limited fluctuation may be tested using a three-
decimal dilution multiple tube test.
TABLE 5. SUGGESTED STARTING DILUTIONS FOR MULTI-
PLE TUBE TOTAL COLIFORM EXAMINATIONS
OF VARIOUS NATURAL WATER QUALITIES
Starting dilutions (ml) for a
0 . three-dilution multiple tube test
Sample source
10 1 0.1 0.01 0.001
Wells x*
Creeks
Rivers
Sewages
Chlorinated
Secondary treatment
Primary treatment
Raw, municipal
*x = starting dilution; x - - - x = alternate choices
PRELIMINARY TEST PREPARATIONS
Preliminary preparation for MPN tests in the laboratory should include
placing the lactose broth or lauryl tryptose broth tubes in test tube racks
and labeling at least one tube in each row with the laboratory sample
number. When samples to be examined require multiple dilutions, one or
more tubes in each dilution should be labeled so as to avoid errors when
confirming positive tubes or recording results.
98 Evaluating Water Bacteriology LaboratorieslGeldreich
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The tube code shown in Table 6 may be helpful in minimizing identifica-
tion errors and reducing the amount of wax pencil marks to be removed in
the glassware washing process. Other coding schemes are acceptable
provided they establish positive identification of sample volumes and are
fully comprehended by all members of the laboratory staff assigned to
examine water samples.
TABLE 6. A TEST TUBE CODING SCHEME
Inoculated volumes (ml) Individual culture tube codes
10 A, B, C, D, E
1 a, b, c, d, e
0.1 a, b, c, d, e
0.01 la,Ib,lc,ld, le
0.001 2a,2b,2c,2d,2e
0.0001 3a,3b,3c,3d,3e
PRESUMPTIVE TEST PROCEDURE
All water samples must be shaken vigorously, preferably in an inverted
position, immediately before removing sample aliquots to inoculate a
series of presumptive tubes in the multiple tube test. Vigorous shaking
ensures a homogeneous distribution of bacteria suspended in the water
sample and is of particular concern in the examination of highly turbid
waters. Paniculate matter in water rapidly settles out; this pulls sus-
pended bacteria into the bottom sediment and, thereby, creates an un-
even distribution of the bacterial population.
Greater accuracy in pipetting sample aliquots is achieved when 10-ml
pipets are used to deliver only 10-ml amounts, 2-ml or 1-ml pipets are used
to measure 1-ml portions, and only 1-ml pipets (graduated in 0.1-ml
increments) are used to deliver 0.1-ml sample volumes. Sample volumes
of 0.01 ml or smaller are prepared by decimal dilutions of 1 ml of the
original water sample as shown in Figure 1. In withdrawing sample
portions, the tip of the pipet should never be submerged more than 1 inch
below the surface of the sample. This procedure minimizes the accumula-
tive drainage from the exterior of the pipet into the medium and also
prevents particles from being picked up from the bottom sediment that
could introduce a significant clump of bacteria—a clump not representa-
tive of the bacteria in the water sample or of their distribution.
When adding sample aliquots into culture tubes, the pipet tip should be
close to the surface of the broth to avoid impingement of droplet portions
on the culture tube side walls and to ensure complete transfer of the
sample aliquot into the culture medium. As a further precaution, it is
suggested that each tube be mixed by a gentle shake or swirl as it is
inoculated, so that the inoculum is mixed quickly and completely with the
broth. After all the dilutions for one sample have been inoculated, the
culture tube rack of inoculated presumptive broth tubes must be placed in
the incubator within 30 minutes.
MULTIPLE TUBE COLIFORM PROCEDURES 99
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to
O
n
o'
f
Dilution Ratios: 1:100
1 ml /gg m)\
1 ml
Delivery volume 10ml 1ml O.lml 1ml 0.1ml
ooooo
1:10,000
Tubes
Petri Dishes or Culture Tubes
Actual volume 10ml 1ml 0.1ml 0.01ml 0.001ml 0.0001ml 0.0,0001ml
sample in tube
Figure 1. Preparation Of Dilutions
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The initial reading of presumptive tubes should be made after 24 hours
± 2 hours. Although this incubation time requirement may place the
initial test observation in the afternoon, it is advantageous to gently shake
all culture racks while in the incubator during the morning period. This
procedure speeds up the release of gas into the fermentation tubes from
the surrounding gas-saturated broth cultures. All tubes should be again
shaken gently just before observations are recorded in the presumptive
24-hour column of the sample sheet or card.
Each tube should be examined carefully. Those tubes showing gas in
the fermentation vial are recorded as positive (+), promptly submitted to
the confirmatory procedure, and then discarded. Gas in any quantity
(including tiny bubbles) is recorded as positive. It is essential that all
positive tubes be confirmed at the end of the initial 24-hour period regard-
less of the amount of gas produced. The practice of not confirming
positive lactose or lauryl tryptose broth tubes until the end of the 48-hour
period is not acceptable. Because of the mixed bacterial flora competing
with coliforms, particularly stressed coliforms, in the presumptive
medium, tubes that are gas positive at 24 hours and contain coliforms
frequently give negative results when confirmed after 48 hours incuba-
tion. Failure of 48-hour tubes to confirm may be due to low pH or to the
antagonistic action of other organisms in the heterogeneous bacterial
flora.
Lactose broth and lauryl tryptose broth yield equivalent recoveries of
coliforms in the presumptive test. However, lauryl tryptose broth sup-
presses the development of aerobic sporeforming organisms that often
ferment lactose with gas production. Therefore, when an analysis of
laboratory data indicates that approximately 20 percent or more of the
presumptive positive lactose tubes fail to confirm as coliforms, the use of
lauryl tryptose broth should be investigated as a substitute presumptive
medium. Parallel tests using lactose broth and lauryl tryptose broth on the
variety of waters normally tested in the laboratory may reveal a marked
reduction in false-positive presumptive tubes with the use of lauryl tryp-
tose broth (4). This results in a savings of labor, materials, and time, plus a
more rapid reporting of negative results. Evaluation of data from some
types of water samples may, however, reveal little or no benefit in using
lauryl tryptose broth to reduce false-positive presumptive tube occur-
rences. Therefore, since lauryl tryptose broth is somewhat more expen-
sive, lactose broth may be preferred, all other factors being equal. The
final choice of presumptive medium should await actual evaluation of a
variety of water samples normally examined by the laboratory.
The amount of gas produced in presumptive tubes should not be the
criterion for a positive test. Large-volume gas production in lactose or
lauryl tryptose broth may be a result of several factors including the
occurrence of noncoliform, spore-forming organisms. Conversely, active
lactose-fermenting coliforms may be suppressed by the presence of
specific soil organisms with the result that only a small bubble of gas may
be produced within 48 hours. Antagonistic action of pseudomonads and
other organisms (5-10) present in the bacterial flora can also suppress
coliform growth so that the minimum concentration of cells (40 to 390
millions of cells per ml) required to produce visible gas in the presumptive
MULTIPLE TUBE COLIFORM PROCEDURES 101
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medium is not obtained within the normal incubation time (11). The
concentration of nitrate in some groundwater supplies may equal or
exceed the 30 to 60 ppm range—a concentration shown to suppress gas
production by coliform bacteria (12). For these reasons, it may be risky to
disregard slow or weak lactose fermenters when assessing water quality.
Culture tubes not showing gas are recorded as a negative (-) results and
returned for an additional 24-hour incubation period. At the conclusion of
the second incubation period (24 hours), these cultures are again in-
spected for evidence of gas production. Any additional positive tubes are
recorded and then submitted to the confirmatory procedure before dis-
card. Those cultures showing no gas production are recorded as negative
in the 48-hour presumptive column and then discarded.
CONFIRMED TEST PROCEDURE
Although the occurrence of gas production in the presumptive test
indicates the probable presence of coliform bacteria, other organisms
may be responsible for this gas production. Thus, all positive presumptive
tubes must be submitted to a more selective test following enrichment in
lactose or lauryl tryptose broth. BGLB broth used in the selective or
confirmatory test can not be inoculated with the water sample directly
because of significantly greater toxicity to attenuated coliforms.
The BGLB confirmatory procedure consists of transferring a small
inoculum of culture from each positive presumptive tube to individual
BGLB broth tubes and incubating them at 35°C for 48 hours. Gas produc-
tion in BGLB broth tubes verifies that coliform bacteria are indeed
present in the water sample examined.
When examining potable water, all gas-positive presumptive tubes are
submitted to the confirmatory procedure. In water pollution and effluent
examinations, however, the confirmation procedure may be modified if,
after 24 hours of incubation, all five replicate tubes are gas positive for
two or more consecutive sample volumes. With polluted waters or waste
effluents, the set of five replicates representing the smallest volume of
sample in which all tubes are gas positive is confirmed plus all other gas
positive tubes from smaller sample volumes (higher sample dilutions) in
which some tubes were positive and some were negative. This modifica-
tion in the confirmatory procedure is predicated on the assumption that all
five positive tubes in the lowest sample dilution would confirm if they
were submitted to the confirmed test. Before transferring cultures from
positive presumptive tubes to BGLB broth, the rack of cultures or each
individual culture should be gently agitated to obtain a uniform bacterial
suspension. Employ a sterile technique and, using an inoculating loop or
an applicator, transfer an inoculum of gas-positive broth from the pre-
sumptive tube to a tube of BGLB broth labeled to correspond with the
appropriate positive presumptive tube. Place each inoculated BGLB
culture tube into the test rack position originally occupied by the pre-
sumptive positive tube. After making the transfers, the rack will probably
contain some 24-hour negative presumptive tubes and the inoculated
BGLB tube additions. Incubate all tubes at 35°C ± 0.5°C and check after
24 hours for gas production in the BGLB tubes and 48-hour presumptive
moes. Kecord BGLB tubes with gas production as positive and those
Evaluating Water Bacteriology Laboratories/Geldrfich
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tubes without gas as negative in the "24-hour confirmatory column" on a
bacteriological report form. Record 48-hour presumptive tubes as nega-
tive or positive, and transfer growth from positive tubes into BGLB
broth. Reincubate negative BGLB tubes for an additional 24 hours along
with the newly inoculated BGLB tubes. Record results of the 48-hour
BGLB tubes and any 24-hour BGLB tubes. Negative 24-hour BGLB
tubes must be incubated an additional 24 hours and the results recorded
before the test is concluded. Then calculate the MPN value from the
combination of confirmed positive results and those negative confirmed
and presumptive tubes. Record the calculated coliform density based on
100 ml of sample. When potable waters are examined, it is also permissi-
ble to report only the positive tube results rather than an MPN value. The
entire test time may require a maximum of 96 hours when gas production
is slow or a minimum of 48 hours if all tubes are negative in the presump-
tive test.
COMPLETED TEST PROCEDURE
The completed test is the reference standard for the multiple tube
procedure. Since the confirmed test may yield positive reactions in the
absence of the coliform group (false-positive test), it is essential that
periodic comparisons be made with the reference standard to verify data
reliability. The number of comparative procedures required to establish
the validity of the confirmed test will be determined by the frequency of
interferences from the water flora. Approximately 20 tests during each
3-month period should be sufficient where good agreement with the
completed test is determined. For comparative testing, the samples
selected should include all public water samples that are found to contain
coliforms by the confirmed test. Since few municipal water samples will
be found that contain measurable densities of coliforms, to obtain the
minimum of 20 positive confirmed tests for processing through the com-
pleted test, use positive confirmed tests from raw water intakes for water
treatment plants and private wells. The number of comparative tests
should be increased whenever the sanitary interpretation of the results is
questionable, and an investigation should be made to discover and correct
the discrepancy. A quality control test of the BGLB may reveal poor
medium selectivity. Additionally, the wrong concentration of BGLB
medium or its exposure to light during storage or excessive heat during
sterilization may be the cause of false-positive reactions in the confirmed
procedure.
The completed test is applied to all gas-positive BGLB tubes in the
individual test. It is permissible to assume that positive EC tube results
from the fecal coliform portion of a double confirmation (BGLB tube for
total coliform verification and EC tube for fecal coliform determination)
are evidence of coliform presence. Therefore, the confirmatory tube
should be recorded as a positive completed test response. All other
confirmation positive BGLB tubes, which are not paralled with positive
EC cultures, must be submitted to pure culture isolations on EMB or
Endo agar streak plates (incubated at 35°C for 24 hours) then verified as
lactose fermenting gram negative bacilli—the prerequisite to identifica-
tion of coliforms in the completed test. In this procedure, an inoculum
MULTIPLE TUBE COLIFORM PROCEDURES 103
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from each individual gas-positive confirmed tube is streaked to a plate of
EMB or Endo agar (labeled to correspond with the confirmed tube) to
obtain discrete colonies separated by approximately 0.5 cm or more.
Since the observation of isolated colonies is mandatory for this procedure
to be valid, subdivision of the plate area to permit confirmation of several
positive BGLB tubes significantly restricts the probability of obtaining
isolated colonies. Therefore, a maximum of two positive confirmatory
tubes may be streaked onto one agar plate that has been divided into equal
portions. After streaking, the agar plates are incubated at 35° ± 0.5°Cfor
24 ± 2 hours.
Following incubation, each EMB or Endo agar plate is examined for
bacterial growth and colony appearance. Well-isolated colonies having a
dark center (nucleated or "fisheye") are regarded as typical coliform
colonies. These typical colonies may or may not have a metallic surface
sheen. Colonies that are pink or opaque and not nucleated are considered
atypical colonies but may be coliforms. Clear, watery colonies are not
considered coliforms and are recorded as negative in the completed test.
To proceed with the completed test, an isolated colony (either typical
or atypical) from each plate is then inoculated into tubes of lactose or
lauryl tryptose broth to demonstrate lactose fermentation within 48 hours
at 35°C and to agar slants to use in preparing a Gram stain after 18 to 24
hours incubation at 35°C.
The Gram stain must be prepared from an actively growing culture,
preferably about 18 hours old and never more than 24 hours old. Prepara-
tions made from older cultures often result in unsatisfactory, irregular
staining reactions. Clean glass slides, free of any trace of oily film, should
be used. Use a wax pencil to divide the slide into squares no smaller than
V2 inch. A drawing of the divided slide on the sample work sheet, with
each square labeled with culture identification numbers, is useful for later
reference when recording Gram stain results. Place one drop of distilled
water on each divided portion of the slide, and use an inoculation needle
to suspend a tiny amount of growth from a nutrient agar slant in each
droplet. Mix the thin (almost invisible) suspension of cells with the tip of
the inoculation needle, and allow the liquid to evaporate. Heat fix the
smear by gently warming the slide over a flame. Do not overheat. This
procedure prevents the bacterial cells from being washed off the slide
during the staining procedure.
Stain the bacteria by flooding the area of the smear for 1 minute with
crystal violet solution. Flush off the excess solution in gently running tap
water and blot the slide dry with absorbent paper. Flood the smear with
Lugol's iodine for 1 minute, and again rinse gently in running water and
blot dry. Decolorize the smear by inclining it at a shallow angle and
dripping 95 percent ethyl alcohol on it until no more crystal violet is
removed—for approximately 15 to 30 seconds. Blot the smear dry and
counterstain for 10 seconds with safranin solution. Wash in running water
and_ blot dry. Place a drop of immersion oil on each of the stained squares
of the slide preparation, and examine under the microscope using the oil
immersion lens. The bacterial smear should contain nonspore-forming,
rod (bacilli) shaped, red-stained cells (Gram negative), occurring singly,
m pairs, or rarely in short chains. If this bacterial morphology is observed
104
Evaluating Water Bacteriology Laboratories IGeldreich
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on the slide and the corresponding culture ferments lactose with gas
production within 48 hours at 35°C incubation, coliforms are present and
the completed test is recorded as positive. In those instances when the
Gram-negative bacilli do not ferment lactose with gas production, or
when the Gram stain shows that spore-forming cells are present, or if
Gram-positive organisms or other morphological types of bacteria pre-
dominate, then that portion of the test is reported as negative. The
positive-negative tube combinations from the entire test procedure (pre-
sumptive, confirmed, completed) can now be determined.
FECAL COLIFORM PROCEDURE
With only a little added effort, the fecal coliform test can be done by a
multiple tube procedure (13, 14, Figure 2). In preparation for the test,
tubes of EC broth are labeled to correspond with each gas positive tube of
lauryl tryptose broth or lactose broth. Growth from each presumptive test
gas-positive tube is transferred to a correspondingly labeled tube of EC
broth with the use of a transfer loop or an applicator stick. Incubate the
EC broth tubes at 44.5°C (± 0.2°C) for 24 hours in a waterbath with a
gabled cover to reduce water and heat loss (see Elevated Temperature
Incubation Requirements in Chapter VI). For optimum temperature regu-
lation, the waterbath must have sufficient water depth to ensure complete
immersion of the culture medium in all tubes. Air incubation cannot be
substituted for water bath incubation because of the intolerable wide
fluctuations in air temperature and slower temperature stabilization in
tubes of culture medium introduced at the start of the incubation period.
Inoculated tubes should be placed in the waterbath within 30 minutes
following inoculation so that selective growth is related to elevated tem-
perature exposure.
Following the 24-hour incubation period, the test tube racks of EC
cultures are removed from the waterbath, shaken gently, and observed
for gas production. Gas in any quantity is a positive test. Cultures with
growth but no gas or tubes in which there is no visible indication of growth
are recorded as negative. Calculate the most probable number based on
the positive and negative tube combinations and report in terms of fecal
coliforms per 100 ml.
Any direct inoculation of sample aliquots into EC tubes without pre-
liminary enrichment in either lauryl tryptose or lactose broth is unsatis-
factory. Research data obtained from parallel testing of 88 fecal samples
showed that the average density of fecal coliforms detected was 24
percent when the enrichment procedure was not followed. Using the
recommended enrichment before EC tube inoculations, however, pro-
duced a 90 percent recovery in the same specimens.
The need for the presumptive enrichment was also demonstrated in
studies on the minimum Escherichia coli cell density necessary for gas
production in EC broth. Most of 25E. coli strains tested required from 1 to
20 viable cells to produce a gas positive reaction in EC broth when
incubated for 24 hours at 44.5°C; however, three E. coli strains that
required 500 or more viable cells per inoculum demonstrated that signifi-
cant variability in the required number of cells may occur. An optimum
cell density, generally in excess of 1,000 viable organisms, is ensured by
MULTIPLE TUBE COLIFORM PROCEDURES 105
-------�
tt]
I
o
o-
o
STREAM SAMPLE
\
Lauryl tryptose broth
(Presumptive test)
I
Incubate 24 hours at 35°C
^
Gas
t
No gas
*
Incubate 24 hours at 35°C
No gas
discard - no
coliforms present
Gas
Elevated temperature
test (EC)
Incubate 24 hours
at 44.5° (±0.5)
Brilliant green bile
lactose broth
Incubate 48 hours at 35°C
•No gas - fecal coliform
group absent (negative)
•Gas - fecal coliform
group present (positive)-
calculate fecal coliform
MPN
No gas
negative test -
coliforms absent
Gas
positive test -
calculate confirmed
MPN
Figure 2. Schematic Diagram For Detecting Total Coliform And
Fecal Coliform Bacterial Groups
-------�
the culture transfer from the presumptive test gas-positive tubes incu-
bated at 35°C to the more selective EC broth for incubation at the elevated
temperature.
Heavy growth in the gas-negative EC tubes may be attributed to ther-
mophilic bacteria that respond to the favorable incubation temperature.
More frequently, the growth is due to nonfecal coliform organisms trans-
ferred from the presumptive medium that were unable to carry out com-
plete fermentation of lactose at the elevated temperature but that attained
a sufficient density to show turbidity. In a study of 24,832 coliform strains
isolated from various environmental sources, 2,533 (9.8 percent) were
able to grow without gas production at the elevated temperature. The
occasional manifestation of these anaerogenic (growth without gas pro-
duction) strains at 44.5°C cannot be related specifically to warm-blooded
animals and are not considered part of the fecal coliform group. Extend-
ing the incubation of EC cultures beyond 24 hours is not warranted since
changes in gas reaction from negative to positive occurred in less than 0.1
percent of cultures examined.
MOST PROBABLE NUMBER CALCULATIONS
A mathematical calculation of the probable density of bacteria in a
sample can be made by combining positive and negative results in the
multiple tube test. Although most probable number (MPN) calculations
can be made from any combination of sample test portions employed, the
most frequent multiple tube combinations used are five, replicate, 10-ml
portions for potable water examinations and five replicate portions in
three-decimal dilutions for base-line data on raw source waters, in water
pollution investigations, and when monitoring treated effluent quality.
The greater the number of replicates of each sample volume in a dilution
series, the greater the test precision. This increase in test precision is
illustrated in Figure 3 for MPN values derived from multiple tube tests
using 1, 3, 5, or 10 replicate tubes and a test sample containing a true
density of 100 coliforms. Obviously, the MPN value is not a precise
measurement.
The simplest MPN calculations are those involving potable water tests
using five, replicate, 10-ml test portions. When all presumptive tubes in
the total coliform test are reported as negative after 48 hours' incubation,
the MPN result is stated to be less than 2.2 (< 2.2) total coliforms per 100
ml. If one presumptive positive result confirms in BGLB as a gas positive,
the MPN value is 2.2 per 100 ml. Similarly, if two, three, or four con-
firmatory test results are positive, the MPN value is 5.1, 9.2, or 16.0 total
coliforms per 100 ml, respectively. When all five presumptive tubes
confirm in BGLB, the MPN value can only be estimated to be greater than
16 total coliforms per 100 ml. The definitive total coliform value can only
be determined by a reexamination of the water sample using a five-tube
test in three or more decimal dilutions.
With respect to the measurement of stream and marine pollution sam-
ples, a five-tube, three-dilution MPN should be used to obtain a broader
range of values and a more accurate coliform determination. The practice
of using a three-tube, rather than a five-tube, MPN for data gathering to be
used in possible enforcement of water quality standards produces a MPN
MULTIPLE TUBE COLIFORM PROCEDURES 107
-------�
to
o
015
r
I
5
50%
75%
ONE TUBE
80%
90%
95%
75%
80%
THREE TUBES
90%
95%
75%
80%
FIVE TUBES
90%
95%
\ 80%\
\ 90% \
\ 95%
TEN TUBES
— ''-"— Maximum-
100
200
300 400 500 600
Confidence Limits - as % of MPN
700
800
900
1000
Figure 3. Confidence Limits For MPN Values Derived From Var-
ious Numbers Of Tubes In Three-Decimal Dilutions
-------�
estimate of significantly reduced precision (Figure 3). The 95 percent
confidence limits for a three-tube test range from 21 to 395 percent of the
true density whereas the five-tube test results may vary from 31 to 289
percent of the absolute value. As a further point, the tables of most
probable numbers were originally calculated to include a positive bias for
health safety reasons. Taking this fact into consideration with respect to a
three-tube MPN, the reported values may be too high by a factor of 43
percent; whereas, with the five-tube MPN test, the values may be overes-
timated by only 23 percent (15, 16). For these reasons, a suggested change
to the five-tube test would substantially improve the data obtained with
little increase in laboratory work or medium cost.
In the five-tube, multiple-dilution-test calculation, the smallest sample
volume tested (highest dilution) in which all replicate tubes are gas posi-
tive is selected as the starting dilution. The results of this test volume and
of the next two smaller volumes are used to determine the positive tube
combination. Since the MPN tables are usually limited to values for tests
starting with 10-ml sample portions, test results from other starting deci-
mal dilutions require appropriate adjustment based on the following for-
mula:
MPN table value x . 10..1 . = MPN per 100 ml
starting dilution
As an example, laboratory results for a sample examined indicated the
positive total coliform confirmed results were 5-3-0 with the smallest
sample portion showing all tubes positive being 0.01 ml. With the use of
the above formula and the MPN table value for a 5 - 3 - 0 positive tube
combination, i.e., 79, the problem is calculated as:
79 x -i°- =19 x 1,000 = 79,000 total coliforms/100 ml
Several examples of possible test results are illustrated in Table 7
including the proper selection of positive tube combinations and the
calculated MPN value. These examples illustrate the following accepted
rules governing proper selection of positive tube combinations:
1. When none of the dilutions used in the multiple tube test have a
positive result, the test results are indeterminately low. Thus, if
no positive results occur in these three dilutions and the largest
sample volume tested was 1 ml, the MPN is reported as <20 per
100 ml. A similar all-negative tube test with a starting dilution of
0.1 ml would be reported as < 200 per 100 ml. Under no cir-
cumstances can the construction of a firm MPN value be justified
by the assumption that if a larger sample volume had been tested,
one or more tubes would have been positive.
2. As a corollary, when all tubes are positive and the starting dilution
is 1 ml, the MPN must be reported as > 16,000, or if the starting
dilution is 0.1 ml, the MPN value is reported as > 160,000. It is not
permissible to assume that if the next larger sample portion had
been tested, the results would have produced one or more nega-
MULTIPLE TUBE COLIFORM PROCEDURES 109
-------�
TABLE 7. SELECTION OF POSITIVE TUBE COMBINATIONS
IN THE MPN CALCULATION
Multiple
10 ml
0
0
5
N.T.
N.T.
5
N.T.
N.T.
N.T.
tube test
1.0 ml
0
1
3
0
3
5
5
5
5
— positive results per dilution
0.1 ml
0
0
0
0
1
0
3
0
5
0.01 ml
N.T.*
N.T.
N.T.
0
0
0
0
2
5
0.001 ml
N.T.
N.T.
N.T.
0
0
0
1
1
5
Selected
combination
0
0
5
0
3
5
5
5
5
-0
- 1
-3
-0
- 1
-0
-3
-0
-5
-0
-0
-0
-0
-0
-0
- 1
-3
-5
MPN value
per 100 ml
<2
2
79
<20
110
230
1,100
5,800
> 160,000
*N.T. = sample portions not tested
tive results and, thereby, permitted the construction of a firm
MPN value.
3. Occasionally, multiple tube results may produce a positive tube
skip in the fourth decimal dilution of a sample. For convenience in
MPN calculations, this positive tube result must be moved to the
third dilution to establish a compatible positive tube combination.
Thus , the multiple tube result 5 - 3 - 0 - 1 must be interpreted as 5 -
3 - 1 in establishing the MPN value.
For special studies involving other combinations of replicate tubes and
dilutions, a simple approximation of the MPN value may be obtained from
use of the following short formula (17):
MPN per 100 ml = _ Number of positive tubes x 100 _
VTotal sample (ml) in negative tubes x total sample (ml) in test
For example, when four dilutions of the five-tube test result in a rare
positive tube combination such as 5 - 0 - 2 - 1 with the starting dilution of
0.1 ml, the MPN value could be determined from the formula in the
following manner:
Number of positive tubes = 5+0 + 2+1=8
Total sample (ml) in negative tubes = 0.0 + 0.05 + 0.003 + 0.0004 = 0.0534
Total sample (ml) in all tubes = 0.5 + 0.05 + 0.005 + 0.0005 = 0.5555
MPN per 100 ml = 8 x 100
V(0.0534) (0.5555)
significant flgures)
If MPN rule 3, previously described, were to be applied to this problem,
MPXT i , J I ~ l would be converted to 5 - 0 - 3 and the resulting
MPN value would be calculated to be 5,800 per 100 ml. Calculations of
MPN s derived by the short formula are more accurate than those derived
Evaluating Water Bacteriology Laboratories IGeldreich
-------�
by the skip accommodation rule, but both numbers are well within the 95
percent confidence limits.
Once the positive tube combinations have been determined, the calcu-
lated density can usually be obtained from the appropriate table of MPN
values. Tables 8, 9, and 10 are useful for evaluating how proficient the
technician is in applying the multiple tube procedure and how adequate
the test is for the waters being examined. Such an analysis should be
based on a minimum of 50 MPN positive tube combinations derived from
laboratory work sheets.
TABLE 8. STATISTICAL EXPECTANCY OF MOST FRE-
QUENT* MPN POSITIVE TUBE COMBINATIONS
Sample
10 ml
0
1
2
3
4
5
5
5
5
5
5
5
5
5
5
5
1 ml
0
0
0
0
0
0
1
2
3
4
5
5
5
5
5
5
size
0.1 ml
0
0
0
0
0
0
0
0
0
0
0
1
2
3
4
5
MPN
< 2
2
5
8
13
23
33
49
79
130
240
348
542
918
1600
> 1600
95% Confidence zone
Low
< 0.5
< 0.5
1
3
7
11
17
25
35
68
120
180
300
640
1400
High
1.3
7
13
19
31
70
93
130
190
300
750
1000
1400
3200
5800
—
Log MPN
—
0.30103
0.69897
0.90309
1.11394
1.36173
1.51851
1.69020
1.89763
2.11394
2.38021
2.54158
2.73400
2.96379
3.20412
* MPN tube combinations in 67.5 percent samples
TABLE 9. STATISTICAL EXPECTANCY OF FREQUENT*
MPN POSITIVE TUBE COMBINATIONS
Sample
10ml
1
2
3
4
4
5
5
5
5
5
1 ml
1
1
1
1
2
1
2
3
4
4
size
0.1 ml
0
0
0
0
0
1
1
1
1
2
MPN
4
7
11
17
22
46
70
109
172
221
95% Confidence zone
Low
0.5
1
2
5
7
16
23
31
43
57
High
11
17
25
46
67
120
170
250
490
700
Log MPN
0.60206
0.84510
1.04139
1.23045
1.34242
1.66276
1.84510
2.03743
2.23553
2.34439
* MPN tube combinations in 23.6 percent samples
MULTIPLE TUBE COLIFORM PROCEDURES 111
-------�
These tables include the typical positive tube combinations, the MPN
values, 95 percent confidence ranges, and the logarithms of the MPN
value that are useful in calculating the geometric mean of a series of MPN
results. The most frequent positive tube combinations (67.5 percent of all
tests analyzed) are shown in Table 8; those listed in Table 9 have a
statistical expectancy of 23.6 percent (18). If more than 7.9 percent of the
MPN positive tube combinations recorded are present in Table 10 or
consist of more than 1 percent of the improbable codes not listed in any of
these groupings, the multiple tube procedure is probably in error. Such an
abnormal distribution might result from substances in the water that
inhibit bacterial growth, from improper laboratory procedures, or from
other causes. Certainly this abnormality indicates the desirability of
special investigations to determine the reason(s) for such variation from
the expected pattern.
TABLE 10. STATISTICAL EXPECTANCY OF LESS FRE-
QUENT* MPN POSITIVE TUBE COMBINATIONS
Sample size MpN 95% Confidence zone Log MPN
10 ml 1 ml 0.1 ml. Low High
0
0
0
1
1
2
2
2
3
3
3
3
4
4
4
4
4
4
5
5
5
5
5
5
5
0
1
2
0
2
0
1
2
0
1
2
3
0
1
2
3
3
4
0
0
2
3
3
4
4
1
0
0
1
0
1
1
0
1
1
0
0
1
1
1
0
1
0
1
2
2
2
3
3
4
2.0
2.0
3.7
4.0
6.1
6.8
9.2
9.3
11
14
14
17
17
21
26
27
33
34
31
43
95
140
180
280
350
<0.5
<0.5
0.49
0.49
1.4
1.4
2.8
2.8
2.8
4.7
4.8
5.0
5.0
6.2
8.6
8.6
11
12
8.8
12
29
48
62
88
89
7
7
12
12
17
17
24
24
24
35
35
35
36
44
68
69
93
120
74
120
240
370
440
750
760
0.30103
0.30103
0.56820
0.60206
0.78533
0.83251
0.96379
0.96848
1.04139
1.14613
1.14613
1.23045
1.23045
1.32222
1.41497
1.43136
1.51851
1.53148
1.49136
1.63347
1.97772
2.14613
2.25527
2.44716
2.54407
'improbable codes not listed have a
Evaluating Water Bacteriology Laboratories/Geldreich
-------�
The geometric mean value is applied to data from the analyses of natural
water and sewage effluents because this statistical approach is not greatly
influenced by the occasional high densities appearing from time to time
(19). However, in potable water data analyses, it is essential to recognize
those infrequent high values that may occur—reflecting possible intermit-
tent problems in back siphonage or marginal treatment practices (20). The
arithmetic mean, unlike the geometric mean and the median, best reflects
occasional high values and is the required statistical approach specified in
the Federal Drinking Water Standards.
REFERENCES
1. American Public Health Association and American Water Works Association. Stand-
ard Methods of Water Analysis, 8th ed. American Public Health Association, New
York (1936).
2. McCrady, M. H. The Numerical Interpretation of Fermentation Tube Results. Jour.
Infect. Dis. 17:183-212 (1915).
3. Hoskins, J. K. The Most Probable Number for the Evaluation of Coli Aerogenes Test by
Fermentation Tube Method. Pub. Health Repts. 49:393-405 (1934).
4. Wattie, E. Relative Productivity of Newer Coliform Media. Pub. Health Repts. 63:269-
274 (1948).
5. Waksman, S. A. Antagonistic Relations of Microorganisms. Bacteriol Rev. 5:231-291
(1941).
6. Schiavone, E. L., and Passerini, L. M. D. The GenusPseitdomonas aeruginosa in the
Judgment of the Potability of Drinking Water. Semana Med. (Buenos Aires) 111:1151-
1161 (1957).
7. Kligler, L. J. Non-lactose Fermenting Bacteria from Polluted Wells and Sub-Soil. Jour.
Bact. 4:35-42 (1919).
8. Hutchinson, D., Weaver, R. H., and Scherago, M. The Incidence and Significance of
Microorganisms Antagonistic loEscherichia coli in Water. Jour. Bact. 45:29 (abstracts)
(1943).
9. Fischer, G. The Antagonistic Effect of Aerobic Sporulating Bacteria on the coli-
aerogenes Group. Zeit. Immun. u. Exp. Ther. 107:16-26 (1950).
10. Weaver, R. H., and Boiter, T. Antibiotic-Producing Species of Bacillus from Well
Water. Trans. Kentucky Acad. Sci. 13:183-188 (1951).
11. Chambers, C. W. Relationship of Coliform Bacteria to Gas Production in Media
Containing Lactose. Pub. Health Repts. 65:619-627 (1950).
12. Tubiash, H. The Anaerogenic Effect of Nitrates and Nitrites on Gram-negative Enteric
Bacteria. Amer. Jour. Pub. Health 41:833-838 (1951).
13. Geldreich, E. E., Clark, H. F., Kabler, P. W., Huff, C. B., and Bordner, R. H. The
Coliform Group. II Reactions in EC Medium at 45°C. Appl. Microbiol. 6:347-348 (1958).
14. Geldreich, E. E. Sanitary Significance of Fecal Coliforms in the Environment. Water
Poll. Cont. Res. Series Publ. No. WP-20-3. FWPCA, U.S. Dept. of Interior, Cincinnati,
Ohio. 122 p. (1966).
15. Thomas, H. A. Jr., and Woodward, R. L. Estimation of Coliform Density by the
Membrane Filter and the Fermentation Tube Methods. Amer. Jour. Pub. Health
45:1431-1437 (1955).
16. Thomas, H. A. Jr., Woodward, R. L., and Kabler, P. W. Use of Molecular Filter
Membranes for Water Potability Control. Jour. Amer. Water Works Assoc. 48:1391-
1402 (1956).
17. Thomas, H. A. Jr. Bacterial Densities from Fermentation Tubes. Jour. Amer. Water
Works Assoc. 34:572-576 (1942).
18. Woodward, R. L. How Probable is the Most Probable Number? Jour. Amer. Water
Works Assoc. 49:1060-1068 (1957).
19. Geldreich, E. E. Microbial Criteria Concepts for Coastal Bathing Waters. Ocean
Management 3:225-248 (1974-1975).
20. Thomas, H. A., Jr. Statistical Analyses of Coliform Data. Sewage and Ind. Wastes
27:212-222(1955).
MULTIPLE TUBE COLIFORM PROCEDURES 113
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GUIDELINES ON MULTIPLE TUBE COLIFORM PROCEDURES
Total Coliform Presumptive Test
Potable water: five standard portions, either 10 or 100 ml
Natural water quality or effluent monitoring: multiple dilutions
Choice of presumptive test medium
Adequate test labeling and tube dilution coding provided —
Sample shaken vigorously immediately before test —
Pipet tip never permitted below 1-inch of sample surface —
Serial dilutions prepared for sample portions of 0.01 ml or less
Tubes incubated at 35° ± 0.5°C for 24 ± 2 hours __
Examined for gas (any gas bubble positive)
Twenty-four-hour gas-positive tubes submitted to confirmed test
Negative tubes returned to incubator
Examined for gas at 48 ± 3 hours; positives submitted to confirmed test ..
Growth extinction MPN calculated from all presumptive tubes with growth
Total Coliform Confirmed Test
Presumptive positive tube gently shaken or mixed by rotating
One loopful or one dip of applicator transferred from presumptive positive
tube to BGLB broth —
Incubated at 35° ± 0.5°C; checked at 24 hours for gas production _
Negative tubes reincubated for additional 24 hours; checked
for gas production —
Positive tube results recorded; MPN value calculated _
Total Coliform Completed Test
Applied to all positive potable water samples or 20 tests performed
each 3 months to reestablish validity of confirmed test _
Applied to all positive confirmed tubes or doubtful colonies on streak
plates from each test sample —
Where positive, confirmed tubes are paralleled with a positive EC tube;
no further verification in completed procedure needed —
Positive confirmed tubes streaked on EMB or Endo streak plates
for colony isolation —
Plates adequately streaked to obtain discrete colonies —
Incubated at 35° ± 0.5°C for 24 ± 2 hours -
Typical nucleated colonies, with or without sheen, given prior selection .. _
If typical colonies absent or not isolated,
atypical colonies selected for completed test identification —
If no colonies or only colorless colonies appeared, the confirmed
test for that particular tube is considered negative -
Selected isolated colony chosen for verification was one typical or two atypi-
cal to lactose or lauryl tryptose broth and to agar slant for Gram stain _
Incubated at 35° ± 0.5°C; checked for gas within 48 hours -
Gram stain prepared from 18- to 24-hour-old culture -
Gram negative rods without spores and gas in lactose tube within 48
hours considered positive evidence for coliforms -
Positive tube results recorded; MPN value calculated
Fecal Coliform Test
Applied as an EC broth confirmation of all positive presumptive tubes .... .
EC tubes placed in water bath within 30 minutes of transfer
Incubated at 44.5° ± 0.2°C for 24 hours
Gas production considered positive test for fecal coliforms' '.'.'.'.'.'.
Positive tube results recorded; MPN value calculated
114
Evaluating Water Bacteriology Laboratories/Geldreich
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Most Probable Number Calculations
Smallest test portion with all tubes positive selected as starting dilution . .
Positive tube codes properly adjusted to accommodate skip results
MPN table values adjusted to reflect starting sample dilution
MPN short formula used to calculate unusual multiple tube combinations
Analysis of positive tube results indicated normal distribution
of possible codes
MULTIPLE TUBE COLIFORM PROCEDURES 115
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CHAPTER VIII
MEMBRANE FILTER COLIFORM PROCEDURES
The membrane filter (MF) procedure for the enumeration of total
coliforms was introduced into Standard Methods as a tentative method in
1955 (1) and established as both a standard test and an alternate to the
multiple tube procedure in 1960 with the publication of the 11th edition of
Standard Methods (2). The basic procedure involves filtering a known
volume of water sample through a MF of optimum pore size for full
bacterial retention. As the water passes through the pores, bacteria are
entrapped on the upper surface of the MF. The MF is then placed in
contact with either a paper pad saturated with liquid medium or directly
over an agar medium to provide nutrients for bacterial growth. Following
incubation under prescribed conditions of time, temperature, and humid-
ity, the cultures are examined for coliform colonies that are then counted
and recorded as a density of coliforms per 100 ml of water sample.
MEMBRANE FILTER TEST LIMITATIONS
The majority of water samples can be tested by MF methods. Some
types of samples, however, cannot be filtered because of turbidity (3),
excessively high noncoliform bacterial populations (3), or heavy metal
compounds (4,5). These difficulties may be encountered in examining
samples from some well waters, impounded reservoirs, small lakes, in-
dustrial effluents, and poor quality chlorinated effluents (6,7).
The presence of suspended material in the sample may limit any appli-
cation of the MF procedure. This limitation will depend on the volume of
sample filtered, the type of suspended material, and the thickness of the
layer of suspended material on the filter surface during incubation of the
sample. Relatively thin layers of gelatinous, finely divided, or hygro-
scopic materials, such as suspended iron, manganese, alum floes, or
algae, may clog the pores of the filter or may cause a spreading film of
growth during incubation. Thicker surface layers of crystalline or silice-
ous materials may cause little or no difficulty. Where the coliform density
is known to be so high that the sample volume need not exceed 2 or 3 ml,
there is little chance that turbidity on the filter will cause problems.
However, if few coliforms are present and the sample has obvious turbidi-
ty, then the multiple tube procedure should be used.
Large populations of noncoliform organisms in potable water supplies
may make coliform analysis difficult by either the multiple tube (MPN) or
the MF procedure, because of possible suppression of coliform detection.
The occurrence of high-density, noncoliform populations is particularly
evident on the MF where overwhelming numbers of bacteria may coun-
teract the suppressive mechanism of M-Endo medium and produce a
massive overgrowth that masks visual detection of coliform colonies on
MEMBRANE FILTER COLIFORM PROCEDURES 117
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the filter surface. Since the selective mechanism of M-Endo MF medium
cannot cope with poor quality potable waters containing in excess of 400
noncoliform to one coliform per 100 ml, the five-tube MPN procedure
must be used for coliform analysis. The preferred solution to this problem
is not to use the less precise MPN procedure but maintain a free-chlorine
residual in the potable water supply that protects against contamination
and controls the general bacterial population.
Some waters, highly polluted with industrial wastes, have been found
to contain more than 1 ppm of zinc or copper. Apparently metallic ions
that exert a bactericidal or bacteriostatic effect can be adsorbed on the
membrane and, thus, prevent bacterial growth. Samples from such wa-
ters should be collected in sample bottles containing a chelating agent. In
addition, the use of a 2-hour MF culture enrichment before planting the
membranes on selective media or in more selective incubation tempera-
tures may be needed for optimum recovery of stressed coliform organ-
isms.
Sewage that has received only primary treatment followed by chlorina-
tion or other sewages containing phenols or toxic metals from industrial
wastes cannot be examined by the MF procedure. Samples of chlorinated
primary effluent often exhibit temporarily reduced coliform density
(1,000 organisms or less per 100 ml), and 4 to 6 ml of sample are needed to
obtain representative coliform density measurement. The upper limit for
the amount of primary effluent that can be filtered, however, appears to
be 1 ml; with larger volumes, extraneous materials clog the MF pores,
deposits build up over the effective filtration area, growth of discrete
coliform colonies is prevented, and the resulting culture confluency
makes selective counting of coliform colonies difficult, if not impossible.
Therefore, wastewaters of this character must be examined by the multi-
ple tube procedure, and it must be realized that a significant number of
false-positive results may occur in the confirmed MPN on chlorinated
primary effluents, particularly when stormwater runoff enters the mixed
sewage collection.
When sewage receives secondary treatment, a MF limitation related to
pore clogging does not exist because there is little gelatinous material or
microfecal pellets remaining in this higher quality effluent. However, the
effect of disinfection action on residual coliforms in those secondary
effluents receiving a chlorination treatment does limit MF procedures to
the two-step (pre-enrichment) procedure for total coliforms. Apparently
the 2-hour enrichment is necessary to permit organisms sufficient time to
achieve repair of damaged enzyme systems before contact with the selec-
tive Endo medium. Recent data (8) indicate that a direct application of the
MF fecal coliform procedure to chlorinated sewage effluents may recover
fewer of these organisms than does the multiple tube procedure. In this
instance, the critical factor is temperature acclimation for the stressed
coliforms surviving disinfection exposure (9).
Review of the attenuated fecal coliform recovery problem suggests that
chlorine inactivation of some coliform cells might be reversed provided
enrichment (10,11) and temperature acclimation (11,12) were possible
without compromising the specificity of the test. All enrichment proce-
dures previously developed for the membrane filter technique required a
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manual transfer of the membrane filter cultures from one membrane to
another. Recognizing media manipulations are time consuming in the
laboratory, a new approach (13) incorporating a two-layer-enrichment
(lactose broth +1.5 percent agar) differential growth medium (M-FC
broth + 1.5 percent agar) allows for repair and subsequent reproduction
of those fecal coliforms that have been stressed by exposure to chlorine,
industrial wastes, or marine waters.
A two-layer medium (Figure 4) is prepared by dispensing approxi-
mately 5 ml of M-FC agar into each culture dish (50- x 12-mm), permitting
the agar to solidify, then adding 2 ml of normal strength lactose broth in
1.5 percent agar over the M-FC agar. Since the ingredients of the two agar
layers will eventually diffuse into each other, it is suggested that the base
M-FC agar be prepared in advance and the lactose agar overlay added 1
hour before using.
After the MF is placed on the two-layer medium, the plates are incu-
bated at 35°C for 2 hours after which the temperature is increased to
44.5°C for 22 to 24 hours to attain the necessary selectivity. All blue
colonies are counted with the aid of a binocular scope employing 10 to
15x magnification and a fluorescent light source. Verification of fecal
coliforms isolated on the test medium is performed by subculturing each
blue colony into either phenol red lactose broth or lauryl tryptose broth
for 24 to 48 hours at 35°C. Tubes showing gas production within this
period are subcultured to EC broth and incubated in a water bath for 24
hours at 44.5°C ± 0.2°C.
The decision to use the slightly more involved two-layered medium
procedure in preference to the direct M-FC method should be based on a
demonstration of increased verified recovery of fecal coliforms from
samples routinely examined. MF's with 2.4-micron surface-opening
diameters (HC type) may also improve recovery of the direct M-FC
method.
Membrane Filter
Lactose
Agar
Standard m-FC
Agar
Figure 4
Two-Layered m-FC Agar
EVALUATION OF THE MF FECAL COLIFORM TEST
FOR SEWAGE EFFLUENTS
Any decision to use the layered M-FC agar procedure or any sub-
sequently proposed fecal coliform MF procedures in the bacterial quality
assessment of chlorinated sewage effluents must be based on laboratory
data that demonstrate at least an 80 percent agreement between parallel
MF and MPN fecal coliform methods. Approximately 100 samples
chosen from a variety of sewage plant effluents should be used
MEMBRANE FILTER COLIFORM PROCEDURES 119
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used in this MF-MPN comparative study. Erratic data from both the MF
and MPN procedures may be caused by fecal micropellets in poorly treated
sewage effluents. Sample blending for 6 to 30 seconds at 3,000 rpm does
help alleviate this problem. When chlorinated secondary effluents are
examined from plants subject to wide variations in effluent quality because
of seasonal or other factors, it is suggested that every fifth sample be
examined by both the MF and the five-tube procedure until comparability
of results is verified. The same approach should be used on combined
sanitary sewer-stormwater overflow samples collected during early runoff
periods when the turbidity is high. This approach should be continued until
the reproducibility of results by the MF procedure is established.
EVALUATION OF THE MF TOTAL COLIFORM TEST
FOR POTABLE WATERS
Initial comparison of the MF test and the multiple-tube MPN com-
pleted test procedure by laboratory parallel testing is recommended.
Such an evaluation establishes the expected sensitivity of the MF test to
the analyzed waters from a given geographical area and also permits the
technician to gain necessary experience in the use of the MF technique.
In such an evaluation, the completed test rather than the confirmed test
should be used to ensure the validity of the coliform results used for
reference. The confirmed test is not a perfect screening procedure for
coliform bacteria since it may yield a positive reaction in the absence of
the coliform group, i.e., false-positive test. Coliform MPN results from
the examination of soils (14) and various waters (15) demonstrate that
significant differences in coliform numbers can occur between the con-
firmed and completed tests. The bacterial flora of a given water, the age of
the sample, or the suppressive action of the brilliant green dye and bile
salts in the confirmatory medium can contribute to the possible occur-
rence of such differences (16).
The comparative evaluation should extend over a 3-month period
(minimum) and include a variety of municipal water samples, wells,
cisterns, lakes, and raw source waters at public water intakes.
Data from both the MF and completed test procedures should yield the
same information about the sanitary quality of water examined. When
potable water samples are examined to evaluate these procedures, a
sample is defined as unsatisfactory if four or more coliforms are detected
per 100 ml by the MF test or three or more positive confirmed tubes are
observed in the MPN procedure. Thus, the comparison for equivalency
does not require that the two test procedures demonstrate numerically
equal coliform densities. In instances where only raw source water sam-
ples are used in the evaluation, 80 percent of the MF values should be
within the 95 percent confidence limits of the MPN completed test results.
Multiple tube results are higher numerically than MF results because
MPN numbers represent a statistical estimate of the true density in the
sample, with the five-tube MPN table of values including a 23 percent
positive bias as a safety factor (17). Additional information may be ob-
tained from numerous comparisons of the MPN and the MF procedures
used with potable water, natural fresh waters, sewage, and marine waters
(18-35).
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TOTAL COLIFORM MF PROCEDURE
Successful application of MF methods requires development of good
laboratory and routine operational practice (36). Preliminary activities
include: recording sample data in the laboratory log; disinfection of
laboratory bench-top working area; and assembly of the necessary sterile
filtration equipment and sterile materials (MF's, culture containers,
pipets, graduated cylinders, dilution blanks and medium).
To prepare Petri dishes for the MF, place one sterile absorbent pad in
each culture dish (using sterile forceps), unless an agar medium is being
used. The amount of culture broth necessary to saturate an absorbent pad
varies as a result of pad thickness and degree of dryness—from 1.8 to 2.2
ml. Pour any excess medium from the culture dish before rolling the
membrane over the absorbent pad. If the excess is not removed, flooding
of the membrane may occur and cause confluent growth on the mem-
brane. Insufficient medium results in small "starved" colony develop-
ment. When agar medium is employed, dispense 3 to 4 ml of the melted
agar medium directly to each culture dish.
The filtration assembly should be sterile at the beginning of each
filtration series that may involve 30 or more samples. A filtration series is
considered interrupted if there is an interval of 30 minutes or longer
between sample filtrations. Resuming filtration after such an interruption
requires another set of sterile filtration units and is considered a new
filtration series. This protocol minimizes chance contamination of funnels
from spills and protects filter holders from leakage of contaminated
waters during filtration malfunctions. Rapid resterilization of the funnel
(see Sterilization Procedures; MF Filtration Equipment in Chapter V) by
UV, flowing steam, or boiling water may be practiced between sample
filtrations at the bench.
A standard sample volume of 100 ml must be analyzed for all public
water supplies, e.g.,treated water supplies. In potable water, test results
should most frequently indicate no coliform detection in 100-ml volumes,
although rare occurrences of one to three coliforms are permissible pro-
vided the arithmetic mean coliform density for a given supply remains
below one coliform per 100 ml. The coliform content of treated water
supplies must be less than one total coliform per 100 ml as measured by
the MF procedure. Untreated water supplies (individual wells, springs,
etc.) may have excessive noncoliform bacterial populations that will
necessitate examining two 50-ml portions per sample.
All potable water sample volumes must be measured within a ± 2.5
percent tolerance as specified in the MF procedure since this test is
quantitative. When glass filter funnels are used, the 100-ml gradation may
be used after its accuracy has been verified. Although metal funnels may
not have 100-ml marks impressed on the interior surface, use a water-
proof, heat-resistant ink or enamel to inscribe a line at the 100-ml water
level.
For the most accurate measurement of potable water sample volumes,
use graduated cylinders. An individual, sterile, graduated cylinder or
volumetric pipet should be assigned to each sample examined in the
filtration series. Sample volumes can then be measured, poured into the
MEMBRANE FILTER COLIFORM PROCEDURES 121
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funnel, and filtered. A small portion of sterile buffered dilution water
(approximately 25 ml) is flushed into the graduated cylinder for rinsing
and then poured into the MF funnel being used for that sample. Follow
this procedure with two separate short rinses (with approximately 20 to 30
ml of sterile dilution water) to flush any residual bacteria from the funnel
walls onto the MF surface. Rinsing the graduated cylinder and funnel
before removing the MF not only ensures transfer of all bacteria in the
sample to the membrane surface but also prevents carryover of coliforms
to the next sample.
MF's are fragile and may be easily damaged by improper handling.
Grasp the outer part of the MF, outside the effective filtering area, with
sterile, smooth-tipped forceps. This procedure avoids smearing entrap-
ped bacteria or the possibility of piercing the MF surface and breaking its
retention capabilities. Place the sterile MF on the filter holder, grid-side
up, centered over the porous part of the filter support plate. To avoid
damage to the MF, the funnel should not be turned or twisted while it is
being seated and locked to the lower element of the filter holder. Filter
holding units featuring a bayonet-joint and locking ring to join the upper
element to the lower element require special care on the part of the
operator. Turn this locking ring sufficiently to give a snug fit, but do not
tighten excessively.
Immediately before filtering a measured sample, invert the sample and
shake it vigorously. This vigorous shaking is needed to obtain a
homogeneous distribution of suspended bacteria and is of particular
concern with turbidity-laden waters. Turbidity in water settles rapidly,
pulls suspended bacteria into the bottom sediment, and thereby creates
an uneven distribution of the bacterial population in measured aliquots.
After shaking the sample thoroughly, pour or pipette the measured
sample volume into the funnel with the vacuum supply line connection
turned off. To avoid uneven distribution of organisms over the effective
filtering area, the vacuum should never be applied simultaneously with
the addition of the sample test portion. Before dispensing 10 ml or less,
add approximately 10 ml of sterile dilution water to the funnel to ensure
uniform dispersion of the bacterial suspension. Then apply the vacuum to
force rapid passage of the sample through the MF, after which, rinse the
funnel wall with 20 to 30 ml of sterile dillution water. After the first rinse
has passed through the filter, repeat this rinsing procedure. Extensive
tests have shown that with proper rinsing technique, bacterial retention
by the funnel walls is negligible.
The buffered dilution water that is used for rinse Water in the MF
procedure is often prepared in large flasks or carboys, autoclaved, and
stored in the laboratory until needed. Since these containers may vary
from 1-liter flasks to 20-liter carboys, the rinse Water is generally dis-
pensed by siphoning through glass, Teflon, or rubber tubing to the MF
funnels or is poured into smaller, sterile wash bottles for ease in handling.
Caution must be exercised that the siphoning devices and dispensing
wash bottles do not become contaminated and, thereby, contribute rtii-
crobial contamination to the filtration procedure. A single occurrence of
heavy microbial growth in the rinse water can nullify the results of an
entire day's water testing program by completely "masking" the mem-
122 Evaluating Water Bacteriology LaboratorieslGeldreich
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brane with noncoliform growths that interfer with coliform colony or
sheen development. Using a fresh sterile rinse water supply and dispens-
ing system each day will avoid this contamination problem.
To ensure that no contamination exists at the start of testing, a sterile
100-ml dilution blank should be subjected to the MF procedure, before the
initial processing of water samples. Whenever possible, analyze potable
water samples first in a filtration series, followed by natural waters, then
sewage and industrial effluents. Inject a sterile test water sample at the
conclusion of each grouping of waters and effluents and one at the
conclusion of the filtration series. The purpose of this quality control
procedure is to ensure materials were sterile at the start of filtration and to
isolate possible cross-contamination if the technician fails to adequately
rinse all organisms onto the filter surface of a polluted sample. When
sterile controls indicate contamination occurred, all data on samples
affected should be rejected and a request made for immediate resampling
of those waters involved in the laboratory error.
Upon completion of the rinse procedure, turn off the vacuum supply to
the filtration assembly to avoid accidentally tearing the filter while trans-
ferring it in the next step. Disengage the filtration assembly and carefully
transfer the MF, using sterile forceps, to a Petri dish containing a
medium-saturated absorbent pad or an agar preparation. Proper contact
between the MF and the absorbent pad or agar substrate requires the
underside of the membrane to be uniformly wetted with culture medium
without air bubble entrapment.
Air bubbles trapped between the membrane and the substrate medium
can easily be recognized on M-Endo MF medium as colorless or light pink
spots on the membrane or can be seen through the agar layer in the
inverted culture dish. The entrapment of air bubbles must be avoided in
the interfacing of the effective filtration area of the MF with the substrate
because this condition becomes an immediate barrier to bacterial contact
with the nutritive substrate. Air bubbles are produced when membranes
are rolled too rapidly over the substrate, engulfing air pockets. Other
causes of air bubble entrapment may relate to changes in agar surface
from desiccation during storage or foaming of agar during the rapid
ejection of medium from an automatic syringe or pipet into culture dishes.
These entrapments of air block the diffusion of nutrients from either the
medium saturated absorbent pad or agar preparation to any bacteria on
the MF surface directly above. This condition results in diminished
potential for growth of the viable bacterial cells into differentiated col-
onies or hastens their death through desiccation. The net result would be
an occassional reduction in the detection of low levels of coliforms in
potable waters. Therefore, inspect all MF cultures before incubation for
any air bubble entrapment inside the effective filtration area. Air bubbles
are easily removed by simply lifting the membrane with sterile forceps
and rerolling it onto the medium saturated pad or agar substrate. There-
upon, close the culture container, invert it, and promptly place it in the
appropriate incubator, preferably within 10 to 15 minutes after filtration.
INCUBATION OF MF CULTURES
MF examinations for total coliform recovery require a 22- to 24-hour
incubation period at 35°C for optimum growth and sheen development.
MEMBRANE FILTER COLIFORM PROCEDURES 123
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This time period is especially important when examining potable water
samples since incomplete disinfection may have created stressed col-
iforms with damaged metabolic pathways. These coliforms are initially
slow to develop the normal lactose fermentation end products that are the
basis for differentiation.
The incubator should maintain a high level of humidity (approximately
90 percent). Reduced humidity often permits the surface of the mem-
branes to lose moisture more rapidly than it is replenished by the diffusion
of medium from an agar or absorbent pad substrate. As a result, growth
failure or, at best, small or poorly differentiated colonies may result. A
conventional, hot-air incubator may be used; however, cultures in loose
fitting Petri dishes must be placed in a tightly closed container, along with
wet paper or cloth to maintain the necessary humid atmosphere. A
vegetable crisper, such as is used in most home refrigerators, is satisfac-
tory for this purpose. Tight-fitting plastic Petri dishes are preferred be-
cause the required humidity is established for each culture by the evap-
oration of some of the medium within the confines of the individual dish.
No modification for higher humidity in the air incubator is necessary
when tight-fitting plastic culture dishes are used.
MF COLONY COUNTING
Coliform colonies are best counted while in the moist state associated
with their growth. Magnification of 10 to 15 diameters and a daylight
fluorescent light source adjusted to an angle of 60° to 80° above the
colonies are essential for optimum reflection of the golden metallic luster
from coliform colonies on an Endo-type medium. The procedure of
drying MF cultures to improve sheen visibility before counting is open to
criticism whenever such colonies are to be subjected to the coliform
verification procedure. Colonies exposed to more than a few minutes of
drying may not be capable of growth following transfer to lactose broth
tubes. Comparisons made by different technicians in several laboratories
indicate there is no significant advantage for this time-consuming drying
procedure. The use of the recommended fluorescent light source
positioned above the MF culture will yield excellent reflection of the
metallic luster from coliform colonies.
The typical coliform colony has a pink to dark red color with a metallic
surface sheen. The sheen area may vary from a small pin-head size to
complete coverage of the colony surface. All members of the coliform
group grow and develop a metallic sheen on Endo-type media. Develop-
ment of colonies of noncoliform bacteria is generally restricted by the
medium, but there are exceptions for certain waters where noncoliform
growth may cover the filter surface.
Noncoliform colonies vary in appearance from colorless to a deep red
color. Colonies having a red color and a "small flake" or "speck" of
shiny material resembling a metallic sheen are the most confusing of the
noncoliform types. The novice has great difficulty with confluent col-
onies, with mirror reflections of fluorescent tubes, which are confused
with sheen, and with water condensate and paniculate matter, which are
occasionally mistaken for colonies. Thus, there is a tendency for the
novice to err on the high side in MF counts. Technicians who have not
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attained proficiency in coliform colony recognition should transfer doubt-
ful colonies to lactose (or lauryl tryptose) broth tubes for verification as
coliform organisms.
SELECTION OF COUNTABLE MEMBRANES
Always report total coliform densities determined by the MF procedure
as "total coliforms per 100 ml" regardless of the size of test portion used
or the nature of the sample (potable or polluted water). The coliform
density may be calculated from one or more MF counts resulting from
testing serial sample portions, provided the counts are in the 20 to 80
colony range and the total count of all colonies on the MF does not exceed
200. When the filter counts are less than 20, total all test results for the
sample and relate the coliform density to the total volume filtered, using
the following equation:
_ . .., . inn i coliform colonies counted x 100
Total coliform colonies per 100 ml = —— •—
volume of sample filtered
Ideally membranes selected for counting total coliform populations in
polluted waters should have from 20 to 80 coliform colonies and not
exceed 200 total bacterial colonies. If different volumes of sample are
examined, it is permissible to total the counts on each membrane and base
the value on the total volume of sample examined. For example, if
duplicate 50-ml portions are examined and the two membranes contain 5
and 3 coliform colonies, respectively, the count should be reported as 8
per 100 ml. This count is reliable since a 100 ml sample portion actually
was examined. Similarly, if 50-, 25-, and 10-ml portions were examined
and the counts were 15, 6, and < 1 coliform colonies, respectively, the 15
and 6 would be totaled and the count, based on a 75-ml volume, would be
calculated using the above equation and reported as 28/100 ml. If 10-, 1.0-,
and 0.1-ml portions were examined and counts were 40, 9, and < 1
coliform colonies, respectively, the result would be reported as 400 per
100 ml. Considering the last example, if the 10-ml portion has a total
coliform count of 40 but the total bacterial colony count (coliform plus
noncoliform colonies) is greater than 200, the total coliform count would
be reported as > 400 per 100 ml. Subsequent samples from this source
water would require adjustment of the sample volume examined by the
MF procedure to obtain specific and reliable counts.
INTERPRETATION OF MF CULTURES
Sample portions with an extremely high density of coliform colonies
(greater than 80 colonies per MF) should be reported as greater than the
number of coliform colonies actually counted. Membranes showing a
mass of growth, devoid of defined colonies, should be reported as "con-
fluent growth" even if sheen covers the entire mass of growth. In both
instances, another sample should be collected and adjustments should be
made regarding sample volume examined.
Drinking water acceptance for public consumption requires demon-
stration of minimal numbers of coliform organisms in individual samples
and at a limited frequency in all samples examined per month as set forth
MEMBRANE FILTER COLIFORM PROCEDURES 125
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in EPA's Primary Drinking Water Standards (37). Where total coliform
density is determined by a multiple tube procedure that analyzes 50 ml of
sample divided into 5 portions of 10 ml each, the monthly report of
bacteriological quality is based on a 5 percent limit of samples having 3 or
more tubes positive. By contrast, the MF technique involves a direct
count of coliforms per 100 ml. When the MF technique is used, the
bacteriological rating of a public water supply is based on two
qualifications—coliform density not to exceed an arithmetic mean of one
per 100 ml for all samples examined per month and a limit on unsatisfac-
tory samples (5 or more coliforms per 100 ml) in one sample when less
than 20 per month are examined or in 5 percent of all samples when more
than 20 are examined each month. Because the range of accurate total
coliform values can be from less than 1 to 80 organisms per 100 ml,
individual densities may make the monthly arithmetic mean limit of 1 total
coliform per 100 ml difficult to obtain without a significant increase in the
number of routine samples. This position stimulates the more desirable
reaction of intensifying the monthly sampling frequency. When using the
multiple tube procedure, however, the percent of positive tubes per
month may easily be lowered with only a slight increase in sampling
frequency since each test adds five individual tubes to the total base
number used in monthly calculation. Thus, the desired increase in sample
frequency is partially lost on those water supplies using the multiple tube
test. To offset this MF-MPN inequality, interpretation of the regulations
should recognize that even though a single MF total coliform result may
prevent the arithmetic mean attainment of one coliform per 100 ml limit,
the water quality is still classed as satisfactory because the frequency of
this unsatisfactory MF coliform occurrence has not exceeded the Primary
Drinking Water Standards.
Various types of water supplies are used for drinking water throughout
the United States. Because some are untreated (usually private supplies)
and others are ineffectively treated, results obtained by the MF procedure
can range from "no growth" to "confluent growth" per 100 ml. The
following guidelines are recommended for reporting MF procedure re-
sults:
Confluent growth—no discrete colonies, growth covering the entire
filtration area of the membrane. Results should be reported as "confluent
growth." The water supply should be treated before additional examina-
tion.
TNTC (too numerous to count)—The total number of bacterial colonies
(coliform plus noncoliform) are too numerous or not sufficiently distinct
to obtain an accurate count, or both; usually greater than 200 colonies per
membrane. It is permissible to adjust the individual sample volumes
filtered; however, the total sample volume examined must equal 100 ml.
For example, rather than examining a 100-ml portion, examine two 50-ml
portions or four 25-ml portions. Coliform colonies observed on each
membrane are then totaled and reported per 100 ml.
If the 100-ml portion examined was found to contain colonies too
numerous to count (TNTC) but distinct, typical coliform colonies are
observed and the number of coliform colonies is-
• less than 4 per 100 ml—then the report should not indicate the
sample to be satisfactory since a high density of noncoliform
126 Evaluating Water Bacteriology LaboratoriesIGeldreich
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organisms may inhibit growth or sheen development or both of the
coliform colonies. Treatment should be recommended before
another sample is collected for examination.
• greater than four per 100 ml—then the report should indicate the
sample to be unsatisfactory. The number of colonies should be
reported as greater than the number counted in the estimate. The
water supply should be treated and another sample collected for
examination.
Examination of some water supplies, usually private supplies, may
result in greater than 200 noncoliform colonies per membrane when a
100-ml sample is examined. Such occurrences emphasize a need for
effective treatment of the water supply before it is resampled and
examined. Employment of an MPN procedure to examine such poten-
tially hazardous water supplies should be discouraged since changes in
methodology will not improve water quality.
VERIFICATION OF COLIFORM COLONIES
When coliforms are found in potable water samples, initiate a rapid
alert to the proper authorities and a request for repeat sampling at the
same sites on the distribution network. Retain these cultures, however,
until subjected to the verification procedure since synergistic false-
positive coliform reactions on Endo media may occur (38,39). This sup-
plemental procedure consists of transferring each coliform colony to
lactose or lauryl tryptose (LTB) broth and then to BGLB for evidence of
gas production at 35°C within the 48-hour limit. If all coliform-type
colonies cannot be transferred, verify a random selection of at least 10
sheen colonies. Avoid direct transfer of colonies to BGLB because of the
inherent lower recovery of stressed coliform strains in this more selective
medium. Omitting the BGLB step is undesirable since this medium elimi-
nates some of the false-positive results from the lactose or LTB broth.
In an effort to expedite the time delay resulting from verification of
sheen colonies, it is permissible to transfer growth from each colony into
pairs of lactose or LTB broth and BGLB broth tubes. In this procedure,
the verification is completed in 24 hours if both the lactose or LTB broth
culture and the BGLB broth culture produce gas at 35°C. However, in
those instances where the pair of cultures is negative, the lactose or LTB
broth culture is reincubated for the second 24-hour period, and if then
positive, a confirmation into a new tube of BGLB is necessary before
verification is complete. This procedure of double inoculation from each
sheen colony could reduce the test time from 80 to 90 percent for all
coliform colony verification.
From the number of BGLB cultures that produce gas within 48 hours at
35°C, calculate the percent of colonies verified as coliforms. Then use this
percent figure to adjust the reported coliform count per 100 ml. As an
example, 10 sheen colonies from one culture might be verified through
inoculations into LTB broth then to BGLB; however, only 8 tubes pro-
duce gas in BGLB. The percent verification is 80. The original coliform
count was recorded as 20 organisms per 100 ml. Based on the verification
of a random selection of 10 such colonies, the final coliform count re-
corded and reported would be 16 (80% x 20) organisms per 100 ml.
MEMBRANE FILTER COLIFORM PROCEDURES 127
-------�
Verification of coliform occurrences in potable water or in at least one
set of critical stream pollution samples obtained during a field survey is
important for several reasons. This additional procedure provides useful
reinforcement of the laboratory findings in any legal action involving
records subpoenaed for court use and in decisions pertaining to reclassifi-
cation of interstate carrier water supply systems. The verification proce-
dure is also an essential part of technician self-training in accurately
discerning coliforms, particularly on those MF cultures that exhibit poor
sheen development because of sample turbidity and spreading films of
bacterial growth. The inexperienced technician frequently finds the deep
red colonies difficult to classify, especially where the presence or absence
of a metallic sheen is the only distinguishing characteristic. In some
instances the true colony sheen has been confused with mirror reflection
of fluorescent microscope lamp tubes on the moist shiny surface of pink
or red colonies. This confusion is greatest with dark red colonies with
granulated surfaces that reflect diffused light similar to that of a sheen
colony. Water condensate droplets and turbidity particles combined with
this mirror reflection have also frequently been classified as coliform
bacteria by the novice technician. This problem of proper coliform dis-
cernment by a new technician is solved only by actual practice and
experience in counting colonies, supported by the verification procedure.
CHOICE OF TOTAL COLIFORM METHODS
The bacteriologist has a choice of methods for the detection of total
coliforms by the MF procedure. Either M-Endo MF broth or LES Endo
agar may be used in a single step procedure, i.e., after sample filtration,
the MF culture is incubated solely on one of these two Endo-type media.
As an alternative, after sample filteration, first incubate the MF culture
1.5 to 2 hours at 35°C on lauryl tryptose broth for enrichment. Then
transfer the MF to a new absorbent pad saturated with M-Endo MF broth,
or to the bottom of the same culture dish containing LES Endo agar for
incubation at 35°C for 20 to 22 hours to differentiate coliform colonies.
With several options for medium choice, with or without enrichment,
laboratory personnel have the opportunity to evaluate these methods for
optimum coliform recovery from waters in their geographical area. Such
an evaluation should include a variety of samples and also a verification of
a proportion (not less than 10 percent) of the sheen colonies. Enrichment
may be beneficial for the optimum recovery of attenuated coliforms from
chlorinated effluents of secondary sewage treatment plants and industrial
wastes containing significant concentrations of heavy metal ions.
FECAL COLIFORM MF PROCEDURE
For those laboratories with the technical capability to perform the MF
procedure for fecal coliform enumeration, the only special items neces-
sary are a water bath, which can be regulated at 44.5°C ± 0.2°C, M-FC
broth, and scalable plastic bags to protect the cultures while immersed in
the water bath incubator. For specific details on the MF procedure,
tollow the recommendations described for total coliform MF tests in the
preceding portion of this chapter.
11S
Evaluating Water Bacteriology LaboratoriesIGeldrelch
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Examination of natural bathing water, stormwater runoff, raw sewage,
and treated sewage effluents for fecal coliforms requires a range of test
volumes to obtain suitable fecal coliform densities on the membrane
within the range of 20 to 60 colonies. When the bacterial level of the
sample is totally unknown, it is necessary to filter several decimal quan-
tities of sample to obtain a countable density of coliforms. The best
method is to estimate the ideal quantity expected to yield a countable
membrane and use two additional quantities representing one-tenth and
ten times that quantity. Use the best density within the 20 to 60 fecal
coliform colony range for the fecal coliform colony count and disregard
the remaining two membrane culture results.
This procedure parallels the field survey practice of inoculating four or
five decimal dilutions of polluted water samples in the multiple tube
procedure and then choosing the three consecutive decimal dilutions that
give an approximately even split of negative and positive tubes for use in
calculating the MPN value. Data in Table 11 are a guide for selecting the
appropriate volume of various waters and wastes. Using peptone dilution
water may increase recovery of stressed cells.
TABLE 11. SUGGESTED GUIDE FOR FECAL COLIFORM
FILTRATION QUANTITIES
Water source Quantities filtered (ml)
100 50 10 1 O.I 0.01 0.001
Lakes, reservoirs
Wells, springs
Water supply, surface
intake
Natural bathing waters
Sewage treatment plant
secondary effluent
Farm ponds, rivers
Stormwater runoff
Raw municipal sewage
Feedlot runoff
X X
XXX
XXX
XXX
X X
X
X
X
X
X
X
X
X
X
X
X
X
X
Following sample filtration, place the MF on an absorbent pad satu-
rated with M-FC broth (or the same medium prepared in 1.5 percent agar)
contained in Petri dishes with tight fitting lids. After inspecting for air
bubbles that must be released from between the medium and the mem-
brane, insert the cultures into scalable plastic bags. These waterproof
plastic bags (Whirl-Pak or equivalent) may be used to hold five to eight
culture dishes during submersion. These cultures must be placed in the
incubator within 30 minutes of filtration since the elevated temperature is
critical to the fecal coliform test selectivity. Incubate at 44.5°C for 24 ± 2
hours, then examine the MF cultures under low-power magnification for
fecal coliform (blue colony) occurrences. Count and calculate fecal col-
iform density per 100 ml. Verify colonies using LTB (35°) then EC (44.5°).
MEMBRANE FILTER COLIFORM PROCEDURES 129
-------�
Occasionally gray to cream-colored colonies may be observed on
M-FC cultures. These organisms are not fecal coliforms and should not b|
counted as such. Count M-FC cultures promptly after their removal from'
the incubator since exposure to room temperature for more than 30
minutes may permit some of the gray to cream-colored nonfecal colifornf
colonies to ferment enough lactose to develop a pale blue color.
MF REPLICATES FOR SPECIAL STUDIES
The generally accepted practice of filtering a single 100-ml portion of'
potable water and single portions of three different increments of a!
polluted water is not acceptable in standard plate count determinations ofi
in special research studies. In these latter instances, where precision is!
most demanding, replication of filtration volumes is essential. Some idea
of the importance of replication to improve test precision can be seen
from a study of Figure 5. This bar graph was developed from data
obtained from 9 different samples examined by the nutrient agar pour
plate technique and from 25 different samples examined by the MF
Y/////A Nutrient Agar Plates - 9 determinations
I I Membrane filters - 25 determinations
ra
o
a
a>
o
h_
a>
I
3
Z
10
9
8
7
6
5
4
3
2
1
CE
\y//.
i f///,
I V///
i \///<
i i/////,
I X///////.
I V////////
- i y//////////////
zn
'//*\
'///A I
////I I
Y//X I
'////A I
V//////A I
/////////A I
////////f//////^ \
85
90
95
100%
105
110
115
Figure 5. Relative Precision of Replicates for Pour Plate
and Membrane Filter Cultures
130
Evaluating Water Bacteriology LaboratoriesIGeldreich
-------�
procedure using a similar enrichment agar. By increasing the number of
replicates, the 95 percent probability for the averaged MF or pour plate
count to approach the true density became significantly greater. Substan-
tial improvement in levels of data precision appears when 3, 5, or 10
replicates are selected, and increasing the number of replicates should be
carefully considered. Thus for routine analyses, every tenth sample
should be done in duplicate to verify continued level of data precision.
REFERENCES
I. American Public Health Association. American Water Works Association, Federation
of Sewage and Industrial Wastes Associations. Standard Methods for the Examination
of Water, Sewage, and Industrial Wastes, 10th edition. American Public Health Associ-
ation, New York. p. 395-404 (1955).
2. American Public Health Association, American Water Works Association. Water
Pollution Control Federation. Standard Methods for the Examination of Water, Sew-
age and Industrial Wastes, llth edition. American Public Health Association, New
York. p. 508-515 (1960).
3 Clark H F , Kabler, P. W., and Geldreich, E. E. Advantages and Limitations of the
Membrane Filter Procedures. Water & Sewage Works 104:385-387 (1957).
4. Shipe, E. L. Jr., and Cameron, G. M. A Comparison of the Membrane Filter with the
Most Probable Number Method for Coliform Determinations from Several Waters.
Appl. Microbiol. 2:85-88 (1954).
5. Shipe, E. L. Jr., and Fields, A. A Comparison of the Molecular Filter Technique with
Agar Plate Count for Enumeration of Escherichia coli. Appl. Microbiol. 2:382-384
(1954).
6. McKee, J. E. Report on the Disinfection of Settled Sewage. Sanitary Engineering
Research, California Institute of Technology, Pasadena, Calif. Apr. 1957.
7. McKee, J. E., McLaughlin, R. T., and Lesgourgues, P. Application of Molecular Filter
Techniques to the Bacterial Assay of Sewage. III. Effects of Chemical and Physical
Disinfection. Sewage and Ind. Wastes 30:245-252 (1958).
8. Lin, S. Evaluation of Coliform Tests for Chlorinated Secondary Effluents. Jour. Water
Poll. Contr. Fed. 45:498-506 (1973).
9. Greene, R. A. Evaluation of Membrane Filter Techniques as Applied to Coliform
Analyses of Chlorinated Wastewaters. Master of Science Thesis, College of Engineer-
ing, Univ. of Cincinnati, Ohio (1973).
10. McCarthy, J. A., Delaney, J. E., and Grasso, R. J. Measuring Coliforms in Water.
Water & Sewage Works 180:238-243 (1961).
11. Taylor, E. W., Burman, N. P., and Oliver, C. W. Membrane Filtration Technique
Applied to the Routine Bacteriological Examination of Water. Jour. Inst. Water Engrs.
9:248-263 (1955).
12. Burman, N. P., Oliver, E. W., and Stevens, J. K. Membrane Filtration Techniques for
the Isolation from Water, of Coli-aerogenes, Escherchia coli, Faecal Streptococci,
Clostridium perfringens, Actinomycetes and Microfungi. p. 127-135. In: Isolation
Methods for Microbiologists, Technical Series No. 3, Shapton, D. A., and G. W. Gould,
Eds., Academic Press (1969).
13. Rose, R. E., Geldreich, E. E., and Litsky, W. Improved Membrane Filter Method for
Fecal Coliform Analysis. Appl. Microbiol. 29:532-536 (1975).
14. Geldreich, E. E., Huff, C. B., Bordner, R. H., Kabler, P. W., and Clark, H. F. The
Faecal Coli-aerogenes Flora of Soils from Various Geographical Areas. Jour Appl
Bacteriol. 25:87-93 (1962).
15. Geldreich, E. E., Clark, H. F., Huff, C. B., and Best, L. C. Fecal-Coliform Organism
Medium for the Membrane Filter Technique. Jour. Amer. Waterworks Assoc. 57:208-
214 (1965).
16. Geldreich, E. E., Jeter, H. L., and Winter, J. A. Technical Considerations in Applying
the Membrane Filter Procedure. Health Lab. Sci. 4:113-125 (1967).
17. Thomas, H. A., Jr., Woodward, R. L., and Kabler, P. W. Use of Molecular Filter
Membranes for Water Potability Control. Jour. Amer. Water Works Assoc 48-1391-
1402 (1956).
18. Kabler, P. W. Water Examination by Membrane Filter and Most-Probable-Number
Procedures. A Committee Report. Amer. Jour. Pub. Health 44:379-386 (1954)
19. Thomas, H. A. Jr., and Woodward, R. L. Estimation of Coliform Density by the
Membrane Filter and Fermentation Tube Methods. Amer Jour Pub Health
45:1431-1437(1955).
MEMBRANE FILTER COLIFORM PROCEDURES 131
-------�
20 McK.ee, J. E.,and McLaughlin, R. T. Application of Molecular Filter-Techniques tothe
Bacterial Assay of Sewage. II. Experimental Results for Settled Sewage. Sewageand
Ind. Wastes 30:129-137 (1958).
21. Laubusch, E. J. MPN Coliform Index. Water & Sewage Works 105:334-338 (1958).
22. Hazey, G. An Operator's Viewpoint of the Membrane Filter Technique. The Amer.
City 73 (II):116-118 (1958).
23. Henderson, W. L. Studies on the Use of Membrane Filters for the Estimation of
Coliform Densities in Sea Water. Sewage and Ind. Wastes 31:78-91 (1959).
24. ORSANCO's 10th Annual Report. Membrane Filter Adopted. Water & Sewage
Works 106:140-141 (1959).
25. Buttiaux, R. Surveillance et Controle Des Eaux D'Alimentation. III. La Standardisa-
tion des Methodesd'Analyse Bacteriologique del'Eua. Revue d'hygieneetde Medicine
Sociale 6:170-192 (1958).
26. Streeter, H. W., and Robertson, D. A., Jr. Evaluation of Membrane Filter Technique
for Appraising Ohio River Water Quality. Jour. Amer. Water Works Assoc. 52:229-246
(1960).
27. McCarthy, J. A., Delaney, J. E., and Grasso, R. J. Measuring Coliforms in Water
Water & Sewage Works 108:238-243 (1961).
28. Benedict, I. J. Membrane Filter Technique. Water & Sewage Works 108:74-76(1961).
29. Taguchi, Katsuhisa. Experimental Studies on the Examination of Coliform Organisms
in Water. II. Application of the Membrane Filter Methods. Bull. Inst. Publ. Health
(Japan) 9(No. 4):214-222 (1960).
30. Petrilli, F. L.,and Agnese, G. On the Accuracy of the Methods Employed for Detecting
the Coliform Bacteria in Water and for Calculating the Microbial Density in General.
Boll. Inst. Sieroterap. Milan 39(l/2):74-86 (1960).
31. Walton, G. Effectiveness of Water Treatment Processes as Measured by Coliform
Reduction: Part I, Water Treatment Plant Data; Part II, Special Cooperative MF-MPN
Study. Public Health Service Publ. No. 898. Robert A Taft Sanitary Engineering
Center, U.S. Department of Health, Education, and Welfare, Cincinnati, Ohio (1964).
32. Mallmann, W. L., and Peabody, F. R. Multiple Tube Dilution and Membrane Filter
Methods. Water & Sewage Works 108:384-389 (1961).
33. Johnson, E. E. Millipore Filter Procedures; New, Approved Methods of Water
Analysis. Johnson Drillers Jour. 35(1): 1-3 (1963).
34. Ernst, G. E. The Bacteriological Examination of Water with the Membrane Filter
Versus Standard Method. Jour. Amer. Med. Technol. p. 225-227 June (1963).
35. Hoffman, D. A., Kuhns, J. H., Stewart, R. C., and Crossley, E. I. A Comparison of
Membrane Filter Counts and Most Probable Numbers of Coliforms in San Diego's
Sewage and Receiving Waters. Jour. Water Poll. Contr. Fed. 36:109-117 (1964).
36. Bordner, R. H., Scarpino, P. V., and Winter, J. A. Microbiological Methods for
Monitoring the Environment. I. Water and Waste Analyses. U. S. Environmental
Protection Agency (in preparation).
37. U.S. Environmental Protection Agency. Interim Primary Drinking Water Standards.
Fed. Register, 40:11990-11998 (March 14, 1975).
38. Fifield, C. W., and Schaufus, C. P. Improved Membrane Filter Medium for the Detec-
tion of Coliform Organisms. Jour. Amer. Water Works Assoc. 50:193-196 (1958).
39. Schiff, L. J., Morrison, S. M., and Mayeux, J. V. Synergistic False-Positive Coliform
Reaction on M-Endo MF Medium. Appl. Microbiol. 20:778-781 (1970).
132
Evaluating Water Bacteriology Laboratories IGeldreich
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GUIDELINES ON MEMBRANE FILTER COHFORM PROCEDURES
Membrane Filter Test Limitations
Laboratory recognized that turbid waters, excessive noncoliform populations,
heavy metal ions, and poor quality chlorinated effluents limits application
Application in the Standard Test
Demonstrated, by an initial parallel testing, that the MF yields essenli;illy
the same information as the completed test MPN on a variety of waters
Total Coliform Membrane Filter Procedure
Filter funnel and receptacle sterile at start of series
Funnel rapidly resterilized by UV, flowing steam, or boiling water
Absorbent pads saturated with medium; excess discarded
Test portions measured not less than 100 ml (± 2.5 percent) or divided for
multiple filtration of potable water
Funnel rinsed by flushing several 20- to 30-ml portions of sterile buffered
water through MF
MF removed with a sterile forceps grasping the area outside the
effective filtering area
MF rolled over medium pad or agar so air bubbles not formed
Incubation of Membrane Filter Cultures
Total incubation time 22 to 24 hours at 35°C (± 0.5°C)
Incubated in high humidity or in tight fitting culture dishes
Membrane Filter Colony Counting
Fluorescent light positioned for maximum reflection of colonies with
metallic yellowish surface luster
Colonies uniformly dispersed over effective filtration area
Special repeat samples requested when coliforms are "TNTC" or
colonial growth is confluent, obscuring coliform detection
Total coliform count calculated in density per 100 ml
Verification of Total Coliform Colonies
When coliforms found in potable water, verified all or 10 percent to lactose
or lauryl tryptose broth; then to BGLB broth
Coliform on one set of critical stream pollution samples to be used in
enforcement action verified
Choice of Total Coliform Methods
M-Endo MF broth or LES Endo agar used in a single step procedure
Incubated MF on LST absorbent pad for \V2 to 2 hours at 35°C; then on
M-Endo broth or LES Endo agar for 20 to 22 hours at 35°C
Enrichment procedure evaluated for optimum recovery of stressed
coliforms in chlorinated waters and industrial wastes
Fecal Coliform Membrane Filter Procedure
_dilution water; (pore size) MF
Following filtration, MF placed over pad saturated with M-FC broth
MF culture placed in waterproof plastic bag and submerged in water
bath within 30 minutes
Incubated at 44.5°C ± 0.2°C for 24 hours
Counts made promptly after removal from the incubator
Blue colonies counted as fecal coliforms
Count calculated in density per 100 ml
MEMBRANE FILTER COLIFORM PROCEDURES 133
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CHAPTER IX
SUPPLEMENTARY BACTERIOLOGICAL METHODS
Monitoring water quality may occasionally require the use of
supplementary microbiological tests that are specific for a particular
need. The standard plate count is recommended for measurement of the
general bacterial population in potable water. This population must be
controlled to reduce the potential public health risk due to secondary
pathogenic bacteria and to minimize interference with the detection of
low levels of coliforms. In swimming pool water (which has not been
considered in this Handbook), the standard plate count is the most impor-
tant test for determining the efficacy of the disinfection process. At the
same time, detection of Staphylococcus aureus and Pseudomonas
aeruginosa populations present in the water provides an important index
of potential skin, eye, ear, and nose infections. Although the primary
bacteriological parameter for monitoring fecal contamination of naturally
occurring recreational waters is the fecal coliform test, parallel examina-
tion for fecal streptococci is of value in interpreting the sources of fecal
contamination, i.e., from domestic wastes or from farm animals or
stormwater runoff.
Water pollution investigations may require the search for Klebsiella
pneumoniae to demonstrate that excessive concentrations of nutrients
are discharged in poorly treated paper mill or textile processing wastes. In
stream, lake, and estuarine field studies, qualitative tests for Salmonella
occurrence are often requested to demonstrate pathogen discharge in
effluents or pathogen persistence in receiving waters. Serotype identifica-
tion ofEscherichia coli and the isolation of enteropathogenic E. coli may
be of value in some epidemiological studies of waterborne outbreaks.
In areas remote from the laboratory, where samples cannot be received
within the specified time limit of 30 to 48 hours for potable waters or 6
hours for water pollution samples, the use of a delayed total coliform test
or fecal coliform procedure may be desirable. The entire testing proce-
dure may be done at the field site with the use of a MF field laboratory kit
or equivalent. Finally, during periods of emergency, a rapid (7-hour) fecal
coliform procedure may be a desirable supplement to the standard pota-
ble water analyses for quality assessment or in monitoring natural bathing
waters for data used to support decisions governing beach closures and
prompt reopenings.
STANDARD PLATE COUNT
The EPA's Primary Drinking Water Standards (1) specify that public
water supplies provide a potable water with no greater than 500 organisms
per 1 ml as determined by the standard plate count. This measurement can
be a valuable criterion for detecting water quality deterioration in supply
SUPPLEMENTARY BACTERIOLOGICAL METHODS 135
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distribution lines and storage reservoirs and for indicating the magnitude
of excessive bacterial populations (populations that may even suppress
visible gas production by coliforms and produce false-positive results in
the multiple tube test or overgrow membrane filter cultures, masking the
detection of total coliforms). The standard plate count limit would also
indirectly restrict the occurrence and magnitude of Pseudomonas,
Flavobacterium, and other secondary pathogenic invaders that could
pose a health risk in the hospital or in a similar environment of suscepti-
bles.
The application of a bacterial density limit to potable waters and swim-
ming pool samples requires strict adherence to a specific protocol that
yields reproducible results and measures a standardized population.
Sample bottles must be sterilized no more than 30 days before use; the
purpose of this time restriction is to reduce the possibility of chance
contamination in the sterile bottle supply during the storage period.
Samples collected for the standard plate count determination must be
transported to the laboratory as quickly as possible and immediately
processed to prevent significant bacterial density changes. These samples
may be transported without refrigeration only when the elapsed time
between sample collection and sample processing in the laboratory does
not exceed 8 hours. This transit time may be extended to periods up to 30
hours only if the samples are transported in iced containers (2).
Before preparing pour plates, shake the sample vigorously (approxi-
mately 25 times) to ensure proper distribution of the organisms within the
water sample. Some laboratories use a dilution bottle mechanical shaker
for vigorous sample agitation; however, such equipment is optional.
Limit the number of samples agitated on a mechanical shaker to four; this
will minimize bacterial stratification due to sedimentation of turbidity
particles during the time period between shaking and sample examina-
tion.
Triplicate sample portions are recommended to ensure optimum data
precision although duplicate plate counts are acceptable for routine
analyses. Sample portions of 1 ml and 0.1 ml may be pipetted directly into
the culture dish; portions of 0.01 ml must be prepared by dilution and 1 ml
of the appropriate dilution used. While pipetting sample volumes, do not
immerse the pipet more than 1 inch (2.5 cm) below the surface of the
sample or dilution. This will reduce the uncontrolled drainage of sample
from the outside of the pipet to the pour plate in preparation. Allowing the
portion of the pipet that was immersed to contact the inside of the sample
container upon withdrawal will also reduce the amount of liquid adhering
to the outer pipet walls. Hold the pipet at an angle of about 45 degrees with
the tip touching the inside bottom of Petri dish when dispensing the
sample. After the sample portion is delivered, gently touch the pipet tip
once against a dry spot in the culture dish bottom and withdraw the pipet.
Blow-out type pipets are not acceptable unless the mouth-end is plugged
with cotton. Gently blow out residual sample portion only in those cases
where such pipets are used. This protocol must be rigidly adhered to so
that replicate sample portions do not produce irregular colony counts.
The estimated amount of agar needed for preparation of the pour plates
should be available immediately after the portions are dispensed. No more
Evaluating Water Bacteriology LaboratoriesIGeldreich
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than 20 minutes should elapse in this procedure to prevent bacterial
density changes in the sample portion. Melt the required amount of agar in
a boiling water bath or in flowing steam not exceeding atmospheric
pressure. Before use, temper the melted agar in a water bath to 44° to
46°C. If the agar temperature exceeds these limits, some viable bacteria
will be killed. To determine melted agar temperature, use a separate flask
or bottle, identical to that used for sterile medium, containing glycerine
(or medium) and an accurate thermometer with bulb immersed in the
liquid. This blank flask or bottle should be exposed to the melting and
cooling procedures along with each lot of medium used. Do not melt more
agar than will be used within a 3-hour period to avoid development of
insoluble phosphate in the clear medium. These particles can be confused
with bacterial colonies during the counting procedure.
Flame the lip of media containers immediately before and periodically
during pouring into the culture dishes. Do not add less than 10 ml of
melted medium to the 100-mm-size culture dishes. The liquid agar and
sample portions are then thoroughly mixed by gently rotating the Petri
dish to spread the mixture evenly. It is also recommended that one control
plate (no sample added) should be prepared for each bottle of agar used to
verify that the agar was sterile before use. After the agar has solidified,
invert the pour plates and place in the incubator. Plate inversion during
incubation prevents condensation from dropping onto the agar surface.
The mandatory use of standard plate count agar and incubation of all
pour plate cultures of potable and swimming pool water samples at 35° ±
0.5°C for 48 ± 3 hours is essential. Many organisms in these samples have
been physiologically stressed, and this results in slow initial growth in
culture media. Bottled water and stored emergency water supplies must
be incubated at 35° ± 0.5°C for 72 ± 4 hours because many of the bacteria
in these waters demonstrate a prolonged lag phase during adaptation to
growth on tryptone glucose extract agar or plate count agar (3).
Count all colonies on selected plates promptly after the incubation
period. If counting must be delayed temporarily, store plates at 5° to 10°C
for a period of no more than 24 hours, but avoid this as routine practice.
Record the results of sterility controls on the report form for each lot of
samples.
A Quebec colony counter, preferably a Darkfield model that reduces
the light glare, is used to count all colonies on each plate, including
pinpoint-sized colonies. Avoid mistaking precipitated matter in the media
for pinpoint colonies. When spreading colonies are encountered, count
each chain of colonies originating from a separate source as one colony.
Do not count each individual growth in a spreader chain as a separate
colony. Each technician should be able to duplicate his count on the same
plate within 5 percent; different individuals counting the same plate
should be within 10 percent. Automatic plate counting instruments utiliz-
ing a television scanner and an electronic counter are now available. Such
instrumentation is acceptable if parallel evaluation with manual counting
gives comparable results.
After incubation, choose, from each sample, sets of replicate plates
that contain between 30 and 300 colonies per plate. Compute the bacterial
count per milliliter by multiplying the average number of colonies per
SUPPLEMENTARY BACTERIOLOGICAL METHODS 137
-------�
plate by the dilution used and report as the "Standard Plate Count" per
milliliter.
If there is no plate with 30 to 300 colonies, and one or more plates have
more than 300 colonies, use the plate(s) having a count nearest 300
colonies. Compute the count by multiplying the average count per plate
by the dilution used and report as the "Estimated Standard Plate Count"
per milliliter.
If plates from all dilutions of any sample have no colonies, report the
count as less than one (< 1) times the corresponding lowest dilution. For
example, if no colonies develop on the 1:100 dilution, report the count as
"less than 100 (< 100) Estimated Standard Plate Count" per milliliter.
If the number of colonies per plate far exceeds 300,do not report the
result as "too numerous to count" (TNTC). If there are fewer than 10
colonies per cm2, count colonies in 13 squares (of the colony counter)
having representative colony distribution. If possible, select seven con-
secutive squares horizontally across the plate and six consecutive
squares at right angles; be careful not to count a square more than once.
Multiply the sum of the colonies in 13 representative square centimeters
by 5 to compute the estimated colonies per plate when the area of the plate
is 65 cm2. When there are more than 10 colonies per cm2, count four
representative squares, take the average count per square centimeter,
and multiply by the appropriate factor to estimate the colonies per plate
(usually about 65). When bacterial counts on crowded plates are greater
than 100 colonies per cm2, report the result as greater than (>) 6,500 times
the highest dilution plated.
If spreading colonies (spreaders) are encountered on the plate(s)
selected, count colonies on representative portions only when (a) col-
onies are well distributed in spreader-free areas, and (b) the area covered
by the spreader(s) does not exceed one-half the plate area.
When spreading colonies must be counted, count each unit of the
following types as one: (a) the first is a chain of colonies that appears to be
caused by disintegration of a bacterial clump as the agar and sample were
mixed. Count each such chain as a single colony; do not count each
individual colony in the chain; (b) the second type of spreader develops as
a film of growth between the agar and the bottom of the Petri dish; (c) the
third type forms in a film of water at the edge or over the surface of the
agar. Types (b) and (c) largely develop because of an accumulation of
moisture at the point from which the spreader originates. They frequently
cover more than half the plate and interfere with obtaining a reliable plate
count.
If plates prepared from the samples have excessive spreader growth,
report as "Spreaders" (Spr). When plates are uncountable due to missed
dilution, accidental dropping and contamination, or the control plates
indicate that the medium or other material or labware was contaminated,
report as "Laboratory Accident" (LA).
When colonies on replicate plates, or consecutive dilutions, or both,
are counted and the results are averaged before recording, round off
counts to two significant figures only at the time of converting the calcula-
tion to standard plate count per milliliter.
Avoid creating fictitious ideas of precision and accuracy when comput-
138
Evaluating Water Bacteriology Laboratories/Geldreich
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ing standard plate counts: record only the first two lefthand digits. Raise
the second digit to the next highest number only when the third digit from
the left is 5, 6, 7, 8, or 9; use zeros for each successive digit toward the
right from the second digit. For example, a count of 142 is recorded as 140,
and a count of 155 as 160, whereas a count of 35 is recorded as 35.
Staphylococcus
Since a specific direct method is not available for detecting
Staphylococcus aureus in swimming pool water, partition counts must be
made on media used for total Staphylococcus determinations (4-7).
Staphylococcus total counts can be made using Chapman-Stone agar,
M-Staphylococcus broth, or Vogel-Johnson agar in conjunction with the
MF procedure; incubate 48 hours at 35°C. Although typical Staphylococ-
cus aureus colonies may appear on Chapman-Stone agar and
M-Staphylococcus broth cultures as yellow pigmented colonies or on
Vogel-Johnson agar as shiny black colonies, individual samples may
contain stressed strains that fail to pigment on the MF. Detection of
Staphylococcus aureus in natural bathing waters may require the addition
of 0.7 mM sodium azide to M-Staphylococcus agar (8) and the inclusion of
lipase manitol salts agar (9) in the isolation procedure to suppress inter-
ferences from Gram negative bacilli (10). Therefore, a proportion of all
colonies present on the MF culture must be verified to determine the
percent occurrence of Staphylococcus aureus. It will be necessary to
replicate from these MF cultures or verify a percentage of individual
colonies as positive in both coagulase medium and dextrose broth as well
as demonstrate that these catalase positive organisms are Gram positive
cocci.
Pseudomonas aeruginosa
If Pseudomonas aeruginosa is present in potable water supplies or
recreational waters, it can be detected by using M-PA agar and the MF
procedure (11) or by using asparagin broth with confirmation in acetamide
medium in a multiple tube procedure.
MF cultures on M-PA agar are incubated at 41.5°C for 48 hours.
Colonies of Pseudomonas aeruginosa on this medium have a flat appear-
ance with darkish-brown to greenish-black centers surrounded by an
opaque to translucent white periphery. Colony verification involves
streaking individual plates of Brown — Scott Foster milk agar (12) with
selected isolated colonies from the MF culture. The milk agar plates are
incubated at 35°C for 24 hours. Pseudomonas aeruginosa hydrolyzes the
casein and produces a yellowish-green to green diffusible pigment.
In the multiple tube procedure, inoculate sample portions into as-
paragine broth; use single-strength broth for sample volumes of 1 ml or
less and double-strength broth if 10 ml inocula are required. Incubate all
tubes at 35° to 37°C. After 24 and 48 hours of incubation, examine each
tube under black light for production of a greenish fluorescence in the
culture. Such observations constitute a positive presumptive test. Con-
firm positive presumptive tubes by transferring a loop full of broth to
either acetamide agar slants or acetamide broth. A positive confirmed
reaction is indicated by a purple color (high pH) development within 48
hours at 35° to 37°C.
SUPPLEMENTARY BACTERIOLOGICAL METHODS 139
-------�
In those waters that exhibit significant false positive results in the
presumptive test, change the incubation temperature to 39°C to reduce
the recovery of fluorescent pseudomonads such as Pseudomonas
fluorescent and Pseudomonas putida (13). To further verify positive
acetamide tubes, transfer growth to A medium (King, Ward, and Raney)
for a test of pyocyanin production (14).
FECAL STREPTOCOCCI
The use of the MF method or agar pour plate technique for fecal
streptococci detection is recommended over the multiple tube procedure
for the following reasons: (a) recoveries on MF media currently in use are
higher and less affected by interference organisms; (b) greater numbers of
false positive reactions occur in broth MPN systems; and (c) when group
or species identification is required, MF plates and agar pour plates
readily allow for primary isolations of fecal streptococcus colonies. How-
ever, the Standard Methods (15) multiple tube procedure that employs
azide dextrose presumptive broth (16) and ethyl violet azide confirmatory
broth (17) must be used on waters with high turbidities that interfere with
membrane filtration.
Media available for use with the MF procedure include
M-Enterococcus agar (18) and KF Streptococcus agar (19). Both media
give equivalent results when domestic sewage is examined because Strep-
tococcus fecalis and its biotypes are the predominant fecal streptococci in
domestic wastes. However, the recovery of Streptococcus bovis and
Streptococcus equinus, both of which are common to feedlot runoff and
meat packing operations, is much better on KF agar. For this reason, KF
agar is the recommended medium for many water pollution investiga-
tions.
Where the pour plate method is preferred, KF Streptococcus agar or
PSE agar (20,21) may be used since these two media give essentially
equivalent streptococcus recoveries. However, PSE pour plates require
only a 24-hour incubation period whereas KF agar must be incubated 48
hours to permit optimum fecal streptococcus colony development. When
chlorinated sewage effluent and water samples with high turbidity must
be examined, use the pour plate technique, with either PSE or KF agar, in
preference to the MF procedure.
Normally there is no need for species identification of fecal strep-
tococci in stream pollution studies. Density relationships with fecal coli-
forms are adequate to assign the probable source of waste discharge as
being domestic or from farm animals and wild life. However, special
applications involving tracer organism identification, confirmation of
sanitary significance of very low fecal streptococcus densities, and media
evaluations will require further biochemical identification. The basic
biochemical tests (Figure 6) include observation of growth in brain-heart
infusion broth within 2 days at 45°C, and within 5 days at 10°C; plus
confirmation for growth at 45°C in 40 percent bile and a negative catalase
reaction. Beyond this point, further choice of biochemical tests varies in
number and kind depending upon the researcher's viewpoint (22-26).
Practical application of identification procedures demands a simplifica-
tion of the tests and more specific biochemical reactions. Further de-
Evaluating Water Bacteriology Laboratories/Geldreich
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r1
w
S
tfl
z
>
70
DO
>
O
w
70
O
O
O
O
s
ttf
O
a
PSE Agar
*
brownish-black colony
with brown halo
KF Agar
*
pink-red colony
growth in brain-heart infusion broth within 2 days at 45° and 5 days at
10°C with confirmation as catalase-negative -
growth at 45°C and 10°C
*
confirm with growth in 5.5% NaCI
and pK-9.5 in brain-heart infusion
broth and reduction of 0.1% methylene blue
t
enterococcus group
reduction of K2TsOs TTC and
fermentation of d-sorbitol and glycerol
starch hydrolysis
positive
I
s. faecalis and varieties
I
hydrolysis of gelatin
x' •**.
positive negative
* *
s. faecalis s. faecalis and
var. liquefaciens s. faecalis var. zymogenes
nemolysis
negative positive negative
+ * *
s. faecmm and s. durans atypical s. faecalis peptonization of
t (vegetation source) Litmus milk
fermentation of l-arabmose - ~-_
positive
*
s. faecium
negative
*
s. durans
positive negative
* *
s. faecalis enterococci
var. liquefaciens (warm-blooded
(insect source) animal sources)
growth at 45°C only
^ ^
s. bovis s. equinus
^ x
starch hydrolysis
I
positive
*
lactose fermentation
^ ^
acid only no change
i i
s. bovis s. equinus
(livestock and poultry sources)
positive
t
s. faecalis
var. zymogenes
negative
*
s. faecalis
Figure 6. Schematic Outline for Identification of Fecal Streptococci
-------�
velopment of a serological schema, which currently includes 39
serotypes, could be an important breakthrough in this problem (25,27-32).
Klebsiella
Specific differential media for the detection of Klebsiella are being
investigated. The use of a nitrogen-deficient medium (33) is a promising
approach for differentiating between Klebsiella and Enterobacter. On
this medium, Klebsiella colonies are larger in size and more convex and
mucoid in appearance than are Enterobacter. Since Klebsiella are coli-
forms, the use of M-Endo MF and the MF procedure may be the most
practical means for primary isolation since this medium is commonly
available in most laboratories. All typical coliform colonies or a signifi-
cant percentage of these colonies are then purified and submitted to the
oxidase test, lactose fermentation, and the HOMoC series (hydrogen
sulfite, ornithine decarboxylase, motility, and citrate utilization) of
biochemical tests. Klebsiella biochemical characteristics are: oxidase
negative, lactose positive, hydrogen sulfite negative, ornithine decar-
boxylase negative, motility negative, and utilize citrate as the sole source
of carbon (34-36). The IMViC biochemical reactions (indole, methyl red,
Voges-Proskauer, and citrate) for Klebsiella are !-+, identical to
Enterobacter (Aerobacter) aerogenes.
Salmonella
The most logical approach to Salmonella quantitation would be apply-
ing the MF procedure since this method has the advantage of large volume
analysis, limited only by the turbidity of the sample. Unfortunately, there
is only one quantitative MF method available for Salmonella detection,
M-Bismuth Sulfite broth (37), and it is essentially specific for Salmonella
typhosa detection, with poor recovery for most of the other 1200 Sal-
monella serotypes that might be encountered. Other quantitative
methods have been proposed, but they also use the multiple tube principle
and involve complex manipulations that lack the selectivity necessary for
use with water samples. Apparently the excessive bacterial flora in
grossly polluted waters overwhelms the selective, suppressive action of
media currently in use for Salmonella recovery.
For these reasons, emphasis has been placed on qualitative methods for
Salmonella detection with the further understanding that there is no
single optimum concentration method, enrichment procedure, selective
differential medium, or incubation temperature that will ensure the re-
covery of all Salmonella strains present in polluted water. Thus, several
alternative choices in methodology must be considered, and the final
decision depends upon the type of water to be examined.
There are three basic concentration techniques for Salmonella recov-
ery from water: (a) sterile gauze pads submerged 3 to 5 days in water at a
sampling site, with entrapped water expressed from pad to enrichment
media (Moore pad technique); (b) filtering 2-liter sample volumes through
diatomaceous earth held in place in the MF funnel by an absorbent pad
followed by the addition of portions of the plug to enrichment media; and
(c) filtration of a large volume sample through the MF, which in turn is
added to a suitable enrichment broth. Gauze pads have been very useful
142
Evaluating Water Bacteriology Laboratories/Geldreich
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in recovering Salmonella from natural waters that are free of excessive
debris. The diatomaceous earth procedure will often produce better re-
sults where floating solids are present, such as in sugar beet effluents and
paper mill wastes and most estuarine environments. MF filtration is often
more useful when investigating contaminated wells or suspect potable
water supplies. Salmonella have also been successfully isolated from a
potable water supply by selecting M-Endo MF cultures that contain
significant background growth and total coliforms, after counting, and
placing the entire MF with the mixed growth into 10 ml of tetrathionate
broth (containing 1:50,000 brilliant green dye) for Salmonella enrichment
(38). This unique approach requires no special large sample collections
and can be an extension of the routine total coliform analysis. For large
volume samples, the transit time must not exceed 6 hours, and the initial
processing, once received in the laboratory, must begin promptly.
Selective enrichment for Salmonella recovery from gauze pads,
diatomaceous earth, or the MF into dulcitol selenite broth, tetrathionate
broth, or GN broth is necessary to enrich the growth of Salmonella while
suppressing the coliform population from a sample. Extending the incu-
bation time from 1 to 5 days with daily streaking of cultures enhances the
recovery of all Salmonella serotypes that might be present. Further
separation of Salmonella strains from other members of the bacterial flora
in feces and polluted fresh water has been accomplished by using a variety
of enrichment-plating — incubation-temperature combinations: 37° to
37°C; 37° to 41.5°C; and 41.5° to 37°C (39-41). The recovery of Salmonella
organisms from solid waste — sludge mixtures, municipal solid waste,
and incinerator residue and quench water has been found to be optimal
when enrichment incubation at 39.5°C for 16 to 18 hours is used (42).
Salmonella detection in estuarine waters (using the same enrichment
media), however, appears to be more successful when 37°C is the chosen
incubation temperature (43). These observations demonstrate that the
choice of media, incubation temperature, incubation time, and water
sample source are interrelated factors that influence Salmonella recov-
ery. Therefore, a variety of plating media should be used to isolate
Salmonella strains from enrichment cultures. Brilliant green agar, Hek-
toen enteric agar, xylose lysine desoxycholate agar, and bismuth sulfate
are most often chosen because of their more selective recovery.
Preliminary Salmonella Screening
From each selective medium, choose isolated colonies of Salmonella-
like appearance. Restreak these strains on the differential media to obtain
pure cultures before proceeding to the preliminary screening procedures.
If the laboratory has fluorescent antibody (FA) capability, it is recom-
mended that suspect cultures be given a preliminary screening in this
technique before proceeding to a study of differential test reactions. Since
the FA technique does have cross-reaction problems that produce false
positives, this method can only be recommended as a rapid gross screen-
ing of suspect colonies to eliminate a variety of strains that would other-
wise require submission to selected differential tests.
In the FA technique (44), a light saline suspension is prepared from an
18- to 24-hour agar slant pure culture. Smears of this suspension are then
SUPPLEMENTARY BACTERIOLOGICAL METHODS 143
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prepared on clear-glass FA slides (1.0 to 1.1 mm thick). After the smears
are air dried, they are fixed for 2 minutes in Kirkpatrick's fixative, rinsed
briefly in 95 percent ethanol, and allowed to air dry. Do not blot dry these
preparations. Once the fixed smears are dry, cover with one drop of
Salmonella polyvalent OH conjugate, previously diluted 1:8. Place the
slides in a moist chamber to prevent evaporation of the staining reagent,
and after 30 minutes, wash away excess reagent by dipping each slide in
buffered saline (pH 7.5 to 8.0). Then place each slide in a second bath of
buffered saline for 10 minutes, remove, rinse in distilled water, and drain
dry. Place a small drop of mounting fluid on the smear and cover with a
No. 1 coverslip. Examine under fluorescence scope, using UG-1 (2 mm)
primary filter and GG-9 (1 mm) ocular filter for evidence of a positive
agglutination fluorescence.
In those laboratories without FA test capabilities, suspect colonies are
further characterized by a study of fermentation reactions in triple sugar
iron agar and reactions to indole, motility, urease, and lysine decar-
boxylase. Commercial differential media kits are also available for use in
this preliminary screening procedure before serological confirmation
(45,46). Although test reactions from these kits may range from 95 to 98
percent agreement with conventional tests, some significant individual
differences may occasionally occur. In some instances, supplemental
tests will be necessary to further differentiate among strains of the large
group of Enterobacteriaceae.
Serological Grouping of Salmonella
Upon completion of the recommended biochemical tests used to tenta-
tively identify suspected colonies as Salmonella, inoculate the pure cul-
ture strain (if necessary, re-streak culture on one of the differential agars
to check for purity) into trypticase soy broth or brain heart infusion broth.
Then incubate the inoculated broth for 24 hours at 37°C. To ensure
maximum culture vigor, transfer the strain through several fresh tubes of
brain heart infusion broth before a final inoculation onto slants of brain
heart infusion agar. The culture is then ready for the slide agglutination
test.
Subdivide a glass slide into appropriate squares, using a thick wax
pencil (47). Place a drop of Salmonella "O" polyvalent antiserum on one
square, antiserum plus 0.85 percent sodium chloride on a second square,
bacterial suspension in 0.85 percent sodium chloride on another square,
and bacterial suspension in 0.85 percent sodium chloride plus antiserum
on a fourth square. Gently rock the slide for a maximum of 2 minutes and
observe for development of an agglutination reaction in the fourth square
only. If agglutination occurs, repeat the slide agglutination procedure
using the specific Salmonella "O" antiserum groups for serotype identi-
ty. For those cultures that do not react to specific "O" Salmonella
antiserums, repeat the slide agglutination procedure using Salmonella Vi
antiserum. A negative agglutination response in Salmonella Vi antiserum
indicates the strain is not of the Salmonella genus and can be discarded. If
agglutination does occur, then heat the culture in a boiling water bath for
10 minutes, cool, and retest with the individual Salmonella "O" an-
tiserum groups and Salmonella Vi antiserum. As a recommended proce-
144 Evaluating Water Bacteriology Laboratories/Geldreich
-------�
dure, submit the tentatively identified culture to a certified public health
laboratory or national typing center for verification of serotype.
Salmonella isolations from water samples should only be conducted in
laboratories that have personnel experienced in medical bacteriology or
trained in these procedures. The search for pathogens in water requires
certain expertise in selecting methodology and media and in interpreting
results. Such personnel may not be available in the small laboratory
limited to routine water testing.
PATHOGENIC LEPTOSPIRES
The presence of pathogenic leptospires in natural waters is extremely
variable and is complicated by many factors that make interpretation of
results extremely difficult. These include intermittent leptospire dis-
charge from infected wildlife or farm animals near the watercourse,
stormwater runoff, and flooding of contaminated land areas in the
watershed (48). Favorable persistence in warm, slow-moving waters
having a pH of 6.0 to 8.0 (49-52) and moderate levels of bacterial nutrients
(53) also complicates the interpretation of leptospire occurrences. Even
when pathogenic leptospires are present, their detection is difficult be-
cause of the competitive growth of other organisms (54) and the necessity
to differentiate between pathogenic and saprophytic strains (50,54-57).
Keep in mind, therefore, that failure to isolate pathogenic leptospires
from natural waters does not necessarily indicate their absence.
These factors explain why qualitative methodology has evolved to
concentrate leptospires from water. Long-term incubation on various
media is necessary because of the relatively slow growth of the organisms
in the laboratory. During incubation, inoculated media are repeatedly
checked for the appearance of leptospires and for culture contamination.
Upon detection, various biochemical responses supplemented by
serological identification can be used to separate pathogenic and sap-
rophytic strains of leptospire isolates. Animal tests for pathogenic lepto-
spires are also recommended, but these should be done on primary pure
culture isolates since pathogenic strains may become avirulent through
subsequent culture passages.
Preliminary Concentration
Pathogenic leptospira may be concentrated in near-shore bottom sedi-
ments of streams and farm ponds. Therefore, gentle agitation of bottom
sediment before sampling is recommended to ensure collection of
bacteria-laden material from the sediment-water interface. The bac-
teriological bottom sampler may also be used to collect this finely sus-
pended material in sterile plastic bags. Upon return to the laboratory (or,
preferably, to a field site), vigorously shake the sample to release entrap-
ped bacteria from the sediment and immediately prefilter through either a
Whatman No. 1 filter paper or a MF absorbent pad to remove heavy
turbidity. Pass the prefiltered sample through a Swinney hypodermic
adapter containing a fiber glass prefilter and a MF of 0.45-micron pore
size to separate leptospires (which can pass through the pores into the
filtrate) from other organisms present in the sample (that are retained by
the MF).
SUPPLEMENTARY BACTERIOLOGICAL METHODS 145
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Cultivation
Portions of sample filtrate (1-ml and 0.1-ml quantities) may then be
inoculated into Fletchers semisolid medium containing 10 percent rabbit
serum (58). Incubate the inoculated medium at 30°C for 6 weeks, and
examine each tube (using darkfield illumination and 250 x magnification)
at least once a week for leptospiral growth and culture contamination (59).
Strains of Vibrio or Spirillum are the most common contaminants ob-
served, particularly when filtrate volumes greater than 0.1 ml are
examined (58).
Leptospires are helicoidal, usually 6 to 20 microns in length, and each
coil is about 0.2 to 0.3 micron in diameter. The coils of leptospires are
more compact than those of other spirochaetes (59). If leptospires are not
observed microscopically within a 6-week incubation period, the test is
considered negative.
As an alternate enrichment procedure, spread plates of plate count agar
(60) or bovine albumin polysorbate 80 medium (61,62) may be inoculated
with 0.1- to 1.0-ml volumes of sample filtrate and incubated at 30°C for 7 to
9 days. When bovine albumin polysorbate 80 medium is used, an agar
overlay of 0.7 percent distilled water agar is recommended. Regardless of
the choice of agar medium, prepare the agar before inoculation (1 or 2
days) to condition it and, thus, promote even spreading of the inoculum
over the agar surface. Use darkfield microscopy to identify morphologi-
cally all colonies that develop before conducting biochemical and serolog-
ical tests or animal inoculations.
Differentiation of Leptospires
The detection of pathogenic leptospires in lakes and streams indicates
leptospirosis in domestic animals and wildlife that frequent these waters,
and signals the health risk to bathers using these waters. Therefore, the
ability to differentiate pathogenic from saprophytic leptospire strains
isolated from the water environment is of critical importance.
Culture Reactions
Saprophytic leptospires are strongly resistant to 10 micrograms copper
sulfate per ml (56) or 100 microgram 8-azaquahine per ml (55) in Stuart's
medium containing 10 percent rabbit serum. Only the saprophytic leptos-
pires grow in a 10 percent rabbit serum mediutn at 13°G (50). In addition,
saprophytic strains demonstrate higher oxidase response (63) and higher
egg yolk decomposition activity (64) than pathogenic leptospires. Op-
timum laboratory cultivation temperature for the pathogenic leptospires
is 30°C; incubate all test cultures for 5 days for organisms to reach their
optimum growth phase. No single test should be used to differentiate
saprophytic from pathogenic leptospires (65).
Verification of Pathogenicity
Commercial antisera are available that permit tentative identification of
pathogenic leptospires. Final verification of the suspect pathogenic strain
by animal testing should be conducted, but only by laboratories with
established expertise in these procedures.
146
Evaluating Water Bacteriology Laboratories/Geldreich
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ENTEROPATHOGENIC Escherichia coli
The examination of suspect potable water supplies for en-
teropathogenic E. coli can be initiated by use of the fecal coliform MF
procedure, utilizing M-FC broth (66). M-Endo broth may be used, but
more effort will be needed to isolate the E. coli from the total coliform
colonies (67). Blue colonies from the M-FC cultures are streaked and
purified and IMViC biochemical reactions determined. Those strains
producing gas by lactose fermentation and having a + H IM ViC reac-
tion are then tested serologically (68).
Three classes of antigens are important in the determination of the E.
coli serogroups. The heat-stable and major grouping-factor "O" antigen
is associated with the bacterial cell, the "K" antigen is associated with
the envelope or capsule, and the "H" antigen with the flagella. The "K"
antigen has three varieties (L, A, and B), which differ in heat lability and
heat inactivation of binding power. Slide agglutination is employed for
"0" and "K" antigen determinations, and the macroscopic tube test is
recommended for confirmation of "O" antigens.
DELAYED INCUBATION COLIFORM PROCEDURES
Occasionally, it is desirable to filter samples in the field and then
transport the MF cultures to the laboratory for subsequent incubation and
examination. For total coliforms, use a modified M-Endo MF broth or
LES Endo agar to slow bacterial growth during 1- to 3-day shipment to the
laboratory for final processing (69-72). To prepare the holding medium
used in the field, add 0.384 grams of sodium benzoate (USP Grade) or 3.2
ml of a 12 percent (W/V) sodium benzoate solution to 100 ml of either
M-Endo MF broth or LES Endo agar. Where overgrowth from fungus
colonies causes problems, adding 50 mg cycloheximide (actidione) per
100 ml of Endo holding medium is desirable.
Upon arrival in the laboratory, transfer the MF cultures to a fresh
culture dish containing standard M-Endo MF broth or LES Endo agar,
and incubate the plates at 35°C for 20 to 22 hours. If growth is visible at
time of transfer, hold the cultures in a refrigerator until the end of the work
day and incubate them at 35°C overnight (16- to 18-hour period). Then
count the sheen colonies and calculate the total coliform count per 100 ml.
It is essential that the laboratory establish the validity of the delayed
incubation test for total coliforms on those waters that are to be examined
routinely by this procedure. Wide variations in ambient temperature and
storage periods up to 72 hours before final processing of the MF cultures
in the laboratory may stimulate the growth of some false positive, non-
coliform organisms that are capable of partial breakdown of lactose. Once
the magnitude of these occurrences has been determined, through sheen
colony verification, data from the delayed incubation test for total col-
iform detection may be more accurately interpreted.
The delayed incubation concept can also be applied to fecal coliform
measurements (73). After the water sample has been filtered in the field,
place the MF in contact with an absorbent pad saturated with VFC
(vitamin-free casitone) holding medium and send, via mail service, to the
laboratory for final processing. Although the delayed incubation proce-
SUPPLEMENTARY BACTERIOLOGICAL METHODS 147
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dure will hold for up to 72 hours, the holding period should be minimal,
and for some distant locations, air mail and/or special delivery should be
used. Upon receipt of the samples in the laboratory, transfer the MF
cultures to fresh culture dishes containing absorbent pads saturated with
M-FC broth, place in waterproof plastic bags, and incubate, submerged,
in a 44.5°C water bath for 22 ± 2 hours. Then count the blue-colored
colonies (fecal coliforms) and calculate the count per 100 ml.
For verification, inoculate selected colonies into lactose broth orlauryl
tryptose broth for incubation at 35°C. Transfer inoculum from each cul-
ture showing gas production in 24 or 48 hours to individual EC broth tubes
for verification of lactose fermentation at44.5°C in 24 hours. The verifica-
tion procedure is recommended as an initial control check of the delayed
procedure when the delayed incubation procedure is to be used for the
examination of source waters on a continual basis. This check on the
validity of delayed test results for specific waters may also be useful to
demonstrate the test accuracy when laboratory data are to be used in
enforcement actions.
RAPID METHODS
Rapid assessment of the sanitary quality of water is often needed for
emergency or temporary potable water supplies, bathing beaches whose
quality may have deteriorated following storms, and shellfish growing
areas subject to sewage pollution. One approach to the quick determina-
tion of water quality has utilized C14-labeled sodium formate in a rapid
(4-hour) test for total coliforms (74,75). The procedure shows considera-
ble promise when used for fecal coliform detection but must be refined for
greater reproducibility and increased sensitivity to coliform concentra-
tions below 100 organisms per 100 ml. A membrane filter — fluorescent
antibody (MF-FA) technique has also been proposed for the rapid iden-
tification of fecal coliforms (76,77). Before the MF-FA test for fecal
coliforms can be considered practical, however, commercial polyvalent
antisera must be developed that include all 145 "O" antigens and 86
"K(B)" antigens identified with the E. coli group. In addition, antigens
for a few Enterobacter and Klebsiella strains, which are also defined as
fecal coliforms, must be included. At present, the three commercially
available polyvalent antisera contain only 20 "O" and "B" serotypes.
Such rapid methods as these may not be adaptable to true emergency
situations where skilled personnel and specialized equipment are not
available. At present, the most promising approach involves the use of a
new MF procedure utilizing a lightly buffered, lactose-mannitol-based
medium (M-7-hour) containing an acid-sensitive indicator system. Fol-
lowing filtration, cultures in this procedure are incubated submerged
(using waterproof plastic bags) in a 41.5°C water bath for 7 hours (78,79).
Colonies must be examined at 10 to 15 x magnification using either a
fluorescent light or an incandescent microscope light with a blue filter.
Fecal coliform colonies appear yellow, generally very bright and distinct,
but all colonies having a yellow appearance should be counted.
Results from a study of fecal coliform differentiation showed that 94.3
percent of 4,082 yellow colonies from the 7-hour medium verified as fecal
colitorms and, from the same samples, 93.7 percent of 4,034 blue colonies
Evaluating Water Bacteriology LaboratorieslGeldrekh
-------�
on the M-FC control medium, after a 24-hour incubation, verified as fecal
coliforms. These data indicate that both media measured essentially the
same population of bacteria.
To verify fecal coliform colonies on the M-7-hour medium, transfer
inocula from yellow colonies into individual tubes of lactose broth or
lauryl tryptose broth for gas production at 35°C within 48 hours. Then
inoculate growth from each positive lactose tube into EC broth for con-
firmation of gas production at 44.5°C for 24 hours. Initial verification of
the colonies on the 7-hour medium is desirable to demonstrate the effec-
tiveness of the medium to the technician using the procedure for the first
time.
During periods of emergency water testing, it is suggested that the rapid
test be used to supplement the standard MF total coliform test. This
protocol will permit the rapid detection of gross fecal contamination in 7
hours while awaiting the 24-hour test results for a total coliform limit of
one total coliform per 100 ml.
PORTABLE FIELD LABORATORY PROCEDURES
By virtue of both the simplicity of operation and the compactness of
essential apparatus, the MF procedure readily lends itself to field applica-
tions. These investigations may involve routine water quality monitoring
in remote areas or be of a preliminary survey nature before initiating an
in-depth field study. Recognizing the potential of this procedure for
monitoring potability of water supplies used in military operations, Col.
Thomas Sparks and his laboratory staff at Fort Sam Houston designed
and field-tested a MF portable laboratory package that had the general
configuration of a suitcase the size of a picnic cooler. Within the fiber
glass carrying case was the filtration funnel, plastic Petri dishes, am-
pouled or preweighed media vials, a hand-pumped vacuum source, a
suitable electrical incubator designed to operate on 6, 12, and 24 volts DC
or 115 and 230 volts AC or DC, plus other small items associated with the
technique. With such a kit (Millipore Portable Water Laboratory,
XX63-001-50), the properly trained technician can test approximately
24 water samples, as prescribed in Standard Methods (11), for total
coliform analysis. A portable heat sink block (Millipore XX63-004-00 or
equivalent) is an available accessory that can be used for field incubation
of MF cultures for fecal coliform determinations.
Several different methods of medium preparation can be used in con-
junction with the portable field laboratory—ampouled M-Endo medium is
the most convenient. Each ampoule contains sufficient sterile, prepared
medium to saturate one absorbent culture pad. Shelf life for ampouled
M-Endo medium is approximately 18 months. Supplies must be stored at
refrigerated temperatures (4° to 10°C) during this period and protected
from excessive light exposure. Ampoules that appear turbid or dark red in
color may be contaminated and should not be used. Another approach to
media supplies for field use is to prepare, or purchase, vials of preweighed
dehydrated M-Endo medium. When needed, the desired number of pre-
weighed vials of medium are reconstituted with the appropriate amounts
of distilled water, 2 percent ethanol (not denatured) is added, and the
medium is carefully heated to dissolve the ingredients. The finished
SUPPLEMENTARY BACTERIOLOGICAL METHODS 149
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medium preparation is then dispensed in 2-ml volumes into culture dishes
containing absorbent culture pads. Poured agar plates of the appropriate
medium previously prepared in the laboratory may also be used in the
field kit. Dehydrated medium pads that are reconstituted by adding 2 ml of
sterile distilled water are not recommended, however, because the shelf
life of this version of M-Endo medium is approximately 3 months or less
and the medium quality is not uniform.
Other available field testing procedures that utilize the MF for bacterial
cultivation include a multi-purpose disposable filtration culture device
(the field monitor). This device serves initially as the filtration chamber
and then as the culture package when a modified Endo formulation is
injected into a pad below the filter. The unit is then ready for incubation
and subsequent colony counting. Several independent evaluations of the
field monitor concept for total coliform recovery from polluted water
indicate that only 70 percent recovery of the known bacterial density is
being obtained. The remaining organism loss occurs from: (a) some
bacterial bypass around the filtration area to the pad below the membrane
or directly to discharge through the bottom port and (b) failure of some
debilitated or stressed cells to grow on the membrane and medium. In an
attempt to seal off the bypass loss, the manufacturer has added a hydro-
phobic substance to the outer periphery of the filter. Inclusion of a
consistent amount of normal-strength medium is dependent on displace-
ment of the water entrapped in the pad with 1.3 times normal-strength
ampouled medium filtered through the field monitor following water
sample filtration. Vapor blockage and uneven flow-through will result in
uncertain medium concentrations in the pad substrate and will ultimately
affect bacterial growth. Ampouled media have a limited shelf life that
must be recognized by the laboratory—6 months for M-FC and 18 months
for M-Endo when stored in the dark, preferably at refrigeration tempera-
tures .
A bacteriological "dip-stick" has also been developed that appears to
offer the ultimate yet achieved in test simplicity at some sacrifice in
sensitivity and flexibility. This device consists of a sterile, rectangular-
shaped MF positioned above a medium-impregnated pad, both of which
are secured to a plastic frame that is inserted into a mating plastic case.
The basic principle of operation is the controlled absorption of 1 ml of
sample through the membrane to the medium-impregnated pad of critical
thickness when the dip stick is held in a water sample for approximately
30 seconds. The small volume of sample makes the dip stick self-limiting
for total coliform analyses in potable water because the test baseline is
established as less than one coliform per 100 ml. Preliminary evaluation of
the dip stick for use as a standard plate count measurement in potable
water, when compared with the Standard Methods procedure, shows the
method to result in significantly lower bacterial counts, possibly because
of the toxicity inherent in the gray-black MF and the inadequately en-
riched medium. The fecal coliform dip stick appears to offer the field
investigator a convenient preliminary screening tool for water pollution
surveys, but may yield data as much as 10-fold lower than that obtained
by the fecal coliform multiple tube procedure.
Evaluating Water Bacteriology Laboratories/Geldreich
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These modifications of the MF test (field monitor and dip-stick) are not
acceptable as a substitute for the Standard Methods procedures because
of inadequate sensitivity for recovering 85 percent or more of the coliform
population or because the test inability to measure coliforms at levels
below 1000 per 100 ml of sample (10 per ml). Such tests may be useful in
obtaining a quick preliminary estimate of water quality, but where the
data are to be used for an enforcement action or submitted as evidence in a
court of law, Standard Methods MF procedures or other proven methods
acceptable to court must be employed.
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SUPPLEMENTARY BACTERIOLOGICAL METHODS 151
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36. Class, O., and Diagranes, A. Rapid Identification of Prompt Lactose-fermenting Gen-
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37. Clark, H. F., Geldreich, E. E., Jeter, H. L., and Kabler, P. W. The Membrane Filterin
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38. Canllas, L. Guam Environmental Protection Agency, Personal Communication (Feb.
5, 1975), Agana, Guam 96910.
39. Spino, D. F. Elevated-temperature Technique for the Isolation of Salmonella from
Streams. Appl. Microbiol. 14:591-596 (1966).
40. Cherry, W. B., Hanks, J. B., Thomason, B. M., Murlin, A. M., Biddle, J. W., and
Croom, J. M. Salmonellae as an Index of Pollution of Surface Waters. Appl. Microbiol.
24:334-340 (1972).
41. Wun, C. K., Cohen, J. R., and Litsky, W. Evaluation of Plating Media and Temperature
Parameters in the Isolation of Selected Enteric Pathogens. Health Lab. Sci. 9:225-232
(1972).
42. Peterson, M. L., and Klee, A. J. Studies on the Detection of Salmonellae in Municipal
Solid Waste and Incinerator Residue. Internal. Jour. Environ. Studies 2:125-132 (1971).
43. Brezenski, F. T. Estuary Waler Quality and Salmonella. Proc. National Specially
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(1971).
44. Brezenski, F. T. Unpublished laboratory procedures, Edison Waler Qualily Laborato-
ry, U.S. Environmental Protection Agency, Edison, New Jersey 08817.
45. Smith, P. D., Tomfohrde, K. M., Rhoden, D. L., and Balows, A. API System: A
Mullilube Micromelhod for Idenlificalion of Enterobacteriaceae. Appl. Microbiol.
24:449-452 (1972).
46. Painter, B. G., and Isenberg, H. D. Clinical Laboratory Experience with Ihe Improved
Enlerotube. Appl. Microbiol. 25:896-899 (1973).
47. Shimmin, K. G. Unpublished laboratory procedures Region IX Laboratory, U. S.
Environmental Protection Agency, Alameda, Calif. 94501
48. Crawford, R. P., Heinemann, J. M., McCulloch, W. F., and Diesch, S. L. Human
infections Associated with Waterborne Leplospires, and Survival Studies on Serolype
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Sk A™"^engvS'^AW-,5 aSd Steele> J- H- Epidemiological Palterns of Lepto-
spirosis. Ann. New York Acad. Sci. 70:427-444 (1958).
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50. Johnson, R. C., and Harris, V. G. Differentiation of Pathogenic and Saprophytic
Leptospires. I. Growth at Low Temperatures. Jour. Bacteriol. 94:27-31 (1967).
51. Okazaki, W., And Ringen, L. M. Some Effects of Various Environmental Conditions
on the Survival of Leptospira pomona. Amer. Jour. Vet. Res. 18:219-223 (1957).
52 Ryu, E., and Liu, C. K. The Viability of Leptospires in the Summer Paddy Water. Japan
Jour. Microbiol. 10:51-57 (1966).
53. Diesch, S. L., McCulloch, W. F., Braun, J. L., and Crawford, R. P. Jr. Environmental
Studies on the Survival of Leptospires in a Farm Creek Following a Human Lepto-
spirosis Outbreak in Iowa. Proc. Ann.Conf. Bull. Wildlife Dis. Assoc. 5:166-173(1969).
54 Chang, S. L., Buckingham, M., and Taylor, M. P. Studies of Leptospira icterohemmor-
' rhagiae. IV. Survival in Water and Sewage: Destruction in Water by Halogen Com-
pounds, Synthetic Detergents, and Heat. Jour. Infect. Dis. 82:256-266 (1948).
55 Johnson, R. C., and Rogers, P. Differentiation of Pathogenic and Saprophytic Lepto-
spires with 8-Azaguanine. Jour. Bacteriol. 88:1618-1623 (1964).
56 Fuzi M., and Csoka, R. Differentiation of Pathogenic and Saprophytic Leptospire by
Means of a Copper Sulfate Test. Zentr. Bakt. Para. Inf. Orig. Abt. I. 179:231-237
(1960).
57. Crawford, R. P., Braun, J. L., McCulloch, W. F., and Diesch, S. L. Characterization of
Leptospires Isolated from Surface Waters in Iowa. Bull. Wildlife Dis. Assoc. 5:157-165
(1969).
58 Braun, J. L., Diesch, S. L., and McCulloch, W. F. A Method for Isolating Leptospires
from Natural Surface Waters. Can. Jour. Microbiol. 14:1011-1012 (1968).
59. Turner, L. H. Leptospirosis. III. Maintenance Isolation and Demonstration of Lep-
tospires. Trans. Royal Soc. Trop. Med. and Hyg. 64:623-646 (1970).
60. Baseman, J. B., Henneberry, R. C., and Cox, C. D. Isolation and Growth of Leptospira
on Artificial Media. Jour.' Bicteriol. 91:1374-1375 (1966).
61. EUinghausen, H. C. Jr., and McCulloch, W. F. Nutrition of Leptospira pomona and
Growth of 13 other Serotypes: Fractionation of Oleic Albumin Complex and a Medium
of Bovine Albumin and Polysorbate 80. Amer. Jour. Vet. Res. 26:45-51 (1965).
62. Tripathy, D. N., and Hanson, L. E. Agar Overlay Medium for Growth of Leptospires in
Solid Medium. Amer. Jour. Vet. Res. 32:1123-1127 (1971).
63. Fuzi, M., and Csoka, R. Rapid Method for the Differentiation of Parasitic and Sap-
rophytic Leptospire. Jour. Bacteriol. 81:1008 (1961).
64. Fuzi, M., and Csoka, R. An Egg-Yolk Reaction Test for the Differentiation of Leptospi-
ra. Jour. Pathol. Bacteriol. 82:208-211 (1961).
65. Kmety, E., Okesji, I., Bakass, P., and Chorvath, B. Evaluation of Methods for Dif-
ferentiating Pathogenic and Saprophytic Leptospira Strains. Ann. Soc. Beige. Med.
Trop. 46:111-118 (1966).
66. Glantz, P. J., and Jacks, T. M. An Evaluation of the Use ofEscherichia coli Serogroups
as a Means of Tracing Microbial Pollution of Water. Water Resources Res. 4:625-638
(1968).
67. Bissonnette, G. K., Stuart, D. G., Goodrich, T. D., and Walter, W. G. Preliminary
Studies of Serological Types of Enterobacteria Occurring in a Closed Mountain
Watershed. Proc. Montana Acad. Sci. 30:66-76 (1970).
68. Edwards, P. R., and Ewing, W. H. Identification of Enterobacteriaceae, 2nd ed.
Burgess Publishing Co., Minneapolis, Minn. (1962).
69. Geldreich, E. E., Kabler, P. W., Jeter, H. L., and Clark, H. F. A Delayed Incubation
Membrane Filter Test for Coliform Bacteria in Water. Amer. Jour. Pub. Health
45:1462-1474 (1955).
70. McCarthy, J. A., and Delaney, J. E. Methods for Measuring the Coliform Content of
Water. Sect. III. Delayed Holding Procedure for Coliform Bacteria. PHS Research
Grant WP 00202. Nad. Inst. of Health, Bethesda, Md. (1965).
71. Brezenski, F. T., and Winter, J. A. Use of the Delayed Incubation Membrane Filter
Test for Determining Coliform Bacteria in Sea Water. Water Res. 3:583-592 (1969).
72. Panezai, A. K., Macklin, T. J. and Coles, H. G. Coli-aerogenes and Escherichia coli
Counts on Water Samples by Means of Transported Membranes. Soc. Water Treat and
Exam. 14:179-186(1965).
73. Taylor, R. H., Bordner, R. H., and Scarpino, P. V. A Delayed Incubation Membrane
Filter Test for Fecal Coliforms. Appl. Microbiol. 25:363-368 (1973).
74. Levin,G. V., Harrison, V. R., Hess, W. C., andGurney, H. C. ARadioisotopeTechnic
for the Rapid Detection of Coliform Organisms. Amer. Jour. Pub. Health 46:1405-1414
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Bacteria in Water. Amer. Jour. Pub. Health 54:827-833 (1964).
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Fluorescent Antibody Technique. I. A Methodological Study. Acta Pathol Mi-
crobiol. Scand. 63:597-603 (1965).
SUPPLEMENTARY BACTERIOLOGICAL METHODS 1S3
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77. Ginsburg, W., Crawford, B., and Knipper, J. J. Filter-fluorescent Antibody Technique
for Rapid Screening of Indicator Organisms. Jour. Amer. Water Works Assoc. 64:499-
505 (1972).
78. Van Donsel, D. J., Twedt, R. M., and Geldreich, E. E. Optimum Temperature for
Quantitation of Fecal Coliforms in 7 Hours on the Membrane Filter. Bacteriol. Proc.
Amer. Soc. Microbiol. p. 25 (1969).
79. Geldreich, E. E., Blannon, J., Reasoner, D. J. A Rapid (7-Hour) Membrane Filter Fecal
Coliform Test for Monitoring Recreational Waters and Water Supplies During
Emergencies (in preparation).
154
Evaluating Water Bacteriology Laboratories/Geldreich
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GUIDELINES ON SUPPLEMENTARY
BACTERIOLOGICAL METHODS
Standard Plate Count
Sample bottles sterilized within 30 days
Sample transit time limited to 8 hours without cooling, or 30 hours if iced;
sample shipping containers used
Sample shaken vigorously at moment of plating
Sample portions plated in triplicate
Not more than 1 nor less than 0.1 ml plated (sample or dilution)
Ten milliliters or more liquefied agar medium added at a temperature
between 44° and 46°C
Melted medium stored for not more than 3 hours before use
Plates for potable waters and swimming pools incubated for 48 hours at 35°C
Plates for bottled waters incubated for 72 hours at 35°C
Only plates with between 30 and 300 colonies counted, except 1-ml sample
with less than 30 colonies
Only two significant figures recorded and calculated as standard
plate count per 1 ml
Slaphylococcus
Total Staphylococcus count determined on (specify type of agar)
Staphylococcus aureus density determined by coagulase test
Pseudomonas aeruginosa
MF cultures incubated on M-PA at 41,5°C for 48 hours
Colonies verified by Brown — Scott Foster milk agar streak plates
MPN procedure employed using asparagine broth in the presumptive test
Greenish fluorescence confirmed in acetamide medium
Fecal Streptococci
Choice of procedures: multiple tube ; MF ; pour plate.
Media choice
Biochemical reactions: growth at 45° and 10°C, 40 percent bile, catalase
reaction, and starch hydrolysis .
Klebsiella
Primary isolations as coliforms on Endo-type medium .
Biochemical tests: HOMoC series; lactose; oxidase . ..
Salmonella
Qualitative procedures:
Concentration method
Enrichment medium
Enrichment incubation time ; temperature.
Choice of plating media
Quantitative procedure:
Salmonella typhosa quantitated using MF procedure and
M-bismuth sulfite broth
Preliminary Salmonella Screening
FA technique:
Light saline suspension of a 18- to 24-hour pure culture, then air dried
Kirkpatrick's fixative used; rinsed in 95 percent ethanol
Salmonella polyvalent OH conjugate, diluted 1:8
SUPPLEMENTARY BACTERIOLOGICAL METHODS 155
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After 30 minutes in moist chamber, excess reagent washed
off in buffered saline
Washed in a second bath of buffered saline for 10 minutes
Placed small drop of mounting fluid on smear and covered
with No. 1 coverslip
Examined under fluorescence scope using UG-1 primary filter
and GG-9 ocular filter
Biochemical reactions included triple sugar iron agar, indole, motility,
urease, lysine decarboxylase, plus others to differentiate strains
encountered
Serological Grouping of Salmonella
An 18- to 24-hour pure culture, grown in brain heart infusion, used ...
Glass slide subdivided into four squares using a thick wax pencil
Square #1 contained Salmonella "O" polyvalent antiserum
Square #2 contained antiserum plus 0.85 percent sodium chloride ....
Square #3 contained bacterial suspension in saline
Square #4 contained bacterial suspension in saline plus
antiserum (test square)
Checked within 3 minutes for positive agglutination in all squares ....
If agglutination occurred in Square #4 only (test square), procedure
repeated using specific antisera for serotype identity
Pathogenic Leptospires
Preliminary concentration:
Water samples collected from near-shore bottom sediments
Turbid sample shaken vigorously, then prefiltered through paper filter
Prefiltered sample then passed through 0.45-/im MF and filtrate
tested for leptospire occurrences
Cultivation:
Medium incubation time at 30°C
Growth verified by darkfield microscopy
Differentiated from saprophytic leptospires
Pathogenic strains serologically identified
Pathogenicity verified by animal testing
Enteropathogenic Escherichia coli
Primary isolations made on M-FC at 44.5°C or Endo-type medium at 35°C
Colonies purified and identified by biochemical procedures
Serotypes determined by slide agglutination reactions
Serotypes confirmed by the macroscopic tube test for "0" antigen reaction
Delayed Incubation Procedures
Total Coliforms:
After filtration, MF placed over pad of M-Endo containing 3.2 ml of 12
percent sodium benzoate solution per 100 ml of medium
Fifty milligrams of cycloheximide added per 100 ml of holding
medium for fungus suppression
Culture transported by mail service to laboratory within 72 hours ....
MF cultures transferred to standard M-Endo medium at laboratory ...
Incubated at 35°C ± 0.5°C for 20 to 22 hours
If growth visible at time of transfer, held in refrigerator until end of
work day then incubated at 35°C overnight
(16- to 18-hour period)
Sheen colonies counted, verified if necessary, and total coliform
density per 100 ml calculated
Evaluating Water Bacteriology LaboratoriesIGeldreich
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Fecal Coliforms:
After filtration, MF placed over pad of VFC broth
Cultures transported by mail service to laboratory within 72 hours
MF cultures transferred to M-FC broth at laboratory
Cultures placed in waterproof plastic bags and incubated in 44.5°C
water bath for 22 ± 2 hours
Blue colonies counted, verified if necessary, and fecal coliform
density per 100 ml calculated
Rapid Methods
M-7-hour broth and MF procedure used; incubated at 4I.5°C
for fecal coliform detection
All yellow colonies counted, verified if necessary, and fecal coliform
density per 100 ml calculated
Portable Field Laboratory
Standard laboratory MF procedures adapted to field application .
Ampouled M-Endo shelf life limited to 18 months
Ampouled M-FC shelf life limited to 6 months
SUPPLEMENTARY BACTERIOLOGICAL METHODS 157
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CHAPTER X
LABORATORY MANAGEMENT
Laboratory involvement in developing the support data used for
monitoring water quality has paralleled the increased concern over en-
vironmental pollution. Bacteriological services offered by the water
laboratory, in addition to the traditional examination of potable waters,
may also include gathering stream pollution data, monitoring fresh and
saline recreational water qualities, checking the quality of shellfish grow-
ing waters, and evaluating effluent qualities from a variety of water users.
The extent of these examinations will be governed by staff size, experi-
ence and training, and laboratory space and the availability of specialized
equipment and safety provisions for handling waterborne pathogen inves-
tigations.
LABORATORY RECORDS
State health and environmental laboratories and municipal water plant
laboratories examine approximately 3.5 million samples annually from
this Nation's public and private water supplies. Frequency of unsatisfac-
tory samples reported from public supplies, serving some 180 million
individuals, varies from state to state but most often ranges from 3 to 5
percent. By contrast, about 40 to 60 percent of all private domestic water
supplies, serving approximately 33 million consumers, fail to meet the
Federal Drinking Water Standards. Available national data indicate that
the MF procedure is being used by 72 state and branch laboratories and by
over 125 municipal laboratories. MF applications range from use on only
stream pollution samples to the analysis of all public and private potable
waters.
Inspection of laboratory records on the bacteriological examination of
public water supplies occasionally uncovers evidence of insufficient data
retention, filing backlogs, and poor data retrieval. Compilations of data
on water samples examined during the year should include a breakdown
on the total number of samples for each of the following waters: public,
private, swimming pool, natural bathing, and stream. Records from some
laboratories using the MPN test must be divided by 5 because total
examinations have been padded by counting five tubes per test as five
examinations.
A study of the available engineering division's records for municipal
supplies may indicate that only a minimum of the information available
from the laboratory water sample report is being retained. Thus, inspec-
tion of laboratory water sample reports are, in general, more meaningful
in evaluating the scope of the surveillance program. In one engineering
record system, only the total number of positive tubes and the total
number of presumptive tubes inoculated per month were recorded. This
LABORATORY MANAGEMENT 159
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made it impossible to reconstruct the MPN value for any given unsatisfac-
tory sample or samples during the month, and the attempt to analyze
these records for evidence of a repeat sampling requirement based on
specific instances of unsatisfactory sample results was inconclusive.
Data submitted on water-stained report sheets must not be arbitrarily
selected for use in monthly reports on public water supply monitoring
only when results are satisfactory and be rejected when the laboratory
findings are unsatisfactory. Any hypothesis that water-stained reports
means the samples did leak in transit and become contaminated is difficult
to substantiate by facts. The more logical explanation for water-stained
reports is found in the common occurrence of wetness on the outside of
the bottle acquired during sample collection. These water droplets then
stain the laboratory report form, which often is wrapped around the
bottle, then inserted into the mailing tube or sample case. Upon arrival in
the laboratory, any received samples found to leak either from improper
screw cap closure, defective cap liners, or cracked bottles should be
rejected and the report marked with an explanation for rejection. Another
sample must be immediately requested for analysis. Any further rejection
of some laboratory reports based on water-stained sample sheets should
be discontinued as purely speculative.
LABORATORY REPORTS
Reports on the examination of potable water samples may be prepared
by the laboratory division personnel or, exclusively, by the division of
engineering clerical staff. Uniformity in state record systems is rare.
Report forms vary in complexity from a minimum of information on the
specific sample to a detailed sanitary evaluation of the supply. The
bacteriological water-sample report form for potable water must include
information that identifies sample location, time and date of collection,
sample collector's initials, time of receipt in the laboratory, and total
coliform occurrence per 100 ml. Additional essential information spaces
should be available for reporting chlorine residual, turbidity, standard
plate count (48 hours at 35°C) per 1 ml, and a check box that states the
sample does or does not conform to the Federal Drinking Water Stand-
ards. Finally, the form should also include a check spot to specify if the
water sample is routine (part of the normal monitoring program), a re-
cl^eck sample (repeat sample requested when potable water results are
unsatisfactory), or a special sample. This latter information would be of
assistance to the laboratory in processing samples and to the engineering
section in separating repeat sample information from routine sampling
data. The form sizes vary from quarter-page, half-page, and full-page, to
cards used in IBM systems. Copies may be prepared with carbon, with
forms where no carbon is required, or by various office copier machines.
Reports may be kept 1,3, or 5 years or on a perpetual basis with long-term
storage on microfilm or in storage boxes located in state archives. In
general, retrieval of records beyond 2 years is frequently difficult because
of the location of inactive file storage areas.
Current files of reports on public water supplies may be indexed by
individual municipal supplies, by county or regional area, or by month. In
several states, the individual records for municipal supplies are scattered
160 Evaluating Water Bacteriology Laboratories/Geldreich
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over the state in the files of branch laboratories assigned the responsibility
for examining the municipal water supplies in their geographical area.
PERSONNEL
The size of the laboratory staff required for a given volume of bac-
teriological examinations may be difficult to predict because of such
factors as demands due to other laboratory program needs, availability of
laboratory support personnel, and personnel involvement with laborato-
ry administration and clerical duties. An analysis of 1965 to 1970 data on
laboratory staffing indicates that 89.0 percent of the central state
laboratories had only one to four technicians; 89.3 percent of municipal
laboratories employed one to three technicians; and 92.6 percent of
private laboratories had only one or two technicians involved in water
analysis on a part-time basis. For the number of samples that could be
analyzed per technician, data from 10 state laboratories employing the
MFprocedure was used to estimate an average of 5,400 samples per year.
This estimate is about 10 percent higher than the 4,900 samples per year
examined, on the average, by technicians using the MPN procedure in 36
other state and branch laboratories. A greater difference in workload
would be evident if the numerous related duties (milk and food analyses,
record keeping, etc.) common to these state health department
laboratories were not involved.
Ideally, the professional staff should include a senior bacteriologist
with a major in bacteriology from a recognized college and a MS (or MA)
degree or equivalent experience in water bacteriology. As an assistant to
the unit chief, the second staff member should have graduated from a
recognized college with a major in bacteriology-biology or have equiva-
lent practical experience in water bacteriology. Such employees can
carry out or supervise routine test procedures, training activities, consul-
tations on methods and problems, and evaluations of new or routine
procedures as needed. Because of the greater number of samples col-
lected during the summer months, qualified temporary help, to work
under the direct supervision of the bacteriologists, may be added as
required.
Laboratory support personnel, i.e. scientific aids, are also needed to
clean glassware and prepare sterile media, sample bottles, and other
materials. The specific number of scientific aids required is determined by
demands for their services from other laboratory program needs, the
volume of disposable plastic items used, the number of water examina-
tions conducted, and the choice and variety of tests performed. Our study
of man-power requirements in 18 state laboratories during the period 1965
to 1970 showed that for each staff bacteriologist in the water laboratory,
the full-time support of 1.4 scientific aids, assigned to the preparation
unit, was needed. In terms of the total number of samples examined each
year, these same laboratories required back-up services of one scientific
aid for every 6,900 water samples examined per year.
The laboratory staff must also have clerical support to type, file, and
distribute copies of reports to the laboratory director, sanitary engineer-
ing section, water companies, and private individuals. Laboratory ac-
tivities also require such additional services as handling telephone mes-
LABORATORY MANAGEMENT 161
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sages, preparing correspondence, requisitioning supplies, and compiling
semi-annual or annual summaries of laboratory activities. In large
laboratory operations, these activities generally require the services of
two full-time clerk-typists; in the small municipal laboratory, one clerk-
typist should be sufficient.
REFERENCE MATERIAL
A copy of the current edition of Standard Methods must be available in
the laboratory for immediate use when some aspect of methodology must
be reviewed, since this essential reference undergoes substantial revision
with each new edition. Some state laboratory systems have prepared
excellent methods manuals for distribution to laboratories within their
states. These manuals serve as a guide to proper sampling techniques, and
provide protocol on sample transit-time restrictions, the use of report
forms, laboratory procedures, and data interpretation. This technical
information is useful to sanitarians and laboratory personnel in city and
county health departments, water works personnel, and institutions in-
volved in the bacteriological examination of water. Concerted effort
should be made to periodically up-date these manuals and to circulate
them throughout the state to all laboratories. In addition, such references
as the EPA manual on microbiological procedures (see reference 36, page
121) on approved protocols and the EPA student training manual (EPA-
430/1-74-008, available from NTIS) employed for analysis of municipal
effluents should be available and used.
A newsletter, initiated from the office of the state laboratory director on
a quarterly basis, can be useful for keeping regional laboratory personnel
informed of significant activities related to the mission responsibilities of
the laboratory system. The newsletter could also include comments on
operating and maintaining laboratory equipment, plus evaluation reports
on equipment items for specific laboratory needs that might be purchased
in the future.
Reference books that are recommended, but not mandatory, include
recent editions of college textbooks on bacteriology, chemistry, statis-
tics, the Merk Index, and commercial application manuals on dehydrated
media and testing procedures. Other suggested references, which should
be available in the laboratory, include current editions of training manuals
acquired through staff participation in state-of-the-art laboratory courses
given by the state health department or environmental agency or other
specialized courses given by universities. Federal agencies, and commer-
cial interests sponsoring workshops and seminars. Since the science of
water bacteriology, chemistry, biology, and sanitary engineering is pro-
gressing at a rapid pace, it is essential that professional personnel be given
the opportunity to obtain short-term specialized training in new concepts,
instrumentation, and methodology.
Several laboratory groups can establish a policy of cooperative sharing
of scientific periodicals obtained through personal memberships in vari-
ous scientific societies. By circulating current journal issues among the
staff or by alerting staff members to articles that relate to their specialties,
the entire work group can be informed on new research findings. Among
the scientific journals that frequently contain articles on water bacteriol-
162 Evaluating Water Bacteriology LaboratorieslGeldreich
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ogy are Journal of the Water Pollution Control Federation; Applied
Microbiology; Health Laboratory Science; Journal of the American
Water Works Association; and Water Research: The International Jour-
nal on Water Pollution Research.
LABORATORY FACILITIES
Laboratory space must be adequate to accommodate periods of peak
work load. Working space requirements must include sufficient bench-
top area for processing samples; storage space for media, glassware, and
portable equipment items; floor space for stationary equipment (in-
cubators, water baths, refrigerators, etc.); and an adequate associated area
for cleaning glassware and sterilizing materials. The bench-top working
area needed for processing samples has been estimated to approximate 4
to 6 linear feet of continuous area per technician. This figure is a practical
estimate derived from space requirements observed in various
laboratories performing routine analyses. Where more specialized bac-
teriological examination of water is required, or in laboratories involved
in bacteriological research, this space requirement may be inadequate.
The space required for both laboratory work and materials preparation
in small water plant laboratories may be consolidated into one room, with
the various functions allocated to different sections of the room. In larger
water plants, county health department laboratories, and in state and
Federal laboratories, the laboratory working area and supporting func-
tions should be in separate rooms but located on the same floor and in
proximity to each other. For laboratories engaged in various
disciplines—i.e., water, milk, food—work space must be increased pro-
portionally so that water and other samples may be processed as neces-
sary throughout the day without the need to program limited work space
and time for one or the other type of sample examination. Where laborat-
ory facilities are limited, the quality of work and the reliability of data may
be impaired.
Where possible, media preparation, glassware processing, and sterili-
zation of materials for different laboratory groups in multi-function
laboratories should be consolidated. Combining these services results in
more economic operation, more efficient use of manpower assigned to
these duties, and less duplication of equipment needed for such services
(e.g., autoclaves, hot-air sterilizers, automatic glassware washers, au-
tomatic pipetting machines, pH meters, balances).
The laboratory should be located in a clean, well-lighted, well-
ventilated room (preferably air conditioned) that is reasonably free of dust
and draft and not subject to excessive temperature changes. A light
intensity of 60 to 100 foot candles is recommended at all working surfaces
(1). A bench height of 36 inches provides knee space and convenience for
the technician who may choose to stand or sit while performing various
tasks. Laboratory benches, 30 inches high should also be provided for use
in counting pour plates and MF cultures, in scanning Gram stains, and in
recording data on laboratory work sheets. Laboratory table or bench-top
working areas should be level to avoid uneven colony distribution over
pour plates or over the effective filtration area of MF's. A laboratory sink
LABORATORY MANAGEMENT 163
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is essential for the disposal of discarded samples, surplus media, or
sample filtrates derived from MF procedures.
Ample cabinets, drawers, and/or shelves should be available in the
laboratory for storage and protection of glassware, small laboratory
equipment, and other materials, especially when sterilized items are
stored for any length of time. The storage area for dehydrated media
should not be located near the glassware working area because summer
temperatures and humidity may cause deterioration of dehydrated media
supplies.
LABORATORY SAFETY
Laboratory safety, which must be an integral and conscious effort in
everyday laboratory operations, should provide safeguards to correct
facility deficiencies and equipment failures, avoid electric shock, prevent
fire, prevent accidental chemical spills, minimize microbiological dan-
gers, and minimize radiation exposures (2-7). Laboratories now are under
the Occupational Safety and Health Act or state equivalent safety and
health program. Free consultation and advising services from these
groups are usually available for safety programs.
Room space must be adequate to avoid storing equipment and supplies
along traffic areas that must be accessible to carts, portable equipment,
and free movement of technicians. The floors of the laboratory should be
clean, dry, and free from projections that might trip personnel or jam cart
passage. When floor wax is required, a nonskid wax should be chosen.
Protective maintenance of autoclaves requires periodic inspections by
a representative of the manufacturer (see section on Autoclaves in Chap-
ter III). Operating instructions for autoclaves and stills should be posted
nearby, particularly if such equipment may be used by inexperienced
personnel or on weekends or holidays when those routinely responsible
for operation are away.
Electrical service in the laboratory should conform with local, state, or
national electrical codes (8). Service feeders must be of adequate size as
specified by the applicable electric code and be properly protected from
overload by either automatic circuit breakers or fuses. All electrical
outlets should be properly grounded using a three-wire ground system. In
addition to providing equipment grounds, the three-prong plug orients
connections to the electrical wiring so that the hot and neutral side of the
equipment circuit always remain at the same potential. In the absence of
the three-wire ground system, a separate ground wire, size No. 14 or 16
gauge, must be connected from laboratory equipment to a cold water pipe
as a protection from electrical shock. Open wiring should not be used in
the laboratory.
All laboratories should have access to both foam and carbon dioxide
type fire extinguishers. Foam extinguishers are effective on small fires in
ordinary combustible materials and in small quantitites of flammable
liquids or grease. Carbon dioxide fire extinguishers must be used where
electrical equipment fires occur. These fire extinguishers must be period-
ically inspected and replaced as necessary. Fire extinguishers should be
located either in the laboratory or in a corridor so that a person need not
travel more than 50 feet from any point to reach the nearest extinguisher.
164 Evaluating Water Bacteriology LaboratoriesIGeldreich
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Other equipment that should be available in case of fire or chemical
accidents includes gas masks, fire blankets, and emergency shower sta-
tions. Fire exits from the laboratory must remain clear at all times and not
become cluttered with equipment, boxes, or cartons of supplies.
Although the hazards from handling and storing chemicals in the bac-
teriological laboratory may not be of the magnitude found in the chemis-
try laboratory, bacteriologists and other laboratory personnel are often
unaware of the basic safety rules that must be followed. All chemical
containers must be clearly labeled; any materials in unlabeled containers
should be carefully discarded. After a reagent has been used, any residual
material adhering to the outside of the bottle should be wiped or rinsed off
to prevent contact with the hands during future handlings. Flammable
solvents should be stored either in an approved solvent storage cabinet or
in a well-ventilated area. Avoid storing solvents above eye level in the
work area, near open flames, or in refrigerators or cold rooms that also are
used to store stock cultures and media. Fumes from leaking containers of
organic solvents are often toxic to bacteria. Oxidizing materials such as
nitrates and chlorates should be stored in a dry area separate from organic
material. When it is necessary to open bottles that may be under pressure
(hydrochloric acid or ammonium hydroxide), cover the bottle with a
towel to intercept any chemical spray. Bottle carriers should be used
when transporting glass bottles containing hazardous chemicals (acids,
corrosives, or flammable liquids).
Compressed gas cylinders should be stored and transported with the
shipping cap on. Use a wheeled cart to transport large cylinders, and be
certain the cylinders are secured at all times. Gas cylinders should be
stored and used in an upright position, being fastened securely and well
away from any heat source. Before use, double check the identity of the
gas cylinder to be certain it is the kind required for the experiment, and
always use a reducing valve or preset pressure controller on the cylinder
outlet. Do not force connections or use some improvised adaptors.
The microbial agents that might be of potential hazard in the water
laboratory are those that could produce disease of varying degrees of
severity (as the result of accidental inoculation or injection or other means
of cutaneous penetration) but that should be contained by ordinary
laboratory techniques (9). Basic dangers associated with microbiological
hazards in the laboratory involve (a) hand-mouth contact while handling
contaminated laboratory materials and (b) aerosols created by pipetting,
centrifuging, or blending samples or cultures and those created by use of
inoculating loops (10).
Aerosols can be created by blowing out the last drop from pipettes. Do
not mix dilutions by blowing air through a pipet into the culture. When
working with grossly polluted water samples, such as sewage or high-
density bacterial emulsions, the use of cotton plugs in the mouth end or a
rubber bulb attached to the mouth end of the pipet is recommended to
prevent the accidental ingestion of sample material. Since untreated
waters may contain waterborne pathogens, it is essential that all used
pipets be discarded into ajar containing a disinfectant solution for decon-
tamination before these items are returned to personnel responsible for
glassware washing. The habit of placing discarded pipets on table tops,
LABORATORY MANAGEMENT 165
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laboratory carts, or in sinks without adequate decontamination presents
an unnecessary health risk to the laboratory personnel. Quaternary am-
monium compounds that include a compatible detergent and solutions of
sodium hypochlorites are satisfactory disinfectants for pipet discard jars.
The highest concentrations recommended for these commercial products
should be used provided this concentration does not cause a loss of
markings or fogging of glass pipets. Disinfectant solutions in the discard
container should be replaced each morning to ensure maximum disinfec-
tion action. Contaminated materials (cultures, samples, used glassware,
sereological discards, etc.) must be sterilized by autoclaving before being
thrown away or being processed for reuse.
Shattering of culture-containing tubes during centrifugation liberates
voluminous quantities of bacterial aerosol in the laboratory (11, 12).
Blenders must be leak-proof and tightly covered during operation to
prevent creating an aerosol spray that might contaminate technicians
stationed some distance away. An investigation of various inoculating
loop techniques showed that inserting a hot loop into a flask of broth
culture created the greatest hazard in terms of aerosolized bacteria (13).
The use of electric heater incineration for sterilizing inoculating loops or
needles may be a desirable procedure, but observe caution to avoid a
possible electrical shock that could occur if the person holding the loop
touches the inside of the heater core while also being grounded (14).
Good personal hygienic practices are important in the control of con-
tact exposures. Frequent disinfection of hands and working surfaces is
essential. Smoking, eating, or taking coffee breaks at the work bench
should be avoided. Drinking water should be available outside the
laboratory, preferably from a foot-operated drinking fountain. The
laboratory staff should also be immunized against tetanus and possibly
typhoid or other infectious agents that might be under investigation.
Flies and other insect occurrences must be minimized in the laboratory
to prevent contamination of sterile equipment, media, samples, and
bacterial cultures in addition to the obvious desire to prevent any spread
of infectious organisms to the personnel via this vehicle. Control meas-
ures must include restriction on food storage in desks and storage
cabinets, installation of screens in all windows and outer doors for those
laboratories without air-conditioning, and a program of periodic spraying
of insecticide along toe-stripping, sink and storage cabinet areas, and
utility service channels. Since some laboratories also include a chemistry
section that analyzes waters for pesticides, application of insecticides to
suppress insect occurrences must be carefully restricted to the immediate
areas of the bacteriological laboratory section.
In those laboratories where radioactive chemicals for tracer studies and
rapid bacterial detection systems are used, personnel should carry film
badges or pocket radiation dosimeters for monitoring individual expo-
sure. Records should be kept of yearly total exposure for each individual
staff member. Work areas where radioactive materials are used should be
monitored once a week and these readings logged also. Area monitoring
should be conducted using a survey instrument (a Geiger-Miiller or ioni-
zation chamber type) capable of detecting 0.01 milliroentgen per hour,
with a maximum of 0.5 milliroentgen per hour at full-scale detection on
166
Evaluating Water Bacteriology LaboratoriesIGeldreich
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the lowest setting. Using disposable laboratory items will eliminate many
washing problems. Radioactive-contaminated disposable items can be
placed in special waste containers, which, when full, can be disposed of
by the radiation safety officer. Nondisposable lab-ware contaminated by
radioactivity should be held apart from other lab-ware items for suitable
cleanup procedures. Where C14-labeled compounds are used, liquid
wastes may safely be released into the sanitary sewer provided the
quantity released does not exceed an average concentration of 0.02 mi-
crocuries per liter. Other radioactive liquid wastes may also be disposed
of via the sanitary sewer subject to concentration limits established under
Federal regulations (15). Protective plastic or rubber gloves should be
worn whenever handling radioactive liquids as a protection for skin cuts
or hangnails. When hands are contaminated, they should be thoroughly
washed (2 to 3 minutes) in warm water using mild soap or detergent. In no
case should abrasive and/or alkaline soap be used. Washing should be
repeated several times with the exposed skin area monitored for radioac-
tivity until the hands are decontaminated.
Finally, every laboratory should have a copy of a manual on laboratory
safety and a laboratory emergency treatment chart for guidelines in
first-aid treatment of accident victims. First aid supplies should be
checked frequently to replace out-of-stock items or items that have limit-
ed shelf life.
REFERENCES
1. Division of Hospital Facilities (Public Health Service, Federal Security Agency) et a).
State Public Health Laboratory. Amer. Jour. Pub. Health 40:48-62 (1950).
2. Wedeun, A. G., Hanel, E., Phillips, G. B., and Miller, O. T. Laboratory Design for
Study of Infectious Disease. Amer. Jour. Pub. Health 46:1102-1113 (1956).
3. Steere, N. W., Ed. Handbook of Laboratory Safety. Chemical Rubber Company,
Cleveland, Ohio (1967).
4. Manufacturing Chemists Association. Guide to Safety in the Chemical Laboratory. Van
Nostrand Co., Inc., New York (1954).
5. Darlow, H. M. Safety in the Microbiological Laboratory. In: Methods in Microbiology.
Vol. 1. J. R. Morris and D. W. Ribbons, Eds. Academic Press, New York, p. 169-204
(1969).
6. National Bureau of Standards. Control and Removal of Radioactive Contamination in
Laboratories. Handbook No. 48. (Available as National Council on Radiation Protec-
tion Report 8, Washington, D.C. 20014) (1951).
7. Science Products Division, Mallinckrodt Chemical Works. Laboratory Safety Hand-
book. Mallinckrodt Chem. Works, St. Louis, Mo. 60 p. (1969).
8. National Electrical Code 1968: A U.S.A. Standard. National Fire Protection Assoc
Boston, Mass. 466 p. (1968).
9. Office of Biosafety. Classification of Etiologic Agents on the Basis of Hazard. 4th ed. 13
p. Center for Disease Control, Atlanta, Ga. (July 1974).
10. Phillips, G. B., Microbiological Safety in U.S. and Foreign Laboratories. Technical
Study 35. Biological Laboratories Project 4B11-05-015. U.S. Army Chemical Corps
Fort Detrick, Md. 291 p. (Sept. 1961).
11. Reitman, M., and Phillips, G. B. Biological Hazards of Common Laboratory Proce-
dures. III. The Centrifuge. Amer. Jour. Med. Technol. 22:100-110 (1956).
12. Hall, C. V. A Biological Safety Centrifuge. Health Lab. Sci. 12:104-106 (1975).
13. Phillips, G. B., and Reitman, M. Biological Hazards of Common Laboratory Proce-
dures. IV. The Inoculating Loop. Amer. Jour. Med. Technol. 22:16-17 (1956).
14. Gordon, R. C., and Davenport, C. V. Simple Modification to Improve Usefulness of the
Bacti-cinerator. Appl. Microbiol. 26:423 (1973).
15. U.S. Code of Federal Regulations. Title 10, Section 20.303. p. 166. U.S. Government
Printing Office, Washington, D.C. (1974).
LABORATORY MANAGEMENT 157
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GUIDELINES ON LABORATORY MANAGEMENT
Laboratory Records
Results assembled and available for inspection -
Data processed rapidly through laboratory and engineering sections .
Adequate data retention, efficient filing system, and prompt
channeling of report copies -
Number of tests per year
MPN Test - Type of sample.
Confirmed (+)_ (-) (Total).
Completed (+) (-) (Total).
MF Test - Type of Sample
Direct Count (+) (-) (Total).
Verified Count (+) (-) (Total).
Personnel
Adequately trained or supervised for bacteriological examination of water.
Personnel involved:
Professional staff (total)
Sub-professional support (total)
Clerical assistance (total)
Reference Material
Copy of Standard Methods (current edition) available in the laboratory ...
State or Federal manuals on bacteriological procedures available for staff use
State or Federal agency newsletter on laboratory information
available for staff use
Scientific journals in water research accessible
Laboratory Facilities
Laboratory room space and bench-top area adequate for needs
during peak work periods
Prep room space adequate and located near laboratory
Sufficient cabinet space for media, chemicals, glassware,
and equipment storage
Facilities clean, with adequate lighting and ventilation, and reasonably
free from dust and drafts
Office space and equipment available for processing water examination
reports and mailing sample bottles
Laboratory Safety
Personnel and carts permitted mobility without obstructions
that cause accidents
Adequately functioning autoclaves and stills, with periodic
inspection and maintenance
Electrical service conforms to local, state or National Electrical Codes ...
All electrical equipment grounded through three-wire system or
separate ground to cold water pipe
Foam-type and carbon dioxide fire extinguishers accessible
Fire exits from laboratory clear at all times
Emergency (deluge) shower accessible and functional
Safety features such as pipet waste jars with disinfectant, centrifuge
shield, splatter guard, and blender covers employed to avoid
bacterial aerosols
Approved practices for handling and disposing of radioactive
chemicals used in special bacteriological procedures
168 Evaluating Water Bacteriology LaboratoriesIGeldreich
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First aid supplies available and not out-dated
Personnel trained to safely handle steam, flames, chemicals, pathogens, etc.
Personnel indoctrinated in first aid emergency procedures, fire control, etc.
Broken glass, sharp needles, etc., properly handled and disposed of
LABORATORY MANAGEMENT 169
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CHAPTER XI
THE NARRATIVE REPORT
PREPARING A NARRATIVE REPORT
Once the on-site evaluation of the laboratory has been completed,
including an informal conference summation of the findings, a narrative
report must be prepared by the laboratory survey officer to accompany
the completed survey form (EPA-103, Bacteriological Survey for Water
Laboratories). The primary purpose of this report is to inform Federal and
state authorities in the water supply program as to the acceptability of
data being developed in the laboratory for use in water quality monitor-
ing. This status report is then further detailed with recommendations
directed toward furthering improved data refinement and monitoring
effectiveness. Where deviations from Standard Methods or the recom-
mended procedures in the EPA Microbiology Methods Manual are ob-
served, the problem should be described with supporting evidence. Re-
commendations must also include an adequate rationale of the need for
change. The technical report must not be used by the laboratory survey
officer as a mechanism to express unsupported personal opinions nor
should the report be used to promote personal favorite choices of
methods, media, instruments, or commercial products without factual
data or other evidence to support such claims. The text must be written in
clear, concise, precise language. Sheer bulkiness of the report is no
criterion of excellence. Finally, the narrative report must be prepared
promptly upon laboratory survey officer's return to the duty station while
the facts are still readily recalled from notes, survey form, and memory.
The Federal Water Supply program recommends the following format:
1. Title
This first section of the report immediately identifies the what, where,
when, and by whom for the reader.
Survey Report on the
Bacteriological Examination of Water
at the
(name of laboratory)
(street address)
(City, State, Zip Code)
(date of survey)
by
(name, title, organization,
and address
of reviewing consultant)
THE NARRATIVE REPORT 171
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2. Laboratory Certification Status
This section immediately announces the survey officer's decision on
the laboratory certification status.
Example:
The equipment and procedures employed in the bac-
teriological analysis of water by this laboratory con-
formed with the provisions of Standard Methods for the
Examination of Water and Waste-water (current edition)
and with the provisions of the Federal Drinking Water
Standards (see most recent update in the Federal Regis-
ter) , except for the items marked with a cross " X" on the
accompanying survey form (EPA-103). Items marked
"O" do not apply to the procedures programed in this
laboratory. Specific deviations are described, and ap-
propriate remedial action for compliance is given in the
following recommendations:
3. Recommendations
List each deviation by item number used on the survey form; describe
exact deviation, supplement by tabular data or specific case histories if
necessary, and recommend procedural change for compliance with stan-
dard procedures.
4. Laboratory Evaluation Program
This section applies only when a Federal or state laboratory program,
whose responsibility it is to evaluate other water laboratories within its
geographical areas of responsibility, is, itself, being evaluated. All
laboratories known to examine water within the geographical area, the
nature of their involvement (bacteriological), dates of the most recent
laboratory evaluations, and the names of the specific survey officers
should be tabulated. Results of a split sampling program for these certified
laboratories should also be included in the table whenever this supple-
mental service is performed. Where the program activity requires the
endorsement of new or additional survey officers, a statement of their
acceptability should be included in this section. Such endorsements can
only be made after the senior evaluation officer in the state or Federal
laboratory evaluation service has observed the candidate's technical
competence and approach to the assignment during a survey.
Example:
Ms. O. Serve, Supervising Microbiologist III, is the
designated state water laboratory survey officer. During
my 2-day conference on laboratory procedures at the
Central Laboratory, Ms. Serve demonstrated the qual-
ities of temperament desirable to obtain the cooperation
of laboratory personnel in improving their procedures
where necessary, without incurring a feeling of resent-
ment. Ms. Serve is familiar with bacteriological indicator
concepts, detection methods using multiple tube, mem-
brane filter and pour plate techniques, laboratory ap-
172 Evaluating Water Bacteriology Laboratories/Geldreich
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paratus, media requirements, and analyses of laboratory
records. For these reasons, we are pleased to certify Ms.
Serve as the Sta,te Environmental Protection Agency (or
State Health Department) water laboratory survey of-
ficer.
5. Remarks
Additional comments on procedures, description of special tests, re-
cord systems, equipment, space, and personnel needs may be included
under this head. If there are no remarks, delete this section from narrative
report.
6. Commendation
If there is administrative protocol or laboratory leadership in the water
program deserving special commendation, place such remarks under this
head. Such commendation should only be used for outstanding perfor-
mance and include an adequate description of the impact on the water
program. If no commendation is included, delete this section from narra-
tive report.
7. Personnel Certification
Names and titles of personnel together with a general statement of the
scope of procedures for which each individual has been approved are
listed in this section. Names listed either by rank or in alphabetical order.
Examples:
Dr. E. Coli, supervising bacteriologist, is approved for
the application of multiple tube procedure and mem-
brane filter method for total coliform detection and the
standard plate count to the examination of potable water;
and the fecal coliform, fecal streptococcus and Salmonella
techniques to a variety of raw surface and groundwaters
used for public water supply intake and treatment.
Ms. C. Water, laboratory technician, is approved for
he application of the membrane filter total coliform pro-
cedure, and standard plate count examination of potable
water.
As an alternative approach, personnel certification may also be given in
a blanket approval to the staff, if all are equally knowledgeable and
involved in the various water examination procedures.
Example:
The following laboratory personnel are approved for
the application of the membrane filter total coliform pro-
cedure (or multiple tube procedure) and the standard
plate count to the examination of potable water:
Dr. P. Gram, Supervising Microbiologist
Mrs. B. Scope, Public Health Bacteriologist
Mr. M. Filter, Laboratory Technician IV
This staff is also approved for the application of total
coliform, fecal coliform, fecal streptococcus,
Pseudomonas aeruginosa, and Salmonella procedures
THE NARRATIVE REPORT 173
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to a variety of waters including fresh and marine recrea-
tional waters, effluents, and stream water quality mea-
surements.
8. Conclusions
Give descriptive conclusions: include recommendations for approval
or rejection of the laboratory. Typical conclusions of laboratory quality
fall into one of three categories: (a) unqualified acceptance; (b) qualified
acceptance; or (c) prohibitive status. Unqualified acceptance is the high-
est rating given to those laboratories that had no apparent deviations from
standard procedures during the period of the on-site survey. Qualified
acceptance recognizes some deviations from acceptable procedures—
deviations that do not seriously affect the validity of results. The prohibi-
tive rating is given when the laboratory lacks essential equipment, mate-
rials, or properly trained personnel, any one or all of which results in
major technical deficiencies that grossly affect the validity of laboratory
results. Reclassification of a laboratory on prohibitive status will require
acquisition of essential laboratory equipment and supplies necessary to
perform the bacteriological tests as described in the current editions of
Standard Methods for the Examination of Water and Wastewater or in
the EPA Microbiological Methods Manual, in addition to training the
designated laboratory personnel in basic techniques used in water bac-
teriology. Upon satisfactory completion of these requirements, the
laboratory directors should request a resurvey of the laboratory, pro-
vided they wish the laboratory data to be used in any official compliance
monitoring program.
The specific categories of conclusions can be expressed as:
A. Unqualified Acceptance
The procedures and equipment in use at the time of this survey were
in compliance with the provisions of Standard Methods for the Examina-
tion of Water and Wastewater (current edition) and the Federal Drinking
Water Standards (Federal Register, current revision). Therefore, it is
recommended that the results of bacteriological examinations made by
this laboratory be accepted as official data defined by the Safe Drinking
Water Act (Public Law 93-523, Dec. 16, 1974).
B. Qualified Acceptance
The procedures and equipment in use at the time of this survey com-
plied in general with the provisions of Standard Methods for the Exami-
nation of Water and Wastewater (current edition) and the Federal Drink-
ing Water Standards (Federal Register, current revision), and with cor-
rection of deviations listed, it is recommended that the results of bac-
teriological examinations made by this laboratory be accepted as official
data defined by the Safe Drinking Water Act (Public Law 93-523, Dec. 16,
1974).
C. Prohibitive Status
The procedures and equipment in use at the time of this survey showed
major deviations from the provisions of Standard Methods for the
174 Evaluating Water Bacteriology Laboratories/Geldreich
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Examination of Water and Wastewater (current edition) and the Federal
Interim Drinking Water Standards (Federal Register, current revision).
As a result of procedural deficiencies, test sensitivity is below an
acceptable level for monitoring potable water quality, established at one
coliform organism per ml. The laboratory is, therefore, placed on a
prohibitive status for the bacteriological examination of public water
supplies as required by the Safe Drinking Water Act (Public Law 93-523,
Dec. 16, 1974).
Requirements for a reclassification of this laboratory to acceptable
compliance will require: (a) acquisition of essential equipment items and
supplies; (b) training of designated laboratory personnel in basic
techniques used in water bacteriology, followed by; (c) satisfactory com-
pliance in aresurvey of the laboratory to be requested at such time as the
laboratory director deems that deficiencies cited in this report have been
satisfied.
The narrative report must be signed by the survey officer or consultant
who conducted the evaluation and prepared the completed survey form.
PROCESSING THE REPORT
In acover letter prepared to accompany the report, comments concern-
ing deviations are summarized and the laboratory director is requested to
respond promptly, indicating that compliance or corrective actions were
taken. Copies of the evaluation report (cover letter, narrative, and survey
form) should be forwarded to the appropriate EPA regional office, the
state engineering director, and state laboratory director. The original
copy should be retained in the office of the laboratory survey officer as
part of the file on this program activity.
THE NARRATIVE REPORT 175
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GUIDELINES ON PREPARING AND PROCESSING
A NARRATIVE REPORT
Anatomy of the Technical Report
Report prepared promptly -
Recommendations include an adequate rationale _
Devoid of unsupported personal opinion or personal preferences
not supported by facts _
Narrative in clear, concise, precise language _
Report Format
1. Title (what, where, when, and by whom) _
2. Lab Certification Status (approved or prohibited) _
3. Recommendations (deviations described) _
4. Laboratory evaluation program (program activity described) _
5. Remarks (suggestions, not deviations, noted) _
6. Commendation (unusual protocol or leadership noted) _
7. Personnel Certification (staff capabilities defined) _
8. Conclusions (data do or do not meet requirements of the
Federal Drinking Water Standards) _
Processing the Report
Cover letter sent to laboratory director requesting response _
Report transmitted included cover letter, narrative, and completed
laboratory survey form _
Copies of the report sent to EPA regional office, state engineering
director, and laboratory director _
176 Evaluating Water Bacteriology Laboratories/Geldreich
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GLOSSARY
abatement: The method of reducing the degree or intensity of pollution,
also the use of such a method.
acclimation: The physiological and behavioral adjustments of an organism
to changes in its immediate environment.
acid: Most commonly refers to a large class of chemicals having a sour
taste in water; ability to dissolve certain metals, bases or alkalies to
form salts and to turn certain acid-base indicators to their acid form.
Characterized by the hydrated H+ ion.
aeration: The process of adding oxygen to, removing volatile constituents
from, or mixing a liquid by intimate contact with air.
aerobe: An organism capable of growing in the presence of oxygen.
aerobic: Description of biological or chemical processes that can occur
only in the presence of oxygen.
aerosol: A suspension of liquid or solid particles in the air.
agar: Dried polysaccharide extract of red algae (Rhodophyceae) used as a
solidifying agent in microbiological media.
algae: Primitive plants, one- or many-celled, usually aquatic and capable
of growth on mineral materials via energy from the sun and the green
coloring material, chlorophyll.
alkalinity: The sum of the effects opposite in reaction to acids in water.
Usually due to carbonates, bicarbonates, and hydroxides; also in-
cluding borates, silicates and phosphates.
amperometric chlorine residual: A means of determining residual availa-
ble chlorine with phenyl arsene oxide (PAO) titration using current
response as an indicator of equivalence. For wastewater, the PAO
preferably is used in excess with iodine backtitration.
anaerobe: An organism capable of growing in the absence of atmospheric
oxygen, with essential oxygen being obtained from sulfates, carbon-
ates, or other oxygen-containing compounds.
anaerobic: Life processes or chemical reactions that occur in the absence
of oxygen or a condition in which dissolved oxygen is not detectable
in the aquatic environment.
anion: A negatively charged ion in water solution. May be a single or a
combination of elements, e.g., the Cl~ ion in a water solution of NaCl
(common table salt) or SOj ion in a H2SO4 (sulfuric acid) solution.
antibiotic: Organic toxins excreted by a microorganism (bacterium or
fungus) that inhibits or kills another microorganism.
antibody: A protein molecule formed by the body in response to the
presence of an antigen.
antigen: A foreign stimulant (usually a protein) that induces the formation
of antibodies in the body.
GLOSSARY 177
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approved laboratory methods: Approved laboratory methods are those
specified in Standard Methods for the Examination of Water and
Wastewater, prepared and published jointly by the American Public
Health Association, the American Water Works Association, and
the Water Pollution Control Federation and those specified by the
EPA manual Microbiological Methods for Monitoring the Environ-
ment.
autoclave: An apparatus using steam under pressure for sterilization.
available residual chlorine: Generally refers to that part of the chlorine
that will react with ortho tolidine or amperometric tests and exhibits
significant germicidal activity.
bacillus: Rod-shaped bacterium; a genus of the family Bacillaceae.
bacteria: Primitive organisms having some of the features of plants and
animals. Generally included among the fungi. Usually do not contain
chlorophyll, hence commonly require preformed organic nutrients
among their foods. May exist as single cells, groups, filaments, or
colonies.
bactericide: Any component that will kill or destroy bacteria.
bacteriophage: A virus that infects bacteria and effects lysis of bacterial
cells.
bacteriostatic: A condition during which the normal metabolic functions
of bacteria are arrested until favorable conditions are restored.
biological oxidation: The process by which bacterial and other microor-
ganisms feed on complex organic materials and decompose them.
Self-purification of waterways and activated sludge and trickling
filter waste water treatment processes depend on this principle. The
process is also called biochemical oxidation.
BODs: The amount of dissolved oxygen consumed in 5 days by biological
processes breaking down organic matter in an effluent.
buffer action: An action exhibited by certain chemicals that limits the
change in pH upon addition of acid or alkaline materials to a medium
or other fluid. In surface water, the primary buffer action is related to
carbon dioxide, bicarbonate, and carbonate equilibria.
capsule: A gelatinous envelope or slime layer surrounding the cell wall of
certain microorganisms.
carrier: A person in apparently good health who harbors a pathogenic
microorganism.
catalyst: A substance that influences the rate of chemical change but
either remains unchanged during the reaction or is regenerated
thereafter.
centigrade: (Celsius) A temperature measurement in which the freezing
point of pure water at sea level is designated as 0°C and the boiling
point designated as 100°C.
cfs: Cubic feet per second, a measure of the amount of water passing a
given point.
chloramines: Products of the combination of chlorine and ammonia.
Commonly classified as combined available chlorine.
178 Evaluating Water Bacteriology LaboratorieslGeldreich
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chlorination: The application of chlorine to water or wastewater for the
purposes of disinfection, oxidation, odor control, or other effects.
Pre-chlorination — before treatment; post-chlorination — after
treatment; in-process chlorination — during treatment.
chlorine demand: The difference between applied chlorine and residual
available chlorine in aqueous media under specified conditions and
contact time. Chlorine demand varies with dosage, time, tempera-
ture, nature, and amount of the water impurities.
coagulant: A chemical, or chemicals, which when added to water suspen-
sions will cause finely dispersed materials to gather into larger mas-
ses of improved filterability, settleability, or drainability.
coagulation: The clumping of particles to settle out impurities; often
induced by chemicals such as lime or alum.
coccus: A spherical bacterium.
coliform group: A group of bacteria that inhabits the intestinal tract of
man, warm-blooded animals; may be found in plants, soil, air, and
the aquatic environment. Includes aerobic and facultative gram
negative nonspore forming bacilli that ferment lactose with gas for-
mation.
colloid, colloidal state: A state of suspension in which the particulate or
insoluble material is in a finely divided form that remains dispersed in
the liquid for extended time periods. Usually cloudy or turbid sus-
pensions requiring flocculation before clarification.
colony: A macroscopic mass of microorganisms growing together, the
cells of which have a common origin; often used in a limited sense to
refer to bacterial masses growing on a solid medium.
combined available chlorine: Generally refers to chlorine-ammonia com-
pounds exhibiting a slower reaction with ortho tolidine, determina-
ble with phenyl arsene oxide after addition of potassium iodide under
acid conditions; usually requires higher concentration and longer time
to kill microorganisms in comparison with free available chlorine.
communicable: Pertaining to a disease whose causative agent is readily
transferred from one person to another.
contamination: A general term referring to the introduction of materials
into water that make the water less desirable for its intended use.
Also introduction of undesired substances into air, solutions, or
other defined media (chemical or biological).
counterstain: A background stain applied to stained material to increase
contrast.
criterion (pi. criteria): Some physical, chemical, or biological characteris-
tic that can be measured. Commonly used as a basis for standards.
cross connection: In plumbing, a physical connection between two differ-
ent water systems, such as between potable and polluted water lines.
deionized water: Water that has been treated by ion exchange resins or
compounds to remove cations and anions present in the form of
dissolved salts.
desalinization: Salt removal from sea or brackish water.
GLOSSARY 179
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detritus: The heavier material moved by natural flow, usually along the
channel bed. Sand, grit, or other coarse material.
differential medium: Medium developed to elicit a specific characteristic
of an organism or group of organisms.
digestion: The biochemical decomposition of organic matter. Digestion of
sewage sludge takes place in tanks where the sludge decomposes and
results in partial gasification, liquefaction, and mineralization of
pollutants.
disinfection: Effective killing by chemical, radiation, or physical process-
es of all organisms capable of causing infectious disease. Chlorina-
tion is the disinfection method commonly employed in water and
sewage treatment processes.
dissolved oxygen (DO): The oxygen dissolved in water or sewage.
Adequately dissolved oxygen is necessary for the life of fish and
other aquatic organisms and for the prevention of offensive odors.
Low dissolved oxygen concentrations generally are due to discharge
of excessive organic solids having high BOD and are the result of
inadequate waste treatment.
distilled water: A purified water resulting from heat vaporization followed
later by vapor condensation to separate the water from nonvolatile
impurities.
drinking water standards: A list of standards prescribed for potable water
acceptable for public consumption.The standards concern sources,
protection, and bacteriological, biological, chemical, and physical
criteria—some mandatory, some desired.
ecology: The interrelationships of living things to one another and to their
environment or the study of such interrelationships.
effluent: Sewage, water, or other liquid, partially or completely treated or
in its natural state, flowing from a reservoir, basin, or treatment plant
into receiving streams or marine coastal waters.
endemic: Peculiar to or occurring constantly in a community.
endogenous metabolism: A diminished level of metabolism in which vari-
ous materials previously stored by the cells are oxidized.
endotoxin: A toxin produced in an organism and liberated only when the
organism disintegrates.
enteric organisms: Those organisms commonly associated with the intes-
tinal tract of warm-blooded animals.
epidemiology: The study of diseases as they affect populations.
equivalent terms:
Exponential
Value American System Symbol British System Symbol
1 x 10 6 parts per million ppm parts per million ppm
1 x 10"9 parts per billion ppb parts per milliard ppm
1 x 10-12 parts per trillion ppt parts per billion ppb
estuaries: Areas where the fresh water meets salt water. For example, at
bays, mouths of rivers, salt marshes, and lagoons.
Evaluating Water Bacteriology LaboratorieslGeldreich
180
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eutrophic lakes: Shallow lakes, weed-choked at the edges and very rich in
nutrients. The water is characterized by large amounts of algae, low
water transparency, low dissolved oxygen and high BOD.
eutrophication: An action involving the aging of lakes; characterized by
nutrient enrichment and increasing growth of plant and animal or-
ganisms. The net effect is to decrease depth until the lake becomes a
bog and eventually dry land. Man-made pollution tends to hasten the
process.
facultative bacteria: Bacteria that can adapt themselves to growth and
metabolism under aerobic or anaerobic conditions. Many organisms
of interest in wastewater stabilization are among this group.
fahrenheit: A temperature scale in which pure water at sea level freezes at
32°F and boils at 212°F
fastidious organism: An organism that is difficult to isolate or cultivate on
ordinary culture.
fecal coliforms: A subgroup of coliform bacteria that has a high positive
correlation with fecal contamination associated with all warm-
blooded animals. These organisms can ferment lactose at 44.5°C and
produce gas in a multiple tube procedure (EC confirmation) or acid-
ity in the membrane filter procedure (M-FC medium).
fecal streptococci: Bacterial indicators of fecal pollution whose normal
habitat is the intestinal tract of man and other warm-blooded ani-
mals. Species and their varieties of particular interest include: 5.
faecalis, S.faecalis var. liquefaciens, S.faecalis var. zymogenes, S.
durans, S.faecium, S. bovis, and 5. equinus.
fermentation: A form of respiration by organisms that requires little or no
free oxygen, yields alcohol and carbon dioxide as end products, and
releases only part of the food energy available; e.g., the conversion
of sugars into alcohol by enzymes from yeasts.
filamentous: Characterized by threadlike structures.
filter: A porous media through which a liquid may be passed to effect
removal of suspended materials. Filter media may include paper,
cloth, sand, prepared membranes, gravel, asbestos fiber, or other
granular or fibrous material.
filtrate: Liquid that has passed through a filter.
filtration rate: A rate of application of water or wastewater to a filter.
Commonly expressed in million gallons per acre per day or gallons
per square foot per minute.
flagellum: A flexible, whiplike appendage on some bacterial cells; used as
an organ of locomotion.
floe: Gelatinous or amorphous solids formed by chemical, biological, or
physical agglomeration of fine materials into larger masses that are
more readily separated from the liquid.
free available chlorine: Generally refers to that chlorine existing in water
as the hypochlorous acid. Characterized by rapid color formation
with ortho tolidine. Can be titrated in neutral solution with phenyl
arsene.
GLOSSARY 181
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fungi: Simple or complex organisms without chlorophyll. The simpler
forms are one-celled; higher forms have branched filaments and
complicated life cycles. Examples are molds, yeasts, and mush-
rooms.
germicide: A chemical agent that kills microorganisms.
Gram stain: A differential stain by which bacteria are classed as Gram-
positive or Gram-negative depending upon whether they retain or
lose the primary stain (crystal violet) when subjected to treatment
with a decolorizing agent.
groundwater: The supply of freshwater under the earth's surface in an
aquifer or soil that forms a natural water resource.
growth curve: Graphic representation of the growth (population changes)
of bacteria in a culture medium.
habitat: The natural environment of an organism.
hardness: Commonly refers to chemicals interfering with soap action or
producing scale in boilers or heating units. Specifically refers to cal-
cium and magnesium salts such as bicarbonate, carbonates, chlo-
rides, and nitrates, sometimes includes iron, aluminum and silica.
humus: A brown or black complex and variable material resulting from
decomposition of plant or animal matter.
hydrostatic head: The pressure exerted by a given height of liquid above a
given datum point. May be listed in feet of head, pounds per square
inch, or other criteria.
IMViC test: A collection of tests used to differentiate Escherichia from
Aerobacter. IMViC stands for /ndole, Methyl Red, Voges-Pros-
kauer, and Citrate. The "i" is for pronunciation convenience only.
indicator: A substance that changes color as conditions change; e.g., pH
indicators reflect changes in acidity or alkalinity. Redox indicators
respond to changes in reduction-oxidation potential.
infection: Introduction of a foreign organism that can multiply and pro-
duce a resulting change from normal.
influent: Material entering a process unit or operation.
inhibition: Prevention of growth or multiplication of microorganisms.
inoculum: A concentration of microorganisms added to a medium to
initiate a growth response.
inorganic: Being composed of material other than plant or animal mate-
rials. Forming or belonging to the inanimate world.
interstate carrier water supply: A water supply whose water may be used
for drinking or cooking purposes aboard common carriers (planes,
trains, buses, and ships) operating interstate. Interstate carrier water
supplies are regulated by the Federal government.
interstate waters: According to law, waters defined as: (1) rivers, lakes,
and other waters that flow across or form a part of State or interna-
tional boundaries; (2) waters of the Great Lakes; (3) coastal waters,
the scope of which has been defined to include ocean waters seaward
to the territorial limits and waters along the coastline (including
inland streams) influenced by the tide.
182 Evaluating Water Bacteriology Laboratories/Geldreich
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leaching: The process by which soluble materials in the soil, such as
nutrients, pesticide chemicals, or contaminants, are washed into a
lower layer of soil or are dissolved and carried away by water.
medium (pi. media): Any substance that supports the growth and multi-
plication of microorganisms.
membrane filter (MF): A flat, highly porous, flexible plastic disc, com-
monly about 0.15 mm in thickness and 47-50 mm in diameter. Mem-
brane filters with a pore size of 0.45/u. are used in water microbiology
to entrap organisms from a sample. With the use of selected media,
incubation time, and choice of temperature, they permit direct
enumeration by colony count of selected organisms.
meniscus: The curved upper surface of a liquid in a tube that is concave
upward when the containing walls are wetted by the confined liquid
and convex upward when they are not.
mesophillic: Organisms capable of optimum metabolic activities at tem-
peratures from about 80° to 110°F (26° to 42°C).
metabolite, essential: A substance whose presence in very low concentra-
tion (micrograms per milliliter or below) must be supplied from an
external source so that the organism may carry out its normal func-
tions or so that a specific biochemical reaction may be allowed to
proceed.
meter: The length of a reference platinum bar used as a standard unit of
measurement of length in the metric system; 1 meter = 39.37 inches.
mg/1: Milligrams per liter; a unit of concentration on a weight/volume
basis. Equivalent to ppm when the specific gravity of the liquid is 1.0.
micro: 1/1,000,000 of a unit of measurement, such as microgram, micro-
liter.
milli: An expression used to indicate 1/1000 of a standard unit of weight,
length or capacity (metric system):
Milliliter (ml) 1/1000 liter (1)
Milligram (mg) 1/1000 gram (g)
Millimeter (mm) 1/1000 meter (m)
mixing zone: An area where two or more substances of different charac-
teristics blend to form a uniform mixture; i.e., chlorine application,
heated water, or other discharged materials entering a water mass
will show significant differences of chlorine residual, temperature,
or other criteria. These differences depend on the sampling location
throughout the mixing zone and approach uniform results with re-
spect to lateral, longitudinal, and vertical sampling positions when
mixing has been completed.
moisture content: The content of water in some material. Commonly
expressed in percentage of moisture in soil, sludge, or feces.
most probable number (MPN): A statistical method of determining micro-
bial populations. A multiple dilution tube technique is utilized with a
standard medium and observations are made for specific individual
tube effects. Resultant coding is translated by mathematical proba-
bility tables into population numbers.
nitrification: The biological oxidation of ammonia to nitrate.
GLOSSARY 183
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normality: (a) A means of expressing the concentration of a standard
solution in terms of the gram equivalents of reacting substances per
liter, (b) Generally expressed as a decimal fraction, such as 0.1 or
0.02 N.
nutrients: (a) Anything essential to support life, (b) Include many com-
mon elements and combinations of them. The major nutrients in-
clude carbon, hydrogen, oxygen, nitrogen, sulfur, and phosphorus.
(c) Nitrogen and phosphorus are of major concern because they tend
to recycle and are difficult to control.
organic: Substances formed as a result of living plant or animal organisms.
Generally contain carbon as a major constituent.
organic chloride: Compounds containing chlorine in combination with
carbon, hydrogen, and certain other elements.
ortho tolidine chlorine test: The dye ortho tolidine, under highly acid
conditions, produces a yellow color proportional in intensity to the
concentration of available residual chlorine and certain other oxi-
dants or interfering materials.
outfall: The mouth of a sewer, drain, or conduit where an effluent is
discharged into the receiving waters.
oxidation: Chemically, the addition of oxygen, removal of hydrogen, or
the removal of electrons from an element or compound.
parasite: An organism that lives in or on another organism and results in
varying degrees of harm or damage.
particulates: Detectable solid material dispersed in a gas or liquid. Small-
sized particulates may produce a smoky or hazy appearance in a gas
and a milky or turbid appearance in a liquid. Larger particulates are
more readily detected and separated by sedimentation or filtration.
pasteurization: Use of heat for a prescribed period of time to reduce the
total number of microorganisms, especially pathogenic or otherwise
undesirable forms.
pathogen: An organism capable of eliciting disease symptoms in another
organism.
Petri dish: Double glass or plastic dish used to cultivate microorganisms.
pH: An index of hydrogen ion activity. Defined as the negative logarithm
(base 10) of H+ ion concentration at a given instant. On a scale of 0 to
14, pH 7.0 is neutral; pH less than 7.0 indicates a predominance of H+
or acid ions; pH greater than 7.0 indicates a predominance of OH~ or
alkaline ions.
pollutant: Dredged spoil, solid waste, incinerator residue, sewage, gar-
bage, sewage sludge, munitions, chemical waste, biological mate-
rials, radioactive materials, heat, wrecked or discarded equipment,
rock, sand, and industrial, municipal, and agricultural waste dis-
charged into water.
pond: A basin or catchment for retaining water used for equalization,
stabilization, or other purposes. Commonly less than 5 feet deep.
potable water: Water suitable (from both health and aesthetic considera-
tions) for drinking or cooking purposes.
184 Evaluating Water Bacteriology Laboratories/Geldreich
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ppm (parts per million): A unit of concentration signifying parts of some
substance per million parts of dispersing medium. Equivalent numer-
ically to mg/1 when the specific gravity of the solution is 1.0.
precipitate: The formation of solid particles in a solution, or the solids that
settle as a result of chemical or physical action that caused the solids
to suspend from solution.
pressure: The total load or force acting upon a surface. In hydraulics, the
term commonly means pounds per square inch of surface, or kilo-
grams per square cm, above atmospheric pressure on site. (Atmos-
pheric pressure at sea level is about 14.7 pounds per square inch.)
primary effluent: Effluent from a sewage treatment process that provides
partial removal of sewage solids by physical methods so that 1 liter of
the effluent does not contain more than 1 ml of settleable solids as
determined by an approved laboratory method.
proteins: Naturally occurring compounds containing carbon, hydrogen,
nitrogen, and oxygen, with smaller amounts of sulfur and phos-
phorus and trace components essential to living cells.
protozoa: Single-cell or multiple-cell organisms, such as amoeba, celiates,
and flagellates. Commonly aquatic and generally deriving most of
their nutrition from preformed organic food.
psychrophilic organisms: Low-temperature-loving organisms, or or-
ganisms having a competitive advantage over other organisms at
lower temperatures, i.e., from about 10°C downward to the freezing
point.
public water supply: A water supply with at least 15-service connections
on the distribution network or a supply regularly serving at least 25
individuals. This system includes the water works and auxiliaries for
collection, treatment, storage, and distribution of the water from the
sources of supply to the free-flowing outlet of the ultimate consumer.
pure culture: A culture containing only one species of organism.
putrefaction: Biological decomposition of organic matter with the forma-
tion of ill-smelling products, such as hydrogen sulfide amines, mer-
captans; associated with anaerobic conditions.
qualitative: Defines a procedure for detecting the occurrence of organisms
or chemical entities in water; applied to nonmeasurable aspects.
quantitative: Defines a procedure or object in terms of its measureable
aspects or characteristics; implies the use of mathematics, especially
statistics.
receiving waters: Rivers, lakes, oceans, or other bodies that receive
treated or untreated waste waters.
reclaimed waste water: Waters originating from sewage or other waste
that have been treated or otherwise purified to permit direct benefi-
cial reuse or to allow reuse that would not otherwise occur.
reservoir: A pond, lake, tank, or basin, natural or man-made, used for the
storage, regulation, and control of water.
river basin: The total area drained by a river and its tributaries.
GLOSSARY 185
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salt: A chemical compound formed as a result of the interaction of an acid
and an alkali (base). The most common salt is sodium chloride
formed from hydrochloric acid and sodium hydroxide. This ionizes
in water solution to form sodium and chloride ions.
saprophytic: Organisms feeding or growing on dead or decaying organic
matter. Organisms that utilize nonliving organic matter as a food.
saturation: Commonly refers to the maximum amount of any material that
can be dissolved in water or other liquid at a given temperature and
pressure. For oxygen, this commonly refers to a percentage satura-
tion in terms of the saturation value, such as about 9 mg 02 per liter at
20°C.
screen: A device with openings, generally having a relatively uniform
size, that permits liquid to pass but retain larger particles. The screen
may consist of bars, coarse to fine wire, rods, gratings, paper,
membranes, etc., depending upon particle size to be retained.
sedimentation: The process of subsidence and deposition of suspended
matter from wastewater by gravity. Also called clarification, set-
tling.
sewage: Liquid or solid refuse (domestic and industrial wastes) carried off
in sewers.
sewage slimes: Consisting of organisms growing on wastewater nutrients
and forming mucilaginous films, streamers, or clumps. May consist
of bacteria, molds, protozoa, or algae.
sewer: A pipe or conduit, generally covered, for the purposes of convey-
ing wastewaters from the point of origin to a point of treatment or
discharge.
sludge: Accumulated or concentrated solids from sedimentation or
clarification of wastewater. Contains varying proportions of solids in
wastewater depending upon source, process, and nature.
sludge banks: An accumulation of solids, including silt, mineral, organic,
and cell mass particulate material, that is produced in an aquatic
system characterized by low current velocity. Generally refers to
gross deposits of appreciable depth.
sludge cake: The solids remaining after dewatering sludge by vacuum,
filtration, or sludge drying beds. Usually forkable or spadable, with a
water content of 30 to 80%. Also may occur on the boundaries of
surface water.
smear: A thin layer of material, e.g., bacterial culture, spread on a glass
slide for microscopic examination. Also referred to as a film.
solution: a) A homogenous mixture of gas, liquid, or solid in a liquid that
remains clear indefinitely.
b) Generally an atomic, ionic, or molecular dispersion in a liquid
(may be colored).
c) A water solution of dissolved material.
specific gravity (Sp. Gr.): a) The weight of a material per unit volume in
reference to the weight of water at maximum density.
b) Water at 4°C has a weight of 1 gram per ml. The weight ratio of any
substance divided by the weight of water is the specific gravity.
spore: A reproductive unit, lacking a preformed embryo, that is capable of
germinating directly to form a new individual. A resistant body
186 Evaluating Water Bacteriology Laboratories/Geldreich
-------�
formed by certain microorganisms; a resistant resting cell; a primi-
tive unicellular reproductive body.
stabilization: (a) The activity proceeding along the pathway to stability.
(b) In organic wastes, generally refers to oxidation via biochemical
pathways and conversion to gaseous or insoluble materials that are
relatively inert to further change.
stain: A dye used to color microorganisms; used an an aid to visual
inspection.
standard: A measurement limit set by authority. Having qualities or
attributes required by law and defined by minimum or maximum
limits of acceptability in terms of established criteria or measurable
indices.
standard methods: Methods of analysis prescribed by joint action of
American Public Health Association, American Water Works As-
sociation, Water Pollution Control Federation, or U.S. Environmen-
tal Protection Agency. Methods accepted by authority.
standard plate count: A measure of the general bacterial population in
potable water and swimming pool water using standard plate count
agar, 48-hour incubation, and 35°C incubation temperature. The
incubation time of standard plate counts of bottled water, done as for
potable water supplies, is extended to 72 hours because of the slow
generation times for organisms in this water environment.
sterilization: The process of making a medium free of living organisms
such as by killing them, filtering them through a porous medium fine
enough to be a barrier to the passage of organisms, etc.
stock cultures: Known species of microorganisms maintained in the
laboratory for various tests and studies.
stormwater: The runoff of rain and melted snow into the natural drainage
pattern.
strain: A pure culture of microorganisms composed of the descendants of
a single isolate.
substrate: (a) Any substance used as nutrient by a microorganism, (b) The
liquid in an activated sludge aeration tank.
supernate: The liquid over a precipitate or sediment; the fluid remaining
after removal of suspended matter.
suspended solids: The concentration of insoluble materials suspended or
dispersed in waste or used water. Generally expressed in mg per liter
on a dry weight basis. Usually determined by filtration methods.
symbiosis: The living together of two or more organisms in a mutually
beneficial state.
synergism: The ability of two or more organisms to bring about changes
(usually chemical) that neither can accomplish alone.
thermal pollution: Degradation of water quality by the introduction of a
heated effluent. Primarily a result of the discharge of cooling waters
from industrial processes, particularly from electrical power genera-
tion. Even small deviations from normal water temperatures can
affect aquatic life. Thermal pollution usually can be controlled by
cooling towers.
GLOSSARY 187
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thermophilic: High-temperature-loving organisms. Generally considered
to include organisms having a favorable competitive advantage at
temperatures above 110°F or 42°C.
titration: The careful addition of a standard solution of known concentra-
tion of reacting substance to an equivalence point to estimate the
concentration of a desired material in a sample.
TOC: Total organic carbon. A test expressing wastewater contaminant
concentration in terms of the carbon content.
total solids: Refers to the solids contained in dissolved and suspended
form in water. Commonly determined on a weight basis by evapora-
tion to dryness.
ultraviolet rays: Radiations in the part of the spectrum having
wavelengths from about 3,900 Angstrom to about 200 Angstrom.
velocity (flow): A rate term expressed in terms of linear movement per unit
of time. Commonly expressed in ft per sec (English) or cm per sec
(metric).
virulence: The capacity of a microorganism to produce disease.
virus: An obligate intracellular parasitic microorganism smaller than bac-
teria. A term generally used to designate organisms that pass filtra-
tion media capable of removing bacteria. Technically described as a
collective term covering disease stimuli held by some to be living
organisms and by others to be nucleic acids capable of reproduction
and growth.
Voges-Proskauer reaction: A test (VP test) for the presence of acetyl-
methylcarbinol to assist in distinguishing between species of the
coliform group.
volatile acids: A group of low-molecular-weight acids, such as acetic and
propionic, that are distillable from acidified solution.
volatile material: a) Descriptive of chemicals having a vapor pressure low
enough to evaporate from water readily at normal temperatures, b)
With reference to dry solids, the term includes loss in weight upon
ignition at 600°C.
wastewater: Refers to the used water of a community. Generally contami-
nated by the waste products from household, commercial, or indus-
trial activities. Often contains surface wash, storm water, and infilt-
rations water.
water pollution: The addition of sewage, industrial wastes, or other harm-
ful or objectionable material to water in concentrations or in suffi-
cient quantities to result in measurable degradation of water quality.
water quality criteria: The levels of pollutants that affect the suitability of
water for a given use. Generally, water use classification includes:
public water supply, recreation, propagation of fish and other a-
quatic life, agricultural use, and industrial use.
water quality standard: A plan for water quality management containing
four major elements: the use (recreation, drinking water, fish and
wildlife propagation, industrial, or agricultural) to be made of the
water; criteria to protect those uses; implementation plans (for
188 Evaluating Water Bacteriology Laboratories/Geldreich
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needed industrial-municipal waste treatment improvements) and en-
forcement plans; and an anti-degradation statement to protect exist-
ing high quality, waters.
watershed: The area drained by an entire river system, including tributary
streams and intermittent creeks.
water supply system: The system for the collection, treatment, storage,
and distribution of potable water from the sources of supply to the
consumer.
water table: The upper level of groundwater.
zoogloea: A jelly-like matrix developed by certain microorganisms at
some stage in their life cycle. Commonly associated with sludge
flocculation in biochemical treatment operations.
GLOSSARY 189
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SUBJECT INDEX
Absorbent pads
absorption capacity, 52
MF substrate, 51-52, 117, 121, 123, 128,
129, 142, 145, 149-150
sterilization, 60-61
total acidity, 52
toxic residuals, 52
Air bubbles, 123, 129
Air conditioning, 28-29, 163
Air incubation, 27-30, 123-124
Air space, 14
Alcohol
cleaning, 59
dishes, 64
forceps, 39, 65
M-Endo medium, 87-88, 149
M-VFC, 89, 147-148
sterilization, 64
Aluminum items
caps, 47-48
inoculating loops, 38, 65
petri dish containers, 46-47, 63
pipet containers, 45-46, 63
utensils, 43
Ampouled media, 77, 149-150
Applicator sticks, 38, 102, 105
Autoclave, 33-34, 59-63, 163
Balance, 36, 163
analytical, 36
torsion, 36
weights, 36
Bathing waters, 12-13,135,139, 146, 148, 159
Biochemical tests
coliforms, 142-147
fecal streptococci, 140-141
Klebsiella, 142
leptospires, 146
Pseudomonas, 139-140
Salmonella, 144
Staphylococcus, 139
Biological suitability test, 44, 49, 51, 52,
67-70
Borosilicate glass, 43, 45, 48, 57-59
Bottom sediments, 13-14, 143, 145
Brilliant green lactose bile broth, 36, 38, 79.
80, 86, 102-104, 107, 127
Calculations
membrane filter, 125-127, 160
multiple tube, 107-113, 159-160
pour plate, 138-139
Calibration tolerance
balance, 36
dilution blanks, 63-64
graduate cylinders, 121-122
MF funnels, 121
pH meter, 35, 78-79
pipets, 45
thermometers, 34-35
Carbohydrate sterilization, 60
Chain of custody, 18-19
Chelation agent, 18, 118
Chlorinated sewage examinations, 118-120,
140
Cleaning glassware, 57-59, 77, 163
Coliform test limitations, 22, 111-112, 117-
118, 136
Collection procedure, 15-17, 136, 143, 145
Colony counting, 37, 124-127, 137-139
Colony description
fecal coliform, 36, 129-130, 147, 148
fecal streptococci, 37
Pseudomonas aeruginosa, 139
Staphylococcus, 139
total coliform, 36, 87, 124, 142, 147
Completed MPN, 103-105
Confirmed MPN, 102-103
Confluent growth, 22,87-88,89, 126-127, 138
Corrosive resistant glass, 45, 48, 57-59
Cotton plugs, 47-48, 78, 80
Culture dishes
sterilization, 46-47, 63
Culture media, 77-95, 139, 143, 146, 147, 148,
150
Culture tubes, 47-48, 78, 84, 85
closures, 47-48, 78, 80
Data processing, 107-113, 125-127, 137-139,
159-161
Dechlorination, 17-18
Deionized water, 65-70
Delayed incubation
fecal coliform, 20, 89, 135, 147-148
total coliform, 20, 135, 147
Desicote, 39
Detergent, 45, 57-59
Deviations, 2-3, 5, 6, 7, 171, 172, 174
Differential test kits, 144
Dilution blanks, 70-73
Dilution bottles, 48-49, 63-64
glassware quality, 48-49
SUBJECT INDEX
191
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Dilution water
ideal diluent, 70
rinse water, 122-123
sterilization, 63-64
stock buffer, 71-73
volume tolerance, 63-64
Dip-stick test, 150-151
Dishwasher, 57-59
Disposable plastic
petri dishes, 46, 64, 80
pipets, 45
reuse, 64
Distilled water
reverse osmosis, 51, 67
storage, 65-67
suitability test, 44, 49, 51, 52, 67-70, 91
system analysis, 67-68
system maintenance, 70
Dry heat sterilization, 32-33
EC medium, 86, 105-107, 148
Elevated temperature, 30-31, 128-129, 140,
143, 148-149
Endo agar, 87-88, 104
Enrichment procedure, 102, 118-119, 128,
142-143, 146
Enteropathogenic Escherichia coli, 147
primary isolation, 147
serotype identification, 147
Eosin methylene blue agar, 86-87, 104
Escher type stoppers, 49
Ethanol, 17, 59, 64, 65, 87-88, 89, 149
FA technique, 143-144, 148
Facility improvement, 163-164
False positives, 84,85,87,101,103,120,127
143, 147
Fecal coliform
media, 86, 88-89
membrane filter procedure, 118-120
128-130, 147, 148-149
multiple tube procedure, 105-107
Fecal streptococci
differential tests, 140-141
media, 90-91, 140
procedures, 140-142
Fermentation vial, 47
Field monitor, 150-151
Filter funnel, 39, 121-122, 149
Filtration volume, 14-15, 121-122, 129, 142
Flaming tap, 17
forceps, 39-40, 65
Fluorescent light, 36-37, 124, 148, 163
Forceps, 39-40, 122-123
Glassware
beakers, 57, 63
bottles, 57, 62-63, 77, 78
chemically clean, 57-59, 77
culture tubes, 47-48, 78, 80, 84, 85
dilution bottles, tubes, 48-49
Erylenmeyer flasks, 63
graduated cylinders, 121
petri dishes, 46, 63, 80, 121
pipets, 45
quality, 59
sample bottles, 43-44
storage, 164
washing, 57-59, 163
Glossary, 177-189
Graduation marks, 35, 39, 45, 48, 121
Gram stain, 104-105, 163
Handwashing procedures, 58-59
Hot air sterilization, 32-33, 163
temperature measurement, 32-33
Incubator
air, 27-30, 123-124
bench-top, 28-29
heat sink block, 30, 149
humidity, 29, 124
temperature record, 28, 30-31, 32, 33
temperature tolerance, 27-31
walk-in unit, 29-30
water bath, 30-32, 128, 148
Inoculating equipment
applicator sticks, 38, 63, 103, 105
needles, 38-39, 63, 104
transfer loop, 38, 63, 103, 105, 165-166
wire loop, 37-38, 63, 103, 105, 165-166
KF Streptococcus agar, 90-91, 140
Klebsiella
differential tests, 142
procedures, 142
Laboratory
facilities, 163-164
management, 159-169
reference material, 162-163
safety, 164-167
staff, 161-162
Laboratory apparatus, 27-42
Laboratory evaluation
approach, 2-3
certification, 3-4, 172-174
conducting the evaluation, 6
deviations, 2-3, 5, 6, 7, 171, 172, 174
frequency, 3
general status, 5
narrative report, 7, 171-175
personnel certification, 173-174
program objective, 2-3
reciprocal agreement, 4
report processing, 175
review conference, 7
state program, 3-4, 172-173
survey form, 6-7, 171, 172, 175
survey officer, 6, 172-173
Laboratory facilities, 163-164
Laboratory guidelines
apparatus, 41-42
culture media preparation, 93-95
evaluating laboratories, 9
192
Evaluating Water Bacteriology Laboratories/Geldreich
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glassware, metal and plastic items. 54-55
laboratory management, 168-169
laboratory materials preparation, 75
membrane filter coliform procedure, 132
multiple tube coliform procedure, 114-
115
preparing and processing a narrative re-
port, 176
sampling and monitoring, 24-25
supplementary bacteriological methods,
155-157
Laboratory records
data processing, 107-113, 125-127, 137-
139, 159-161
legal considerations, 18-19
media pH records, 83
record forms, 102-103, 137, 160-161
Laboratory safety
aerosols, 165-166
chemical storage, 165
electrical service, 164
equipment maintenance, 28, 30, 34, 35,
36, 38, 40, 62, 164
fire protection, 164-165
first aid, 167
insect control, 166
laboratory space, 164
personal hygiene, 166
radioactive chemicals, 166-167
Laboratory water quality
biological quality, 65-70
chemical quality, 65-70
suitability test, 67-70, 91
system, 65-67
system maintenance, 66-67
Lactose broth, 83-84, 98, 101, 104, 127
Lauryl tryptose broth, 85-86, 98, 101, 104,
127
Leak-proof liner, 43-44, 49
Legal considerations, 18-19
Leptospires
concentration, 145
cultivation, 146
differentiation, 146
Light source
microscope, 36-37, 124, 148
laboratory, 105, 146
M-Endo broth, 87-88, 117-118, 123, 127-128,
142, 143, 147, 149
M-FC broth, 88-89, 119, 128, 147, 150
M-PA agar, 90, 139
M-7-hour agar, 89-90, 148-149
M-VFC broth, 89, 147
Media
bacteriological dyes, 83, 120
general chemicals, 83, 165
pH measurement, 35-36, 78-79, 83
preparation, 43,77-78,119, 121, 163-164
quality control, 80-83, 101, 103
specifications, 83-91, 147
sterilization, 60
storage, 79-80, 137, 150, 164
volume, 83-85, 86, 90, 91, I 19, 121, 137
Membrane filter
bacterial retention, 49
emergency reuse, 51
grid system, 49-50
pore size, 49-50, 119
quality, 49-52
specifications, 49-51, 119
sterilization, 60-61
toxicity, 60-61
variability, 49, 51
vlembrane filter apparatus
field equipment, 19,77, 149-151
filtration units, 39, 61-62, 121-122
forceps, 39-40, 65, 122-123
microscope, 37-38, 124, 148
microscope light, 38, 124, 148
UV sterilizer, 61-62
vlembrane filter (MF) procedure
air bubbles, 123
counting, 124-125, 163
excessive background growth, 22,
87-88, 89, 147
filtration quantities, 14-15, 121-122, 129,
142
filtration series, 121, 123
incubation, 123-124
limitations, 117-120
measured quantities, 39, 121-122
MF-MPN comparisons, 119-120, 159
MF replicates, 130-131
reuse, 51
samples per technicians, 161
substrate
absorbent pad, 51-52, 61, 117, 121,
123, 129, 142, 145, 149-150
agar, 52, 119, 121, 129, 140, 147
verification, 127-128, 139, 147-148, 149
vletal items
caps, 47, 78, 80
foil, 44, 47, 49
utensils, 43, 77
Microscope
binocular, 36-37, 124, 146
FA scope, 143-144, 148
light source, 37, 124, 148
oil immersion, 105
Milk agar, 139
Monitoring response, 13, 14, 21-22, 125-127
Multiple tube (MPN) procedure
calculations, 107-113, 159-160
completed MPN, 103-105
confirmed MPN, 102-103
fecal coliform MPN, 105-107
multiple dilutions, 97-98
presumptive MPN, 15
samples per technicians, 161
tube codes, 99
SUBJECT INDEX
193
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Narrative report, 171-175
Noncoliform populations, 22, 84, 85, 87, 88,
89, 117-118, 122-123, 124, 126-127, 135-
136
Paper, char-resistant, 44, 46, 47, 49, 63
Pathogens, 15, 22, 139-140, 142-147
Personnel
certification, 173-174
clerical, 161-162
professional, 161
sub-professional, 161
testing proficiency, 111-112
training, 128, 162
Peptone dilution water, 71, 129
Petri dishes
containers, 46-47, 63
MF, 46-47, 64, 119, 121, 124
SPC, 46, 63, 136
sterilization, 63, 64
pH measurements, 35-36, 71, 72, 78-79, 83
pH meter, 35-36, 163
Phosphate buffered water, 71-73, 122-123
Physical facilities, 163-164
Pipets
containers, 45-46, 63
discard jars, 165-166
pipetting accuracy, 99
Plastic items
bags, 44-45, 128-129, 148
bottles, 44, 62-63, 77
caps, 47, 77, 80
petri dishes, 46, 64
pipets, 45, 63
Plate count agar, 91, 137
Portable field procedures, 77, 149-151
Potable waters
excessive bacterial populations, 22,
87-88, 89, 117-118, 122-123, 124.
126-127
Preparation room, 57, 163
Presumptive MPN, 99-102
Procedural changes, 2-3, 5, 6, 7
PSEagar, 91, 140
Pseudomonas aeruginosa
media, 90
procedures, 139-140
verification, 139-140
Quality control
absorbent pads, 51-52
agar, SPC, 137
balance accuracy, 36
culture tubes, 47-48
dilution water, 67-73, 123
distilled water, 65-67
glassware cleaning, 57-59
incubation temperature, 27-31
media, 80-83
membrane filters, 49-51, 60-61
MF procedures, 119-120, 123, 130-131,
148
MF rinse (filtration series), 122-123
pH meter, 35-36
pipets, 45, 63
plastic bags, 44-45
plastic dishes, 46
plastic reuse, 64
plastic screw caps, 44
records (data), 18-19, 83, 102-103
sterilization exposure, 32-34, 59-65
technician proficiency, 111-112
thermometer accuracy, 34-35
UV light effectiveness, 61-62, 64
Quebec colony counter, 37, 137-138
Rapid tests, 89-90, 135, 148-149
Records, 18-19, 83, 102-103, 125-127, 137-
139, 159-161
Recreational waters, 12-13, 135, 139, 146,
148, 159
Reference material, 162-163
Refrigeration, sample, 19, 20-21, 136
Repeat sampling, 21-22, 126-127, 160
Representative samples, 11, 12, 13, 14
Rinsing procedures, 57-59, 122-123
Rosolic acid, 88-89
Rubber stoppers, 35, 39, 49
Rust inhibitor, 31
Salmonella
biochemical tests, 144
FA technique, 143-144
preliminary screening, 143-144
qualitative tests, 142-143
quantitative tests, 142
selective media, 143
serological identification, 144-145
Sample
bathing water, 12-13, 98
collecting procedure, 14, 15-17, 136,
143, 145
dechlorination, 17-18
identification, 18-19, 160
minimum size, 14-15, 121, 126,129,136,
142
mixing, 14, 99, 122
potable water, 11-12, 97, 121, 136
refrigeration, 19, 20-21, 136
report forms, 159-161
sediments and sludges, 13-14
stream pollution, 13, 98
transit time, 19-21, 136, 143, 147
transport, 20-21
Sample bottle
air space, 14
closure, 16
specification, 43-45
sterilization, 62-63, 136
Sampling frequency, 11-14, 125
Sampling location, 11, 12, 13, 14, 160
194
Evaluating Water Bacteriology Laboratories/Geldreich
-------�
Screw cap
culture tubes, 48, 77, 78, 80
dilution bottles, 48-49
sample bottles, 43-44, 136
Serological procedures
Enterpathogenic Escherichia coli, 147
pathogenic leptospires. 146
Salmonella, 144-145
Sludges, 13-14, 143
Sodium thiosulfate, 17-18
Stainless steel items
caps, 47. 77, 78, 80
inoculating loop. 37-38, 65
petri dish containers, 46-47, 63
pipet containers. 45-46, 63
Standard plate count
calculation, 138-139
counting, 137-138, 163
incubation time-temperature, 137
interpretation, 22, 135-137
plate count agar, 91, 137
procedure, 57-58, 62. 64. 81-83. 136-137
sample transit time, 20-21. 136
Staphylococcus
media. 139
Sraphylococcus aiireiis. 139
statistical analyses, 107-113
verification, 139
Sterilization methods
alcohol, 70 percent, 64
boiling water. 60-62. 69, 87. 88. 90. 91.
121
dry heat, 32-33, 63
filtration apparatus, 39, 61-62, 121
Hame, 39, 65
membrane filtration. 69, 73, 89. 91
steam, 33-34, 59-64, 121
ultra violet light, 61-62, 64, 121
Storage
media, 79-80, 103, 137, 164
samples, 19-21, 136, 143
Streak plate, 103-104
Stream samples, 19-20, 129, 135, 140, 143,
145, 148, 150
Stressed organisms. 84,85, 118, 124. 139. 150
Supplementary bacteriological methods.
136-157
Survey form, 6-7. 171. 172. 175
Survey frequency, 3-4
Survey officer, 4. 6, 172-173
Swimming pool water. 136, 139, 159
Temperature measurement, 27-35
Thermometer
certification, 34-35
placement. 28. 30, 32-33
Total coliforms
MF test, 117-128. 147-151, 159
MPN test, 97-115. 159-160
Toxic residual. 43, 44. 45. 48. 49, 50-51. 52.
57-59. 61, 65-70, 73
Training, 128. 162
Transit time
estuarine waters. 19-20
natural waters. 19-20. 143
potable waters, 20-21
standard plate count, 20. 136
Tryptose glucose yeast agar, 91, 136-137
Unsatisfactory samples. 21-22, 126-127
Utensils. 43. 77
UV sterilization. 61-62, 64, 121
Variability of replicates, 82-83, 130-131,
136-137
Verification
fecal coliforms, 119, 129, 149
fecal streptococci, 140-141
Klebsiella, 142
Pseudomonas aeruginosa, 139-140
Staphylococcus aureus, 139
total coliforms, 127-128, 147
Washing glassware, 57-59, 163
Water bath
modifications, 31-32
rust inhibitor, 31
Well samples, 15-16, 98, 143
"Whirl-Pak" bags, 44-45, 128-129, 148
Wide mouth bottles, 43-44
SUBJECT INDEX
195
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TECHNICAL REPORT DATA
(Please read Instructions on the reverse before completing)
. REPORT NO.
EPA-670/9-75-006
3. RECIPIENT'S ACCESSION NO.
4 TITLE AND SUBTITLE
HANDBOOK FOR EVALUATING WATER BACTERIOLOGICAL
LABORATORIES
5. REPORT DATE
August 1975 flssuing Datel
>. PERFORMING ORGANIZATION CODE
AUTHOR(S)
Edwin E. Geldreich
8. PERFORMING ORGANIZATION REPORT NO.
9. PERFORMING ORGANIZATION NAME AND ADDRESS
Municipal Environmental Research Laboratory
Office of Research and Development
U.S. Environmental Protection Agency
Cincinnati, Ohio 45268
1CB047
11. CONTRACT/GRANT NO.
12. SPONSORING AGENCY NAME AND ADDRESS
Same as above
13. TYPE OF R
In-house
14. SPONSORING AGENCY CODE
EPA-ORD
15. SUPPLEMENTARY NOTES
6. ABSTRACT
The material included in this Handbook is designed and intended to provide a comprehen-
sive source of information and reference for the evaluation of laboratories involved
in bacteriological testing of potable water supplies and their sources. All aspects
of the laboratory operation are considered—material and media preparation, equipment
needs and specifications, sample collection and handling, bacteriological methodology,
quality control considerations, laboratory management, and the qualifications and
responsibilities of the survey officer. The purpose of the Handbook is to assist the
laboratory survey officer, laboratory director, and senior bacteriologist in charge
of the water program to evaluate the many aspects of the laboratory that are involved
in attaining reliable data.
KEY WORDS AND DOCUMENT ANALYSIS
DESCRIPTORS
b.lOENTIFIE
Tl Field/Group
'Potable water
*Water supply
*Bacteriology
'Laboratories
'Evaluation
Handbooks
Safe Drinking Water Act
Drinking water standards
State laboratory survey
officers
13B
19. DISTRIBUTION STATEMENT
RELEASE TO PUBLIC
19. SECURITY CLASS /ThisReport/
UNCLASSIFIED
21. NO. OF PAGES
206
20. SECURITY CLASS (Thispage)
UNCLASSIFIED
'3)
ftUSGPO: 1976 —657-691/1307 Region 5-11
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