United Stales
Envronmental Protect,on
Agency
EPA 600 3-89 01 3
Mat en 1989
vvEPA
Ecological Assessment of
Hazardous Waste Sites:
A Field and Laboratory
Reference
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EPA/600/3-89/013
March 1989
ECOLOGICAL ASSESSMENT OF HAZARDOUS WASTE SITES:
A FIELD AND LABORATORY REFERENCE
Edited By
William Warren-Hicksl
Benjamin R. Parkhurst2
Samuel S. Baker, Jr.1
iKilkelly Environmental Associates
Highway 70 West - The Water Garden
Raleigh, NC 27622
2Western Aquatics, Inc.
P.O. Box 546
203 Grand Avenue
Laramie, WY 82070
s Environmental Protect
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DISCLAIMER
The information in this document has been funded by the United States
Environmental Protection Agency by Contract Number 68-03-3439 to Kilkelly
Environmental Associates, Raleigh, NC 27622. It has been subject to the Agency's
peer and administrative review, and it has been approved for publication as an EPA
document. Mention of trade names or commercial products does not constitute
endorsement or recommendation for use.
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ACKNOWLEDGMENTS
The cooperation and support of the U.S. Environmental Protection Agency (EPA)
Office of Solid Waste and Emergency Response (OSWER) and Office of Research and
Development (ORD) are gratefully acknowledged. In addition, the support of
U.S. EPA Regions IH, IV, V, and X is greatly appreciated. The authors wish to
specifically thank the individuals who participated in a workshop held in Seattle,
WA on July 25-27,1988. During the workshop, the material contained in this
document was presented and discussed, and many of the comments received during
the workshop have been incorporated. The authors are also appreciative of the many
suggestions for improving the report that have been offered since the workshop and
during the peer review process, and those comments have been considered and
incorporated where appropriate.
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EXECUTIVE SUMMARY
This report is a field and laboratory reference document that provides guidance on
designing, implementing, and interpreting ecological assessments of hazardous
waste sites. It is comprised of nine chapters that address the following: (1) the
definition of an ecological assessment, (2) evaluation and selection of appropriate
ecological endpoints, (3) basic strategies and approaches to ecological assessments,
(4) considerations in field sampling design, (5) the role of quality assurance and
quality control, (6) recommended aquatic and terrestrial toxicity tests, (7)
recommended biomarkers, (8) recommended aquatic and terrestrial field survey
methods, and (9) considerations in data analysis and interpretation. The report
discusses the scientific basis for assessing adverse ecological effects at a hazardous
waste site and presents methods for evaluating the ecological effects associated with
toxic hazardous waste site chemicals.
The methods are intended for implementation in the early phases of the hazardous
waste site evaluation process and should be used as integral parts of hazardous
waste site studies. The methods presented in this document can be implemented
within a time frame of 12 to 18 months and, in some cases, the analyses can be
completed in a matter of days.
The methods presented in this document are not required by regulation. However,
they provide a reasonable basis for assessing the adverse ecological effects associated
with hazardous waste sites.
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Table of Contents
Chapter Title Page
List of Table viii
List of Figures ix
1 INTRODUCTION 1-1
1.1 Purpose 1-1
1.2 Background 1-1
1.3 Definition of an Ecological Assessment 1-3
1.4 Criteria for Methods Selection and Presentation 1-4
1.5 Organization of the Document 1-5
1.6 References 1-6
2 ECOLOGICAL ENDPOINTS 2-1
By: G. Suter
2.1 Introduction 2-1
2.2 Types of Endpoints 2-1
2.3 Criteria for Endpoints 2-4
2.3.1 Assessment Endpoints 2-4
2.3.2 Measurement Endpoints 2-7
2.4 Potential Assessment Endpoints 2-11
2.4.1 Population 2-12
2.4.2 Community 2-14
2.4.3 Ecosystem 2-15
2.4.4 Human Health Concerns 2-16
2.5 Measurement Endpoints 2-16
2.5.1 Individual 2-17
2.5.2 Population 2-19
2.5.3 Community 2-20
2.5.4 Ecosystem 2-22
2.6 Assessment Goals and Assessment Endpoints 2-23
2.7 References 2-26
3 ASSESSMENT STRATEGIES AND APPROACHES 3-1
By: J. Baker
3.1 Introduction 3-1
3.2 Review of Existing Information for the Site 3-1
3.3 Initial Site Visit 3-2
3.4 Development of the Assessment Strategy and Design 3-4
3.5 Assessment Methods 3-6
3.5.1 Toxicity Tests 3-7
3.5.2 Biomarkers 3-10
3.5.3 Field Surveys 3-13
3.6 Summary 3-14
4 FIELD SAMPLING DESIGN 4-1
By: D. Stevens
4.1 General Statistical Considerations 4-1
4.1.1 Theoretical Considerations 4-2
4.1.2 Practical Considerations 4-4
4.2 Sample Design Development 4-5
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Chapter Title Page
4.3 Selection of Sample Design 4-6
4.3.1 Terminology 4-6
4.3.2 Non-Random Methods 4-7
4.3.3 Random Methods 4-8
4.3.4 Stratified Sampling 4-8
4.4 Determination of Sample Size 4-10
4.5 References 4-13
5 QUALITY ASSURANCE AND DATA QUALITY OBJECTIVE 5-1
By: William Warren-Hicks
5.1 Quality Assurance 5-1
5.2 Data Quality Objectives (DQOs) 5-2
5.2.1 Overview of DQOs and the DQO Process 5-2
5.2.2 The Three Stages of the DQO Process 5-5
5.3 References 5-6
6 TOXICITY TESTS 6-1
By: B. Parkhurst, G. Linder, K. McBee, G. Bitten, B. Dutka, C. Hendircks
6.1 General Overview of Toxicity Tests 6-1
6.1.1 Introduction 6-1
6.1.2 Alternative Approaches to Assessing Toxicity 6-2
6.1.3 Toxicity Data 6-4
6.1.4 Integration of Toxicity Tests with Field Surveys 6-6
6.1.5 State of the Science 6-7
6.1.6 References 6-12
6.2 Aquatic Toxicity Tests » 6-15
6.2.1 Introduction 6-15
6.2.2 Aquatic Toxicity Test Methods 6-15
6.2.3 Methods Integration 6-21
6.2.4 Case Studies 6-23
6.2.5 References 6-24
6.3 Terrestrial Toxicity Tests 6-27
6.3.1 Introduction 6-27
6.3.2 Terrestrial Toxicity Test Methods , 6-27
6.3.3 Methods Integration 6-36
6.3.4 References 6-39
6.4 Microbial Toxicity Tests 6-44
6.4.1 Introduction 6-44
6.4.2 Microbial Toxicity Test Methods 6-45
6.4.3 "Ecological Effects" Test 6-54
6.4.4 Case Study: Battery Approach to Toxicity Testing 6-59
6.4.5 References 6-61
7 BIOMARKERS 7-1
By: R. DiGiulio
7.1 Introduction 7-1
7.2 Biomarkers for Exposure 7-4
7.2.1 Direct Indices of Exposure 7-4
7.2.2 Indirect Biomarkers for Exposure 7-11
7.3 Biomarkers for Sublethal Stress 7-19
7.3.1 Non-Specific Biomarkers 7-20
7.3.2 Specific Biomarkers 7-25
7.4 References 7-29
VI
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Chapter Title Page
8 FIELD ASSESSMENTS 8-1
By: L. Kapustka, T. LaPoint, J. Fairchild, K. McBee, J. Bromenshenk
8.1 Introduction 8-1
8.2 Aquatic Surveys 8-3
8.2.1 Introduction 8-3
8.2.3 Methods 8-8
8.2.4 Methods Integration 8-24
8.2.5 Examples of Field Surveys 8-29
8.2.6 References 8-34
8.3 Vegetation Assessment 8-40
8.3.1 Introduction '. 8-40
8.3.2 Remote Sensing Methods 8-43
8.3.3 Direct Observational Methods 8-45
8.3.4 Process Measurement Methods 8-53
8.3.5 Recommended Assessment Approach 8-55
8.3.6 References 8-56
8.4 Field Surveys: Terrestrial Vertebrates 8-58
8.4.1 Introduction 8-58
8.4.2 Class I Methods 8-58
8.4.3 Methods Integration 8-66
8.4.4 Examples 8-68
8.4.5 References 8-70
8.5 Terrestrial Invertebrate Surveys 8-73
8.5.1 Introduction 8-73
8.5.2
9 DATA INTERPRETATION 9-1
By: D. Stevens, G. Under, W. Warren-Hicks
9.1 Causality 9-1
9.2 Uncertainty 9-3
9.3 ANalysis and Display of Spatial Data 9-5
9.3.1 PointMethods 9-5
9.3.2 Surface Methods 9-8
9.4 Data Analysis and Interpretation Case Studies 9-14
9.4.1 Rocky Mountain Arsenal 9-14
9.4.2 Comparative Toxicity Assessment 9-15
9.4.3 Small Mammal Assessment 9-18
9.4.4 Mutagenesis Assessment 9-19
9.5 References 9-23
Appendix A: List of Workshop Attendees A-l
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LIST OF TABLES
Table Title Page
2-1 Characteristics of Good Assessment Endpoints 2-5
2-2 Characteristics of Good Measurement Endpoints 2-8
2-3 Potential Assessment Endpoints 2-12
2-4 Potential Measurement Endpoints 2-18
3-1 Advantages and Limitations of Toxicity Tests in
Ecological Assessments 3-8
3-2 Advantages and Limitations of Microbial Studies in
Ecological Assessments 3-10
3-3 Advantages and Limitations of Biomarkers
in Ecological Assessments 3-12
3-4 Advantages and Limitations of Field Surveys
in Ecological Assessments 3-14
3-5 Recommended Approaches for Addressing Key Questions
for Ecological Assessments at Hazardous Waste Sites 3-15
4-1 Multipliers of 2(s/d)2 for Determination of Sample Size 4-12
6-1 EC50 Response of Percent Inhibition Caused by Chemical
Contaminants in Rocky Mountain Arsenal Soil Elutriate,
Wastewater, and Ground Water Samples 6-39
8-1 Methods for Measuring Physical and Chemical Variables 8-9
8-2 Sampling Methods for Macroinvertebrates 8-15
8-3 Sampling Methods for Fish 8-20
8-4 Generic Negative Impacts of Hazardous Materials on Plants
That Influence Vegetational Characteristics 8-41
8-5 Estimated Minimal Area for Each Relevee Survey
for Selected Vegetation Types 8-47
8-6 Modified Braun-Blanquet Cover Class Ranges 8-47
8-7 Braun-Blanquet Plant Sociability Classes 8-47
9-1 EC50 Response in Soils (Earthworm), Soil Elutriate, and Surface
Water to Chemical Contaminants in Western Processing Samples 9-18
9-2 Chromosome Aberrations in Peromyscus leucppus from
One Field Site (FS) and Two Control Sites (CSl and CS2) as
Assessed by Standard Metaphase Chromosome Preparations 9-20
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LIST OF FIGURES
Figure Title Page
5-1 The DQO three-stage process 5-4
6-1 Battery of single-species bioassays for various types
of environmental samples 6-28
6-2 Considerations in hazard assessment 6-37
9-1 A comparison of percent toxicity and percent
reduction of the taxa 9-3
9-2 Sunflower technique for displaying clusters of data points 9-6
9-3 Hexagonal binning technique for displaying clusters
of data points 9-7
9-4 Ozone and meteorology data 9-8
9-5 Example glyph plot 9-9
9-6 Example data depiction using Thiessen polygons 9-11
9-7 Estimated lettuce seed mortality (Based on Kriging) for
the 0-15 cm soil fraction from the Rocky Mountain Arsenal 9-16
9-8 Normal geimsa stained standard karyotypes of a. Peromyscus
leucopus,female,2n = 48;b.Sigmodonhispidus,male,2n = 52 ... 9-21
9-9 Representative chromosomal aberrations detected in standard
metaphase chromosomal preparations of Peromyscus leucopus
and Sigmodon hispidus from one field site (FS) and two control
sites (CSl and CS2) 9-22
IX
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CHAPTKR1
INTRODUCTION
1.1 PURPOSE
This document has the following purposes: (1) to discuss the scientific basis for
assessing adverse ecological effects at hazardous waste sites iHWSs), and (2) to
present methods for evaluating the on-site and off-si to ecological effects of HWSs.
The methods are intended for implementation in the early phases of the HWS
evaluation process and should be used as integral parts of HWS evaluations. This
document is intended for use by administrative and scientific personnel with a strong
background in the environmental sciences, including laboratory and field procedures,
and environmental assessment strategies.
1.2 BACKGROUND
A high priority of the U.S. EPA is to identify, characterize, and cleanup HWSs. These
activities are regulated by the Comprehensive Environmental Response
Compensation and Liability Act (CERCLA), as amended by the Superfund
Amendment and Reauthorization Act of 1986 (SARA). Both CERCLA and SARA
address the toxic effects of hazardous wastes to aquatic and terrestrial organisms;
consequently, environmental toxicity is one of the principal characteristics used to
identify and characterize HWSs. Many of the methods presented in this document
have been adapted from toxicity-based approaches to environmental assessment.
The toxicity-based approach was developed for measuring and assisting in the
regulation of toxic complex effluents discharged to surface waters (U.S. EPA 1985).
It has also been used to identify and characterize toxic wastes under regulations
enforced by the Resource Conservation and Recovery Act (RCRA) of 1976 as amended
(Millemann and Parkhurst 1980). While site-specific characteristics may influence
the assessment strategy at a HWS, the potential list of "appropriate, relevant, and
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applicable regulations" (ARARs) in force under CERCLA and SARA could provide a
basis for selecting methodologies applicable to a given site, particularly if mandated
through legislation (e.g., Clean Water Act, Endangered Species Act and the Safe
Drinking Water Act).
Three types of information are needed to establish a firm, causal relationship
between toxic wastes and ecological effects. First, chemical analyses of the
appropriate media are necessary to establish the presence, concentrations, and
variabilities of specific toxic chemicals. Second, ecological surveys are necessary to
establish that adverse ecological effects have occurred. And finally, toxicity tests are
necessary to establish a link between the adverse ecological effects and the toxicity of
ihe wastes. Without all three types of data, other potential causes of the observed
effects unrelated to the toxic effects of hazardous wastes, such as habitat alterations
and natural variability, cannot be eliminated. For the following reasons, confidence
in cleanup and monitoring decisions is greatly enhanced when based on a
combination of chemical, ecological, and toxicological data:
• Ecological and toxicological data can be used to assess the aggregate toxicity of
all toxic constituents at an HWS.
• The bioavailability of toxic chemicals is measured with ecological and
toxicological assessments, but not with chemical analyses; therefore, the use of
chemical data alone may over or underestimate the toxicities of single
chemicals.
• Ecological and toxicological assessments link chemical-specific toxicity with
measured biological responses, thereby providing a realistic assessment of
environmental effects.
• Ecological and toxicological assessments provide information on the
magnitude and variation of toxic effects, which may be useful in cleanup and
monitoring strategies.
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1.3 DEFINITION OF AN ECOLOGICAL ASSESSMENT
The objective of an ecological assessment is to quantify the ecological effects
occurring at an HWS. In this document, ecological effects refer principally to
population- and community-level effects on terrestrial and aquatic biota and
biological processes. The magnitude and extent of ecological effects are measured
based on a select set of ecological endpoints that are considered reasonable indices of
the status of biological populations and communities on and near HWSs.
The expected outputs from an ecological assessment include the following:
• A basic inventory of the current status of selected components of the biological
community in the area.
• An estimate of the current level of ecological effects associated with the HWS
based on the selected subset of ecological endpoints.
• An estimate of the magnitude and variation of toxic effects.
• To the degree possible, identification of the extent to which these effects have
resulted specifically from the presence of hazardous and toxic chemicals, as
opposed to other associated effects such as habitat disruption.
Outputs not expected from an ecological assessment include the following:
• Predictions of future ecological effects at the HWS.
• An assessment of risk, although the data generated will be a useful component
of an environmental risk analysis.
• Analyses specific to optimizing the design of remedial actions, assessing
potential effects on human health, and evaluating the fate and transport of
hazardous wastes. However, the data generated from an ecological assessment
may contribute significantly to such analyses.
• Comprehensive ecological studies or research investigations. Ecological
assessments of HWSs will focus on selected ecological endpoints.
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Ecological assessments are a single component of an HWS evaluation. Other studies
at the site include chemical analyses to establish the occurrence and distribution of
potentially hazardous substances in the environment, models that predict the fate
and transport of chemical substances at the site, and assessments of the threat to
human health. The assessment methods presented in this section should be
integrated with these analyses as part of the HWS evaluation process.
1.4 CKITKKIA FOR METHODS SELECTION AND PRESENTATION
Some of the methods presented in this document are well developed, widely accepted
procedures while others are less standard. This discrepancy is due, in part, to a
differing amount of scientific research in methods development within specific
environmental areas. For example, methods of toxicity assessment in freshwater
systems are well developed while methods of toxicity testing in terrestrial systems
are less well developed. To reflect the present state-of-the-science, the laboratory and
field methods presented in this document are categorized into two classes, I and II.
Class I methods represent standardized off-the-shelf methods, i.e., ones that have
been extensively researched and validated for use in environmental assessments. In
most cases, a large body of existing information is available documenting the ability
of the test results to confirm the existence of adverse ecological effects. Class II tests
represent test methods that are still under development, but which may be applicable
to specific environmental situations at an HWS. Class II methods have not
undergone the amount of standardization and validation associated with Class I
methods. However, Class II methods should not be considered inferior methods.
They may be the procedures of choice for site-specific evaluations or may be the only
methods available at this time. Within this document, the advantages and
disadvantages of Class I and Class II methods are presented, where appropriate.
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Step-by-step details are not included for conducting the methods presented in this
document. Rather, specific tests and procedures are recommended, and selected
references are provided. The reader should consult the reference(s) for specific,
detailed guidance on implementing a desired procedure. In addition, information
useful for selecting a specific method, the expected outputs from the method, and the
strengths and weaknesses of the method are discussed, where appropriate.
The methods presented in this document can be implemented within a time frame of
12 to 18 months. Methods requiring longer periods of time were not included. Given
that environmental conditions vary greatly among sites, the selected methods are
sufficiently flexible to permit implementation at most sites.
This document should be used in conjunction with the Superfund Environmental
Evaluation Manual, currently under development by the U.S. EPA Office of Solid
Waste and Emergency Response (OSWER). The reader is directed to the OSWER
document for further guidance on the role of ecological assessment within the
Superfund program. Additionally, other federal agencies have developed summary
documents which may be relevant to HWS evaluation on a site-specific basis (U.S.
FWS 1987).
1.5 ORGANIZATION OF THE DOCUMENT
This document is a field and laboratory reference document that provides guidance on
designing, implementing, and interpreting an ecological assessment. It is comprised
of nine chapters that address the following subjects: (1) the introduction, (2)
evaluation and selection of appropriate ecological endpoints, (3) basic strategies and
approaches to ecological assessments, (4) considerations in field sampling design, (5)
the role of quality assurance and quality control in HWS evaluations, (6)
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recommended aquatic and terrestrial toxicity tests, (7) recommended biomarkers, (8)
recommended aquatic and terrestrial field survey methods, and (9) considerations in
data analysis and interpretation.
Each chapter in this document presents a discussion of issues and methods related to
designing, implementing, and interpreting ecological assessments of hazardous
waste sites. The authors of each of these chapters presented their papers at a
workshop held in Seattle, WA on July 25-27, 1988. Workshop participants are
presented in Appendix A. During the workshop, the material contained in this
document was presented and discussed, and many of the comments received during
the workshop have been incorporated. As new information on ecological assessment
becomes available, new techniques undoubtedly will be developed. The methods and
recommendation presented in this document will, as a consequence, be revised.
1.6 REFERENCES
Millemann, R.E., and B.R. Parkhurst. 1980. Comparative toxicity of solid waste
leachates to Daphnia magna. Environ. Internet. 4:255-260.
Public Law 94-580. 1976. Resource Conservation and Recovery Act (RCRA), as
amended.
Public Law 96-510. 1980. Comprehensive Environmental Response, Compensation,
and Liability Act (CERCLA), as amended.
Public Law 99-499. 1986. Superfund Amendment and Reauthorization Act (SARA),
as amended.
U.S. Department of Interior. 1987. Type B Technical Information Document. Injury
to Fish and Wildlife Species. CERCLA Project 301. Washington, DC.
U.S. Environmental Protection Agency. 1985. Short-Term Methods for Estimating
the Chronic Toxicity of Effluents and Receiving Waters to Freshwater Organisms.
EPA/600/4-85/014, Environmental Monitoring and Support Laboratory, Cincinnati,
OH. 162pp.
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U.S. Environmental Protection Agency. In preparation. Superfund Environmental
Evaluation Manual. Office of Solid Waste and Emergency (OSWER), Washington,
DC.
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CHAPTER2
ECOLOGICAL ENDPOINTS
By
Glenn W. Suter II, Environmental Sciences Division,
Oak Ridge National Laboratory, Oak Ridge, TN.
2.1 INTRODUCTION
The purpose of ecological assessment of hazardous waste sites is to provide input to
the decision making processes associated with a broad range of applications including
site prioritization, waste characterization, site characterization, cleanup or
remediation assessment, and site monitoring. The results of the ecological
assessment that constitute the input to the decision making processes are
descriptions of the relationship of pollutants to ecological endpoints. If the ecological
endpoints are not compelling, they will not contribute to the decision. This chapter
describes two different types of endpoints, presents criteria for judging endpoints,
presents classes of endpoints that are potentially useful in assessments of waste sites,
judges them by the criteria, and discusses how the nature of the assessment problem
affects endpoint choice.
2.2 TYPES OF ENDPOINTS
Some confusion may occur in the practice of environmental assessment because the
term endpoint has been used to describe two related but distinct concepts. To avoid
this confusion, the following paragraphs distinguish assessment endpoints from
measurement endpoints.
Assessment endpoints are formal expressions of the actual environmental values
that are to be protected. Ecological assessments, as defined in this document, are
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concerned with describing the existing effects of a hazardous waste site on the
environment. Therefore, the assessment endpoints are environmental
characteristics, which, if they were found to be significantly affected, would indicate
a need for remediation.
Assessment endpoints must be valued, but they are not ultimate values. Rather,
they are the highest values that can be objectively assessed. Ultimate values fall in
the domain of risk management, where ecological and human health assessment
results are considered along with political, legal, economic, and ethical values to
arrive at a plan for remediation.
A measurement endpoint is a quantitative expression of an observed or measured
effect of the hazard; it is a measurable environmental characteristic that is related to
the valued characteristic chosen as an assessment endpoint. In some cases, the
measurement endpoint may be the same as the assessment endpoint. If the
assessment endpoint for a waste site is decreased abundance of green sunfish in a
stream adjoining the site, then abundance of the sunfish can be measured and related
to abundance in reference sites. Because some potential assessment endpoints are
not observable or measurable, and because assessments are often limited to using
available of standard data, measurement endpoints are often surrogates for
assessment endpoints. For example if the assessment endpoint is reduced production
of green sunfish in the stream due to toxic effects of the leachate, productivity can not
be measured in the time allotted to a typical field study and toxic effects can not be
reliable separated in the field from other effects on productivity. In that case, toxicity
test endpoints are appropriate but they are likely to be standard EPA test endpoints
such as a fathead minnow LC50 for the leachate. When the measurement endpoint is
not the same as the assessment endpoint, then some model must express the
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relationship between the two. It may be as simple as: a fish is a fish and so fathead
minnows can simulate green sunfish, and population production would probably be
affected at the LC50. More sophisticated assessments might use a fathead minnow to
green sunfish extrapolation model or a green sunfish population model to relate the
measurements to the assessment endpoint.
Measurement endpoints may be measured in the field or laboratory. Field
measurements from monitoring or survey programs indicate what effects are
occurring on a site. Laboratory measurements can be used to predict field effects or to
provide evidence of causality for observed field effects. Measurement endpoints are
typically simple statistical or arithmetic summaries of the measurement results.
Examples are the LC50, a point on a regression line fitted to concentration-response
data, and the relative abundance measures derived from field survey data.
In an unfortunately large number of monitoring programs, there are measurement
endpoints, but the assessment endpoints are not clearly defined. In effect, the
assessment endpoints are: "Are the things that we are measuring changing?" or "Are
the things that we are measuring different on and off the site?" Without a better
definition of why measurements are being taken, time and effort are wasted. If one
monitors any aspect of the environment long enough, change will be seen; and if any
two sites are sampled intensively enough, they will be found to differ. Minute
changes or differences may be statistically significant but not environmentally
significant. A clearly defined assessment endpoint not only indicates what is worth
measuring, but also how intensively it must be measured.
The remainder of this document is concerned with the various sorts of measurements
that can be performed for ecological assessments of hazardous waste sites. The
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purpose of this chapter is to make the assessor aware of the need to decide what is
being assessed (i.e., to chose explicit assessment endpoints) before deciding what to
measure.
This document does not describe methods for performing risk assessments. That is, it
is not concerned with prediction of future effects or with optimization of the remedial
actions. However, if the Superfund process proceeds beyond the activities described
in this document, the effects of alternate remedial actions will have to be predicted
and the remedial design selected in part on these predictions. If the measurements
made for the ecological assessment are to be useful in this risk assessment and risk
management process, then the assessment and measurement endpoints should be
selected so as to be useful for prediction and relevant to the selection of remedial
actions. Otherwise effort will have been wasted and the risk assessment will be
impeded or impaired.
2.3 CRITERIA FOR ENDPOINTS
2.3.1 Assessment Endpoints
Criteria for a good assessment endpoint are listed in Table 2-1. First, an assessment
endpoint should have social relevance; that is, it should be an environmental
characteristic that is understood and valued by the public and by decision makers. In
ecological assessments, the most appropriate endpoints often are effects on valued
populations such as crops, trees, fish, birds, or mammals. This is not to say that
species and other environmental attributes that are not publicly valued or
understood have no place in ecological assessment. Rather, if species that are not
socially valued are particularly susceptible, then their link to valued species or other
valued environmental attributes must be explicitly demonstrated.
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Table 2-1. Characteristics of Good Assessment Endpoints
Social relevance
Biological relevance
Unambiguous operational definition
Measurable or predictable
Susceptible to the hazard
Logically related to the decision
It is desirable that the assessment endpoint have biological relevance. The biological
significance of an effect is a function of its implications for the next higher level of
biological organization. For example, the significance of infertility of individuals is
determined by the resulting population reduction, and the significance of the loss of a
major grazing species is determined by the ability of other grazers to functionally
substitute for the lost species, thereby sustaining the community structure.
Biomarkers are biologically significant if they indicate that individuals are being
affected. However, some markers are also a part of adaptation to varying
environmental conditions, which may have no long-term implications for whole
organism performance. Biological significance may not correspond to societal
significance. The abundance of peregrine falcons has clear societal significance and
is a worthy assessment endpoint on that basis, but has no apparent biological
significance.
Assessment endpoints should have unambiguous operational definitions so that they
can be related to measurements. Phrases such as "ecosystem integrity" and
"balanced indigenous populations" reflect concerns for a good natural environment.
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Although they are suitable concepts for contemplation by the risk manager, they are
not suitable subjects for assessments because they can not be measured or modeled
from any measurement. Without well-defined endpoints, the ecological assessment
will not provide useful insight for environmental decisions associated with the
hazardous waste site. A complete operational definition of an assessment endpoint
requires a subject (e.g., bald eagles or endangered species in general) and a
characteristic of the subject (e.g., local extinction or a percentage reduction in range).
Assessment endpoints should be measurable or predictable from measurements.
Assessment requires toxicity tests and statistical models for summarization and
extrapolation of test results, measurements of responses of similar systems to similar
hazards, or mathematical models of the response of the system to the hazard. An
endpoint that cannot be tested, measured, or modeled cannot be assessed except by
expert judgment. For example, responses of fish are good assessment endpoints
because fish population and community characteristics are easily measured in the
field, routine toxicity tests are available, and models are available to relate
laboratory test species in the field.
The assessment endpoints chosen for a particular assessment must be susceptible to
the hazard being assessed. Susceptibility results from a potential for exposure and
responsiveness of the organisms or other entities to the exposure. In some cases,
susceptibility will be known in advance because it prompted the assessment. In other
cases, where a novel hazard is involved, or the causal linkage between the putative
hazard and the observed damage is unclear, establishing susceptibility will be a goal
of the assessment. This criterion is obviously situation-specific and will not be
discussed further.
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Finally, the assessment endpoints should bear some logical relationship to the
environmental decisions of concern. For example, rates of soil processes may be
considered as an assessment endpoint, but what does a decreased carbon
mineralization rate mean when the potential remedial actions are capping the soil or
incinerating it? In contrast, effects of leachate from the soil on aquatic communities
are relevant.
Seriousness of effects has been mentioned in other discussions of endpoints (e.g., AMS
1987), but is excluded here as inappropriate. This criterion includes severity,
reversibility, and extent. If an endpoint has societal and biological significance, then
it should not be excluded simply because more serious effects are possible. Rather,
both serious but low probability endpoints and less serious but potentially high
probability endpoints should be assessed so that they can be considered and balanced
in the risk management process.
2.3.2 Measurement Endpoints
Criteria for a good measurement endpoint are listed in Table 2-2. A measurement
endpoint must correspond to or be predictive of an assessment endpoint. The
environmental sciences literature is replete with examples of traits that were
measured in the laboratory or field, but which could not be explicitly translated into a
societally or biologically important environmental value. If the endpoint of a
measurement does not correspond to an assessment endpoint, it should be correlated
with an assessment endpoint, or should be one of a set of measurement endpoints that
predict an assessment endpoint through a statistical or mathematical model. If this
is not possible, then the measurement endpoint or suite of measurement endpoints
should be protective; that is, they should be so sensitive and inclusive of the
hazardous processes on the site that if they are not affected, nothing will be affected.
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Table 2-2. Characteristics of Good Measurement Endpoints
Corresponds to or is predictive of an assessment endpoint
Readily measured
Appropriate to the scale of the site
Appropriate to the exposure pathway
Appropriate temporal dynamics
Low natural variability
Diagnostic
Broadly applicable
Standard
Existing data series
Measurement endpoints must be readily measurable. That is, it should be possible to
quickly and cheaply obtain accurate measurements using existing techniques and
personnel.
Measurement endpoints must be appropriate to the scale of the pollution, physical
disturbance, or other hazard. It would be inappropriate to use the productivity of a
deer population to assess the effects of a 1-hectare waste site, but it might be
appropriate to use this index for a large complex of waste sites.
Measurement endpoints must be appropriate to the exposure pathway. The
organisms or communities that are measured should be exposed to the polluted media
and should have the same routes of exposure in approximately the same proportions
as assessment endpoint organisms or communities. When such matching is not
possible, then organisms that have the highest exposure should be used. For
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example, at sites where soil is contaminated, burrowing rodents have higher
exposures than rodents that use surface runs and nests (McBee 1985).
Measurement endpoints should have appropriate temporal dynamics. If the hazard is
episodic, then the measured response should be persistent so that evidence of effects
will still be apparent after the event. For example, fish kills are apparent after
pollution episodes, but behavioral responses tend to recover rapidly. Waste sites are
generally thought of as sources of chronic exposure, but acute exposures may result
due to spills (e.g., drum failures, overflowing sumps, or flushes of leachate following
storms) and to movement of leachate to or near the surface (e.g., rainwater filling old
sumps or waste trenches and creating "bathtubs" of leachate in the slumped surface).
Also, stress markers (physiological indicators of stress) should not respond so rapidly
that they increase due to the stress of capture.
Measurement endpoints should have low natural variability. Responses that are
highly variable among individuals or across space and time are difficult to interpret
when used to measure pollution effects. As a result, either the effects are masked or
large numbers of replicates must be used. For example, fecundity is more sensitive to
most pollutants than mortality in fish, but fecundity is highly variable among
individual females, so fecundity effects are hard to distinguish in toxicity tests (Suter
et al. 1987). The importance of variability depends on the relative scales of the
variance and the measurements. For example, most pollution effects studies address
effects on the scale of years, so diurnal variance is irrelevant, and variance due to
climatic trends on the scale of hundreds to thousands of years is not detected.
It is desirable for measurement endpoints to be diagnostic of the pollutants of
interest, to the extent that they have been identified. For example, concentrations of
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adrenal corticoids are indicators of stress in general; DNA single-strandedness is
indicative of genotoxins; and DNA adducts of benzo[a]pyrene (BAP) are indicative of
DNA damage by BAP (DiGiulio, this volume; McCarthy et al. in press).
It is desirable for measurement endpoints to be broadly applicable to allow
comparison among sites and regions. For example, armadillos are probably good
monitors of soil pollutants because they burrow and feed on soil and litter
invertebrates. However, they occur in a small portion of the United States, whereas
mice of the genus Peromyscus are ubiquitous.
Measurement endpoints should be standardized to assure precise, replicable results
and to permit interpretation of results in terms of previously reported effects.
Methods that have been standardized for toxicity testing or monitoring fulfill both of
these needs. Methods that are standard in research or in some applied field other
than toxicology (e.g., nitrification rates) fulfill the need for replicable results, but are
difficult to interpret because there is no data base of toxic effects. Standard methods
and endpoints for toxicity testing are readily available for a variety of aquatic
organisms, for some terrestrial animals, for a few plant responses, and for a few
microcosms and mesocosms. Sources include the American Society for Testing and
Materials (ASTM), American Public Health Association (APHA), Organization for
Economic Cooperation and Development (OECD), and U.S. Environmental
Protection Agency (EPA). Standard methods for measuring pollutant concentrations
in the environment are available from the same organizations. Methods for
monitoring biota are much less standardized, and the few existing standards (e.g.,
APHA 1985, ASTM 1987) are not as widely used.
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Finally, it would be desirable to use an endpoint that is already being measured so
that there is a baseline from which to estimate background levels, variability, and
trends. There is the additional advantage that data from an ongoing monitoring or
testing program is free. This is seldom possible for waste sites, but there are areas,
such as federal reservations, where biological monitoring precedes a CERCLA
assessment.
2.4 POTENTIAL ASSESSMENT ENDPOINTS
Potential assessment endpoints for ecological risk assessments are listed in
Table 2-3. They are arranged in terms of the standard ecological hierarchy, but the
levels are not distinct. Endpoints are listed in the lowest hierarchical level to which
they are appropriate. For example, massive mortality is listed under population, but
can also occur within a community or region. The listed assessment endpoints are
actually classes of endpoints; an endpoint for a real assessment would specify an
entity and characteristic (e.g., kills of more than 100 fish of any species). Even at this
level of generality, any list of endpoints will be incomplete. Anyone can imagine
other assessment endpoints that may be useful in specific cases. The listed endpoints
were chosen to have generic utility.
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Table 2-3. Potential Assessment Endpoints
I. Population HI. Ecosystem
Extinction Productive capability
Abundance
Yield/production
Age/size class structure
Massive mortality
n. Community IV. Human health concerns
Market/sport value Contamination
Recreational quality Gross morbidity
Change to less useful/desired type
2.4.1 Population
Population-level assessment endpoints are generally the most useful in local
assessments because (1) responses at lower levels (i.e., organismal and
suborganismal) maybe perceived as having less social or biological significance
(actions may be taken to protect individuals of endangered species but only because it
is prudent in light of the precarious state of the population), (2) populations of many
organisms have economic, recreational, aesthetic, and biological significance that is
easily appreciated by the public, and (3) population responses are well-defined and
more predictable with available data and methods than are community and
ecosystem responses. The remainder of this discussion will refer to populations of
socially or biologically important species.
The most drastic population-level effect is extinction; it is well-defined and
potentially has great societal and biological significance. It can be predicted with
good success if the hazard is habitat loss and with moderate success if the hazard is
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toxic effects. Extinction can be monitored with relative ease for conspicuous species,
and, on the scale of a typical waste site, it can be readily monitored for almost any
macroscopic species. Anthropogenic local extinctions are relatively common as a
result of direct toxic effects, loss of habitat, loss of competitive ability with more
resistant species, or other indirect causes.
Yield, abundance, and production are expressions of the ability of a population to
fulfill a biological or resource role. If the yield (e.g., harvestable production) of a
resource population such as timber trees or sport fishery declines, the societal
significance is readily apparent. Abundance of nonresource species also has societal
importance if the species is missed. The biological significance of both abundance
and production may be large or small depending on the role of the species and its
natural variability. These attributes are well-defined. Although techniques exist to
predict these quantitative population responses, their reliability is not well
established. Effects of habitat modification on wildlife can be predicted using the
U.S. Fish and Wildlife Service's habitat evaluation procedure (Division of Ecological
Services 1980) and effects of pollutants can be predicted by applying the effects
observed in toxicity tests to population models (Barnthouse et al. 1987, and in press).
These effects are easily measured for many species, but variance is often high.
Population-level endpoints are appropriate to waste site assessments when
(1) individuals of a valued species occur on the site in communities receiving effluents
from the site, or formerly occurred on the site in receiving communities, (2) those
individuals are or were potentially exposed to waste chemicals, and (3) death or
injury of those individuals are believed to cause significant effects on the population
as a whole.
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2.4.2 Community
Changes in the character of a biotic community can have major societal implications.
If the market or sport value of a community changes, such as when a trout stream
changes to a stream supporting only acidophilic bacteria due to acid leachate from
mining waste, the societal implications are evident. Similarly, community changes
such as severe eutrophication (possibly due to leaching of high phosphorous wastes)
can diminish the recreational value of the community. There is a large body of
literature on the economic value of recreation (Economic Analysis, Inc. 1987).
Changes of community type that do not directly involve commercial, sport, or
recreational values are also likely to be regarded as changing the utility or
desirability of the community. However, the definition of what constitutes a
significant negative change in a community type is often ambiguous. A moderate
increase in the trophic status of a lake may increase production of desirable fish
species, but diminish its value for swimming, boating, and aesthetic enjoyment,
particularly for an oligotrophic lake.
Changes in community type are likely to have biological significance because large
numbers of species and large areas are potentially involved. However, whether a
change is biologically significant depends on the particular change and the
community function under evaluation. For example, conversion of a mixed forest to a
mowed grassland would decrease the movement of waste chemicals to the surface by
plant roots but would decrease habitat for wildlife. It would also affect local
hydrology by decreasing summer transpiration and increasing runoff.
Endpoints for most significant community transformations can be given good
operational definitions. Examples include the conventional classification of lake
trophic status and classifications of vegetation types.
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Prediction of local community changes due to physical disturbances (e.g., converting
a forest to lawn, or dredging a stream) is a trivial assessment problem. Effects on
communities of additions of nontoxic pollutants (e.g., organic matter and nutrients
from sludges) are reasonably predictable in aquatic systems, and there is a growing
body of information on sludge and waste water disposal in terrestrial systems that
can provide a basis for prediction. Effects of toxic chemicals on communities are not
directly predictable. They can be inferred from information on toxicity to component
taxa and knowledge of the relationship between taxa (O'Neill et al. 1982, West et al.
1980), but there is insufficient experience with this approach to evaluate its
predictive power for community transformations. Microcosms and mesocosms are
alternate means of assessing toxic effects in communities.
Community transformations that take the form of changes in vegetation are easily
measured from ground surveys or aerial images. Changes in terrestrial animal
communities and in aquatic communities require greater effort in sampling or
observation, but present no conceptual problems.
Community-level endpoints are applicable to waste site assessments when a valued
community exists on the site or receives effluent from the site and when the affected
portion of the community is a significant portion of the entire community.
2.4.3 Kcosystem
The only ecosystem property that is generally useful for waste site assessment is
productive potential. If productive use of the site is an option, then it is reasonable to
consider the potential productivity of the site with and without remediation. This
endpoint has social and biological significance and can be operationally defined if a
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future use is specified. It can be reasonably predicted either from the effects of the
waste on production and estimates of the rate of loss of toxic chemicals from the
system (assuming no restoration) or from the alternate restoration plans.
Productivity is logically related to the decision. However, because remediation
activities such as dredging streams, removing soil and vegetation, installing caps,
and establishing a mowed grassland tend to reduce the productivity of a site,
productivity considerations would often tend to be an argument against remediation.
2.4.4 Human Health Concerns
Contamination of populations by pollutants has societal significance if the organisms
provide human food. This endpoint is well-defined by the FDA action levels.
Contamination is readily predicted for aquatic organisms from concentrations in
water and is relatively straightforward for terrestrial plants, but the complexity of
exposure in terrestrial wildlife (food, water, air, and soil can all be important) makes
prediction of body burdens very difficult.
The frequency of gross morbidity (tumors, lesions, and deformities) is societally
significant because the public has come to interpret them as signs of pollution that
may constitute a health threat, but they have little biological significance per se.
Gross morbidity is not presently predictable, although deformities are observed in
reproductive toxicity tests. Gross morbidity is readily measured because the
conditions persist and can be evaluated by inspection of a sample of organisms.
2.5 MEASUREMENT ENDPOINTS
Potential measurement endpoints for waste site assessments are listed in Table 2-4.
As with the assessment endpoints, these are general classes of endpoints. For
example, actual measurement endpoints for individual mortality include median
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lethal concentration (LC50), the threshold for mortality in a cohort (LC01), the no
observed effect level (NOEL) for mortality, and the number of dead individuals
observed following a pollution episode. It is more difficult to generalize about the
utility of measurement endpoints because the ability to measure an environmental
characteristic and its relation to the spatial, temporal, and other characteristics of
the hazard are situation-specific.
2.5.1 Individual
The endpoints of nearly all toxicity tests are statistical summarizations of the
responses of individual organisms. For example, the LC50 is a statistical estimate of
the concentration at which the median individual dies. Death, reproduction, and
growth can be related to population-level assessment endpoints by using population
models based on the survival and reproduction of individuals (Barnthouse et al. 1987,
and in press) and to population and ecosystem endpoints by using ecosystem models
(O'Neill et al. 1982, Bartell et al. 1987). Conventional laboratory tests are easily
conducted, have reasonably low variability, are broadly applicable, are highly
standardized, and can have appropriate temporal dynamics. Because exposure and
other conditions are controlled, diagnostic effects are not needed. While the use of
more than one test is advocated, it is important to select tests that relate to exposures
on the site rather than using a battery of tests that are quick and convenient (e.g.,
Porcella 1983). For example, Daphnia tests of soil leachate when it is not polluting
surface water or earthworm tests of desert soils provide no evidence concerning the
magnitude or nature of ecological effects. Tests of plants and aquatic organisms
typically have appropriate modes of exposure, but wildlife dosing or dietary tests are
difficult to relate to wildlife exposure at most waste sites.
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Table 2-4. Potential Measurement Kndpoints
Individual
Death
Growth
Fecundity
Overt symptomology
Biomarkers
Tissue concentrations
Behavior
Population
Occurrence
Abundance
Age/size class structure
Reproductive performance
Yield/production
Frequency of gross morbidity
Frequency of mass mortality
Community
Number of species
Species evenness/dominance
Species diversity
Pollution indices
Community quality indices
Community type
Ecosystem
Biomass
Productivity
Nutrient dynamics
Overt symptomology (visible effects such as spinal deformities in fish and chlorosis of
plant leaves) and biomarkers (biochemical, physiological, and histological indicators
of exposure or effects) are potentially diagnostic and measurable in field-collected
organisms. Handbooks are available for attributing visible plant injury to specific
air pollutants (Jacobson and Hill 1970; Malhotra and Blauel 1980). Overt
symptomology and biomarkers, as well as behavioral responses, currently cannot be
used to predict assessment endpoints even though they have clear implications for
the health of organisms. There are currently no quantitative models that relate
symptoms or biomarkers to higher-level effects. However, many biomarkers are
diagnostic of exposure to particular classes of chemicals (e.g., metallothioneins for
metal exposure) or for specific chemicals (e.g., DNA adducts of specific mutagenic
chemicals) (DiGiulio, this volume; McCarthy et al. in press). In addition, tissue
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concentrations of accumulated chemicals are diagnostic of exposure to those
chemicals, and, for most metals and some other chemicals, body burdens associated
with effects are available in the literature. Both overt symptomology and tissue
concentrations can be related to human health concerns. The variance of overt
symptoms, biomarkers, and tissue concentrations depends on the chemical, marker,
or symptom being measured. Only the methods for measuring tissue concentrations
have been standardized.
Behavioral responses are difficult to measure in the laboratory and are even more
difficult to measure in the field. They are not diagnostic or standardized, and, except
for avoidance of the pollutant, tend to be difficult to interpret.
2.5.2 Population
The conventional population parameters (occurrence, abundance, age structure,
birth and death rates, and yield) are poor subjects for laboratory tests, but are
popular components of ecological field studies. They are directly interpretable in
terms of assessment endpoints for valued populations. Occurrence and abundance
are easily measured, but age structure is difficult to establish for many species. Birth
rates, death rates, and yield are difficult to establish for many species (excluding
annual plants) in short field studies. The scale of population responses is appropriate
for very large waste sites or for populations with small ranges. Otherwise, movement
of individuals and propagules onto or off of the site will obscure effects. In some cases,
the waste site will constitute a habitat island with distinct populations, in which case
the populations are automatically scaled to the site. Population responses have good
temporal dynamics in that they integrate chronic and acute exposures. Their
variability depends on the species. They are not diagnostic, however, and the
requirement of a valued species on the site limits the applicability of population-level
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endpoints. Methods for population surveys are not standardized, but there are
generally accepted methods applicable to most species.
The frequency of mass mortalities, and the frequency and nature of overt morbidity
correspond to assessment endpoints. Overt morbidity is readily measured in the field
for most vertebrates; however, mass mortalities are unlikely to occur during a field
survey, so local residents or agencies must be the source of data. Frequencies of overt
morbidity are quite variable and care must be taken in diagnosis of lesions and
tumors to distinguish effects of toxicants from those of parasites and mechanical
injury. These endpoints are not standardized and, with the possible exception offish
kills, are unlikely to be interpreted through the use of existing data.
2.5.3 Community
The most commonly used community characteristics in environmental monitoring
are the number of species, species evenness, and species diversity. They are popular
because they conveniently summarize the data generated by biotic surveys. They are
easily measured, appropriate to the scale of the site, and they temporally integrate
acute and chronic exposures. For most macroscopic flora arid fauna, they have
reasonably low variance, but the evenness and diversity of invertebrates tend to be
high. They are broadly applicable, but not diagnostic or well standardized; some
standard methods for community sampling exist (APHA 1985, ASTM 1987).
The problem comes in relating these numbers to assessment endpoints. If the nature
and aspect of the community has not been affected, then changes in number,
evenness, and diversity must be interpreted in terms of the species that have
appeared, disappeared, or changed in relative abundance as a result of the presence of
the waste. In other words, the assessment must shift to the population level because
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the number and diversity of species is no longer believed to confer stability or any
other biological value (Goodman 1975). Certainly, the increase in species number
and diversity that results from colonization of disturbed areas by weedy species is not
valued or of great consequence. If the nature and aspect of the community has been
changed by the presence of the waste, then number, evenness, and diversity numbers
are simply adjuncts to the description of the changed community type. In many
cases, intensive sampling and data summarization will not be necessary to describe
community changes. A quick survey can establish that contaminated soils are
entirely or nearly devoid of vegetation or that a stream draining a waste site is
barren of macroorganisms. Although they are not sensitive, such descriptions of
gross community changes are clearly good measurement endpoints where they are
applicable.
Another type of community-level endpoint is the index of community quality, which
may be indicative of pollution effects or of habitat quality in general. The best
example of a community pollution index is the saprobic index (Hynes 1960). This
index arrays aquatic communities with respect to conventional organic pollution (i.e.,
sewage and similar effluents) which predictably replace one set of species with
another. Such indices are unlikely to be useful at waste sites, and it is unlikely that
useful new pollution indices can be devised for waste sites because wastes are
unlikely to have a suitably stereotypic effect. Indices of generic community quality,
such as the index of biological integrity (IBI) (Karr et al. 1986), show promise as
indicators of the state of communities because they are sensitive to physical habitat
quality as well as to pollution. In addition, they have been applied to water quality
assessments in contexts other than HWS evaluations. All of these community
quality indices, like diversity indices, reduce to one number the information obtained
from a biotic survey. Therefore, they do not indicate how two sites differ and provide
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no evidence as to the cause of the difference. However, if an index like the IBI is well
characterized for a region, then it can be used to indicate how waste site effects
compare to effects of other disturbances in similar communities. For most regions
and community types, appropriate indices and baseline data are not currently
available.
The indicator species concept is conceptually similar to community indices in that
they are intended to describe the state of communities relative to anthropogenic
effects. The presence or abundance of a species that is thought to be either pollution-
sensitive or pollution-tolerant is used to indicate the status of a community. Like the
saprobic index, indicator species have been effective for assessing oxygen-demanding
pollution, but not for other types. Therefore, an indicator species may not reliably
define effects of hazardous waste sites, but within site-specific contexts may
contribute to the ecological assessment.
2.5.4 Ecosystem
Ecosystem properties relate to the exchange of energy and nutrients among
functionally defined groups of organisms and between organisms and the
environment. The most commonly measured ecosystem properties are biomass of the
system or its components (e.g., trophic levels), productivity of the system or its
components (e.g., primary and secondary production), and nutrient dynamics (e.g.,
nitrogen mineralization rates). These do not correspond to any assessment endpoint,
but all relate to the productive capability of a site. In particular, the realized
productivity of a site is an estimator of its productive capability, which may or may
not be relevant to its post-restoration potential. Productivity is more relevant to
affected off-site ecosystems, but, in any case, ecosystem or trophic level production is
less socially meaningful than production of valued populations. Soil processes would
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seem particularly promising because the waste chemicals typically occur at the
greatest concentration in soil. However, the complexity of soil processes, including
competition between natural processes and degradation of the waste, and the wide
range of organisms involved make interpretation difficult (Suter and Sharpies 1984).
Ecosystem properties can be difficult to measure on site, tend to be highly variable,
are not diagnostic, and are difficult to interpret, but are broadly applicable. No
standard methods exist for measuring toxic effects on ecosystem processes in the
field, but the EPA has recently adopted laboratory microcosm protocols that include
some measurements of ecosystem processes (Office of Pesticides and Toxic Substances
1987).
2.6 ASSESSMENT GOALS AND ASSESSMENT KNDPOINTS
Although the primary focus of this document is on selecting measurement endpoints
and performing measurements, it is critical to keep assessment endpoints and their
relation to the decision making process in mind. The point of the ecological
assessment is not to find out if anything ecological has been, is being, or could be
affected. Rather, it is to determine whether ecological effects have any relevance to
the choice of remedial action or other decisions. Is any socially valued ecological
entity being significantly affected in a way that can potentially be remediated? In
some cases the answer is clearly no. It would not be appropriate to go through an
ecological assessment process at most urban sites where there are no significant
ecological values, at residential sites where ecological values are minor relative to
potential human effects, or at sites where only deep geologic strata and ground water
are contaminated. On the other hand, an ecological assessment may reveal that in
spite of the waste, a valuable and viable community exists on the site that would be
destroyed by conventional remedial actions. Therefore, in choosing endpoints the
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assessor should consider the nature of the site, its current and potential ecological
state, the nature and dynamics of the wastes, and the potential remedial actions.
The problem of scale of effects is particularly acute in assessments of waste sites,
because sites tend to be small. Scale is not such a problem for human health
assessment because individual humans are valued so a site that includes a single
human resident is important. If endangered species are not an issue, plants and
animals are generally not valued biologically as individuals so it is necessary to
consider the magnitude of effects on a waste site relative to entire populations,
communities, or regions. An entire distinct microbial community can exist under a
single waste drum, and a distinct rodent population can exist on a waste site such as
Love Canal, but these communities may not have social significance. On the other
hand, socially significant populations, such as birds and medium to large mammals,
typically have populations that occupy large areas and may not be significantly
affected by toxic effects on a few individuals on a waste site. Similarly, most plant
community types occupy large areas relative to the scale of a typical waste site.
Therefore, ecological assessment effort should be concentrated on situations where
considerations of scale does not limit the significance of effects. One such situation is
large complexes of waste sites such as an oil field with numerous sumps, spills of toxic
materials, oil spills, land farms, and landfills spread over several square kilometers.
Another is where a waste site is able to significantly influence all or a major portion
of an off-site community. For example, plans for oil shale development in the
Piceance Basin, CO., involved filling the upper ends of canyons with retorted shale,
which would have resulted in associated trout streams being fed by waste leachate
and runoff (Suter et al. 1986). A third situation where scale is not a problem is use of
a site by an endangered species such as the bald eagles at the Rocky Mountain
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Arsenal. Injury of even a few individuals of an endangered species is not allowed
because each individual is assumed to be important to the survival of the species.
In the case of large complexes of sites, two types of assessment endpoints might be
appropriate. One type is the proportion of the community that has experienced
severe effects, such as devegetation of the individual sites by persistent phytotoxic
chemicals. This type of endpoint is readily measured and expressed at the
community level. The other type is reductions in a population experiencing combined
effects of habitat loss and toxic chemicals. This can occur either as members of the
population move across the site, spending various amounts of time at variously
contaminated locations and being exposed by various routes, or by integrating the
effects of a mosaic of individuals inhabiting clean or contaminated habitat. These
population effects are more difficult to assess because changes in the population as a
whole are difficult to attribute to the waste sites, and effects on individuals
inhabiting the waste sites must first be identified and then extrapolated to the
population level.
The situation of a waste site dominating an off-site community is more
straightforward. The choice of assessment endpoint depends on the valued attributes
of the affected system. In the oil shale example, the assessment endpoint would be
irout production and the measurement endpoints might be trout density, indices of
trout production (e.g., age to weight relationships), and trout prey base.
In the case of an endangered species, the assessment endpoint would be reduction in
the recovery rate of the species from its endangered status. Population parameters of
an endangered species are likely to be poor measurement endpoints because the
number of individuals is likely to be low and the species is likely to be far from
equilibrium with its environment. Measurement of effects is complicated by the
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inability to destructively sample the subjects. Sampling for body burdens or
biomarkers is largely limited to food species or to surrogate species that have similar
ecologies, physiologies, and exposure patterns to the endangered species. In general,
community and ecosystem properties are of interest not so much for their ability to
support the endangered species as for their role in causing exposure of the
endangered species to waste chemicals.
2.7 REFERENCES
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Division of Ecological Services. 1980. Habitat evaluation procedure (HEP). ESM
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Economic Analysis, Inc. 1987. Measuring damages to coastal and marine national
resources: Concepts and data relevant for CERCLA Type A Damage Assessments,
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Goodman, D. 1975. The theory of diversity-stability relationships in ecology.
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Jacobson, J.S., and A.C. Hill, eds. 1970. Recognition of Air Pollution Injury to
Vegetation: A Pictorial Atlas. Air Pollution Control Association, Pittsburgh, PA.
102pp.
Karr, J.R., K.D. Fausch, P.L. Angermeier, P.R. Yant, and I.J. Schlosser. 1986.
Assessing biological integrity in running waters: A method and its rationale. Illinois
Natural History Survey Special Publication No. 5, Illinois Natural History Survey,
Champaign, IL. 28pp.
Malhotra, S.S., and R.A. Blauel. 1980. Diagnosis of air pollutant and natural stress
symptoms on forest vegetation in western Canada. Northern Forest Research
Center, Edmonton, Canada. 84 pp.
McBee, K. 1985. Chromosomal aberations in resident small mammals at a
petrochemical waste dump site: A natural model for analysis of environmental
mutagens. Ph.D. dissertation, Texas A&M University, College Station, TX.
McCarthy, J.F., L.R. Shugart, and B.D. Jimenez. In press. Biological markers in
wild animal sentinals. In: Bioindicators of Exposure and Effect, Eighth ORNL Life
Sciences Symposium.
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Guidelines, OPTS-42095. 40 CFR, Parts 796-797.
O'Neill, R.V., R.H. Gardner, L.W. Barnthouse, G.W. Suter H, S.G. Hildebrand, and
C.W. Gehrs. 1982. Ecosystem risk analysis: A new methodology. Environ. Toxicol.
Chem. 1:167-177.
Porcella, D.B. 1983. Protocol for bioassessment of hazardous waste sites, EPA/600/2-
83-054. U.S. Environmental Protection Agency, Corvallis, OR.
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Toxicity Screening Procedures Using Bacteria. Marcel Dekker, Inc., New York, NY.
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ORNL/TM-9808, Oak Ridge National Laboratory, Oak Ridge, TN.
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responses offish to chronic toxic exposures. Environ. Toxicol. Chem. 6:793-809.
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chronic air pollution stress. J. Environ. Qual. 9:43-49.
228
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CHAPTERS
ASSESSMENT STRATKGIKS AND APPROACHES
By
Joan P. Baker, Kilkelly Environmental Associates, Raleigh, NC.
3.1 INTRODUCTION
Careful selection of the specific techniques and measures to be applied at a hazardous
waste site (HWS) will maximize the value of an ecological assessment. The optimal
design and methods for an ecological assessment vary depending upon the
characteristics of the HWS and the specific objectives and issues of concern. Given
the diversity of environmental conditions and problems at HWSs, a single best
strategy or design for ecological assessments, appropriate for all sites, cannot be
defined. Instead, to aid in selecting the best approach for a given HWS, this chapter
provides a general discussion of the alternative methods or "tools" available, and the
types of information contributed by each.
3.2 REVIEW OF EXISTING INFORMATION FOR THE SITE
The more that is known about conditions at the HWS, the more efficiently one can
conduct an ecological assessment. The first step in the design of the ecological
assessment, therefore, should be a compilation and review of this existing
information for the site. Examples of relevant information include the following:
• Site history -- Information on prior industrial activities at the site (e.g.,
operational history for the Rocky Mountain Arsenal) provides insight into the
nature, sources, and extent of site contamination.
• Chemistry data — As part of the HWS evaluation process, contaminant
concentrations in local soils, sediments, and waters will be determined. As
noted in Chapter 1, ecological assessments involve the integration of these
chemical data with results from the biological assessment methods described
in this document. This integration will only occur if the chemical sampling
and biological sampling are closely coordinated. For example, collection of
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chemical and biological samples must be done at common sites for direct data
comparisons. If chemical sampling has occurred at the HWS prior to initiation
of the ecological assessment, results from these studies will play a major role in
the development of the sampling design for the ecological assessment by
identifying "hot spots" or gradients of contamination that represent important
locations for biological sampling and testing. Results from biological sampling
also may aid in optimizing the design for further chemical sampling program.
• Kesults from fate and transport models -- Models of contaminant
movement and transformation provide insight into the extent and distribution
of potentially toxic substances at the HWS, both on site and off site. Model
results may identify locations and ecosystem components (e.g., soils and
associated soil organisms, or surface waters and aquatic biota) most likely to
be impacted. Results from the ecological assessment may, in turn, be useful in
the development and testing of fate and transport models. Thus, again,
coordination of these activities should be given a high priority.
• Existing ecological data -- Historical data for the HWS, or recent ecological
studies of similar, nearby ecosystems not affected by the HWS, may be used to
define natural, background conditions expected at the HWS. If such reference
data do not already exist, they must be collected as part of the ecological
assessment process. In addition, the design of the ecological assessment should
take full advantage of any prior studies of ecological effects at the HWS.
Since the data collected as part of an ecological assessment can benefit the design and
interpretation of other components of the HWS evaluation, ecological studies should
be initiated as early as possible in the HWS evaluation process. Procedures for
incorporating other sources of information within the ecological assessment design
and analysis are discussed further in Chapters 4 (Field Sampling Design) and 9 (Data
Interpretation).
3.3 INITIAL S1TK VISIT
The second step in an HWS ecological assessment involves a visit to the site by a
trained ecologist familiar with ecological community types in the region and with
experience in HWS evaluations. The primary objectives of this initial site visit are to
(1) identify the basic environmental (physical, chemical, and biological)
characteristics of the site and (2) develop a qualitative map of the major types and
status of ecological communities at the HWS. Little, if any, quantitative sampling is
3-2
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required (or recommended) at this stage; both the map and site characterization are
based largely on a visual assessment of site conditions. Off-site habitats should also
be examined if off-site effects are suspected to occur. The following environmental
features should be noted and, if appropriate, mapped:
• Major landscape features -- site topography and the distribution of major
habitat types, e.g., grasslands, forests, lakes, streams, wetlands.
• General physical and chemical characteristics of the terrestrial
environment -- soil type(s) and local geology.
• General physical and chemical characteristics of the aquatic
environment -- lake area and depth, stream size and flow, types of bottom
substrate, temperature, water clarity, and general water quality parameters
such as conductivity, salinity, hardness, pH, temperature, alkalinity, and
dissolved oxygen levels.
• Vegetation types -- identification of dominant species and classification of the
major vegetation community types.
• Occurrence of important terrestrial and aquatic animals -- qualitative
observations of birds, mammals, fish, stream benthos, and other animals
inhabiting the HWS, or the apparent absence of organisms considered typical
of the HWS habitat type(s).
• Occurrence of areas of contamination and ecological effects — locations
of obvious zones of chemical contamination and ecological effects, ranked by
apparent severity (e.g., ranked on a scale of 1 to 3, where 1 = obvious effects,
2 = possible effects, and 3 = no observed effects).
As part of these initial site characterization activities, it may also be appropriate to
collect selected soil, sediment, and water samples for assessment of acute toxicity (see
Chapter 6). Sites for sample collection should be selected subjectively in areas of
obvious ecological effects or at locations where ecological effects are most likely to
occur (based on prior chemical surveys or modeling). To the extent possible, samples
should be collected from each major habitat type (i.e., terrestrial and aquatic
habitats, soils, aquatic sediments, and surface waters).
3-3
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3.4 DEVELOPMENT OF THE ASSKSSMKNT STRATEGY AND DKSIGN
The existing site data and results from the initial site visit provide the basis for
developing a site-specific assessment strategy and design. Important components of
this plan include the following:
• Specific objectives - The objectives of the ecological assessment should be
clearly defined and should reflect both primary ecological concerns and the
anticipated role of the ecological assessment in the HWS evaluation process
and subsequent decision making.
• Conceptual framework — Formulating the optimal design for an ecological
assessment may be facilitated by developing a conceptual model for the site,
including information on the movement and distribution of contaminants,
likely interactions among ecosystem components, and expected ecological
effects at the HWS, on site and off site.
• Assessment and measurement end points -- The assessment endpoints and
corresponding measurement endpoints to be provided by the ecological
assessment should be selected based on the criteria outlined in Chapter 2. The
selected endpoints should match the specific objectives defined above.
• Assessment methods -- For each measurement endpoint, one or more of the
methods outlined in Chapters 6 through 8 should be chosen as the optimal
means for quantifying the response variable of interest.
• Quality assurance/quality control -- For each measurement endpoint, a
data quality objective (DQO) must be defined, i.e., the measurement precision
and accuracy required in order to satisfy the objectives of the HWS evaluation.
In addition, procedures for monitoring and controlling data quality must be
specified and incorporated within all aspects of the ecological assessment, i.e.,
during sample collection, processing, and analysis; data management; and
data analysis. Data quality objectives and procedures for quality
assurance/quality control are discussed further in Chapter 5.
• Field sampling design -- Statistical issues relating to design of the field
sampling program (e.g., optimal sample size, procedures for sample selection)
are discussed in Chapter 4.
• Schedule - Typically, the entire HWS evaluation (including planning, data
analysis, and report preparation) must be completed within 12 to 18 months.
Thus, the ecological assessment may be subject to quite severe time
constraints. On the other hand, some of the ecological methods, particularly
field surveys, may be easier and more effective to do if conducted at certain
times of the year. The schedule and time requirements for each aspect of the
ecological assessment must be given careful consideration.
3-4
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• Data analysis plan — Prior to the collection of data, a specific plan for data
analysis should be developed. By considering, immediately, the types of
analyses and outputs anticipated, important components, confounding factors,
and data requirements are less likely to be overlooked.
A tiered approach to an ecological assessment may be particularly effective. At each
step, or tier, the decision is made whether to proceed and how best to proceed, based
on the data collected up to that point. The tiers may be designed to reflect increasing
levels of effort and/or different aspects of the overall HWS ecological evaluation. In
the first instance, Tier 1 may consist of relatively crude, but rapid and inexpensive
methods for evaluating the extent and severity of ecological effects. If severe and
extensive effects are documented at this stage, there may be no need for additional
data to quantify the problem at the HWS. On the other hand, if few or no effects are
detected, it cannot be assumed that significant adverse effects are not occurring.
Thus, it may be necessary to apply more sensitive and comprehensive methodologies,
which are likely also to be more costly and time consuming, in a second tier of
analyses.
Tiers may also be designed to address a series of questions regarding ecological
conditions and effects at the HWS. In this case, results from the first tier feed directly
into design of the second tier, and Tiers 1 and 2 into Tier 3, etc. For example, Tier 1
could involve field surveys to determine whether significant population-level effects
on important organisms can be documented at the HWS (e.g., a significant reduction
in the abundance of important game fish in receiving streams). If such effects are
measured, of primary interest in Tier 2 would likely be the relationship, if any,
between the observed field effects and the toxicity of contaminants at the HWS. One
approach for Tier 2, therefore, would be to conduct aquatic toxicity tests using water
samples collected along the gradient of effects observed in Tier 1. If no toxic response
is measured, the population-level effect observed in the field survey may result
3-5
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principally from habitat degradation, rather than the presence of hazardous wastes
at the site. In certain instances (e.g., if the initial site visit suggested no overt
effects), it may be better to reverse the order of these tasks, asking first whether
acute or chronic toxic effects can be demonstrated before conducting field surveys to
quantify ecological status. Decisions regarding the optimal order for addressing
assessment issues are likely to be site specific, depending on the nature of the site and
existing information on the HWS.
The step-by-step, tiered approach is intended to maximize the efficiency of data
collection, using the information obtained at each stage to optimize the design of the
next stage. Typically, such an approach would require multiple trips to the HWS.
The logistics of on-site sampling at an HWS, however, can be quite cumbersome. In
such cases, the benefits derived from a tiered approach may be more than offset by
the added costs and difficulties associated with additional site visits. A tiered
approach may also require more time to implement, and thus may or may not be
feasible within the time constraints of the HWS evaluation. Again, the optimal
strategy for an ecological assessment would be site specific, depending on the
complexity of the site, the difficulties and costs associated with obtaining access to
the site, and the available time for data collection.
3.5 ASSESSMENT METHODS
The methods recommended for use in ecological assessments at HWSs are grouped
into three major categories: (1) toxicity tests (see Chapter 6), (2) biomarkers (see
Chapter 7), and (3) field surveys (see Chapter 8). Each of these basic methodologies
contributes a different type of information to the HWS evaluation. As a result, all
three must often be applied to gain a complete understanding of the ecological effects
at an HWS. The following subsections provide an overview of the primary
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advantages, and also limitations, of each of these major categories of assessment
methods. Similar discussions for specific recommended methods and procedures are
presented in Chapters 6 through 8.
3.5.1 Toxicity Tests
Toxicity tests measure the effects of contaminated media from the HWS on the
survival, growth, and/or reproduction of aquatic and terrestrial biota. Most often,
samples of soil, sediment, or water are collected from the HWS and returned to the
laboratory for testing with several standard laboratory test species. Toxicity tests
can also be run in mobile laboratories or m situ, and with resident species from the
site (see section 6.1).
The advantages and limitations of using toxicity tests in ecological assessments are
reviewed in Table 3-1. Chemical analyses provide a measure of the total
concentration of specific chemical compounds. Toxicity tests, on the other hand,
provide an integrated index of the bioavailable toxic contaminants on the site.
Furthermore, some toxic chemicals on a site may not be measured accurately in
chemical analyses because of the complexity of the matrix or analytical detection
limits. Thus, toxicity tests play an important role in and of themselves in site
assessments, and potentially link the occurrence of contamination, as evidenced by
an elevated chemical concentration, to biological effects. Toxicity tests are only an
index, however, of the potential for population- or community-level effects at the
HWS. Demonstration and quantification of ecological effects require field surveys.
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Table 3-1. Advantages and Limitations of Toxicity Tests in Kcological
Assessments
Advantages
Measure of toxic conditions that
can be linked to the presence of
contaminants and hazardous wastes;
an important assessment component
needed to establish causality.
Results are an integrated index
of bioavailable contamination, whereas
chemical analyses measure only
total concentrations of specific
compounds.
Results are specific to the location
at which the sample was collected,
thus they can be used to develop
maps of the extent and distribution
of bioavailable contamination and
toxic conditions.
Results are easily interpreted and
amenable to QA/QC; within- and among-
laboratory precision, estimates are
already available for several tests.
Acute toxicity tests are relatively
quick, easy, and inexpensive to
conduct; results from acute tests
are used as a guide in the design of
chronic toxicity tests.
Chronic toxicity tests are generally
more sensitive than are acute tests,
and can be used to define "no effect"
levels; in addition, chronic tests
provide a better index of field
population responses and more closely
mimic actual exposures in the field.
Limitations
Measure of potential toxic effects
on resident biota at the HWS; however,
cannot always be directly translated into
an expected magnitude of effects on
populations in the field.
Results are somewhat dependent on
specific techniques, e.g., test species,
water or soil quality, test duration, etc.
Ecological survey data also provide
an integrated measure of effects
for the entire HWS, and may be more
useful for addressing certain assessment
objectives.
Exposure conditions in toxicity tests are
not directly comparable to field
exposures; additional confounding
variables and other stresses are
important in the field.
Acute tests are less sensitive measures of
toxic conditions (relative to chronic tests
or biomarkers); thus, the absence of an
acute toxic response cannot be
interpreted as the absence of a toxicity
problem
Chronic tests require more time and
and expertise to conduct, yet still may
not detect all sublethal effects.
Results from toxicity tests are specific to the site of sample collection, and thus can be
mapped to define gradients and zones of toxic conditions. Such maps, in addition to
response surfaces of toxicity, can serve as a guide to the design of field surveys and
3-8
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other sampling programs. A close correspondence between spatial patterns of
toxicity and spatial patterns of effects measured in field surveys provides strong
evidence for the importance of toxic contaminants in controlling the status of
ecological communities at the site.
Like chemical analyses, procedures for quality assurance and quality control for
toxicity tests are fairly well established. Given standardized test conditions, as
described in Chapter 6, results from toxicity tests are typically highly repeatable
both within and among test laboratories.
Toxicity tests are generally classified as either acute (short-term) or chronic (long-
term) depending on the length of exposure of the organism to the contaminated
media. Acute toxicity tests are probably the best means for conducting a first-order
assessment of the distribution and extent of toxic conditions at a site. They are
relatively quick, easy, and inexpensive to conduct. On the other hand, acute tests
tend to be less sensitive measures of toxicity than are chronic tests or biomarkers.
Thus, the absence of an acute toxic response cannot be interpreted as the absence of a
toxic problem. Chronic toxicity tests, while requiring additional time and expertise,
may be needed to detect less severe, but still important, toxic effects. In particular,
chronic toxicity tests may be used to define "no effect" levels, useful for evaluating
the effectiveness of remediation programs.
Microbial systems, and methods relying on measurements of microbial activity, were
treated somewhat separately in development of the recommended methodologies for
ecological assessments. Although included within the chapter on toxicity testing
(Section 6.4), some of these procedures could also be applied in field surveys; many
3-9
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assay the effects of contaminants on sensitive physiological and biochemical
processes and thus could also be considered biomarkers.
The advantages and lirni tations of using microbial tests in ecological assessments are
reviewed in Table 3-2. The advantages result principally from their small size and
generally rapid response. Most of the tests described are quick, inexpensive, and easy
to conduct, and require quite small sample volumes, an added advantage if the
samples are to be transported from the field back to the laboratory. In addition, many
of the microbial functional responses assayed represent important ecosystem
processes and microbial tests have been applied in the field to evaluate these
processes. Unfortunately, relatively little data are available on the effectiveness of
these tests for measuring toxicity at HWSs.
Table 3-2. Advantages and Limitations of Microbial Studies in Ecological
Assessments
Advantages
Tests are quick, inexpensive,
and relatively easy to conduct,
and require small amounts of
sample.
Many of the response variables
represent basic ecosystem processes.
Limitations
Relatively little data are available on the
responses of microbes to HWS
contaminants.
Relationship between responses
in small-scale tests and ecosystem
processes has not been evaluated in the
field.
3.5.2 liiomarkers
The term "biomarkers" refers to the measurement of selected endpoints in individual
organisms, typically physiological or biochemical responses, that serve as sensitive
indicators of exposure to contaminants and/or sublethal stress. As used in this
document, measures of bioaccumulation, i.e., chemical concentrations of
3-10
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contaminants in organisms, are considered a biomarker of exposure. Other examples
of biomarkers of exposure and sublethal stress include the following: (1)
concentrations of enzymes such as cholinesterases and delta-aminolevulinic acid
dehydrase (delta-ALAD); (2) genetic abnormalities, e.g., DNA unwinding; (3)
physiological responses, such as rates of gas exchange in plants; and (4)
histopathological (e.g., occurrence of tumors) or skeletal abnormalities (see Chapter
7).
The advantages and limitations of using biomarkers in ecological assessments are
reviewed in Table 3-3. An important advantage is their broad applicability. The
techniques can be applied at many taxonomic levels (plants and animals) and the
results have inferences that go beyond the organism(s) tested. Evidence for
genotoxicity or disruption of basic physiological and biochemical processes based on
biomarker analyses have relevance to assessments of potential hazards to human
health.
Biomarkers can be measured in organisms collected from the field, reflecting "real-
world" exposures, and in organisms exposed to contaminated media under more
controlled conditions in the laboratory or m situ. Thus, biomarkers provide an
important tool for comparing biological responses in the laboratory and in the field
since the same methods can be applied in both environments. In addition, some tests
are diagnostic of specific contaminants, and most tests provide some information on
the mechanism of toxic response. All of these attributes aid in establishing causality
for ecological effects in the HWS evaluation.
3-11
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Table 3-3. Advantages and Limitations of Biomarkers in Ecological
Assessments
Advantages
Broadly applicable; a measure of
biological response that crosses
taxonomic lines, including inferences
to potential human health effects.
Provides insight into the potential
mechanisms of contaminant effects;
in many cases, biomarkers are
diagnostic of specific contaminants.
Can be applied in both the laboratory
and field, providing an important
linkage between laboratory toxicity
tests and effects in the field.
For field samples, biomarkers provide
an important index of bioavailability
with "real-world" exposures.
When applied correctly (i.e., a
biomarker appropriate for the
contaminants at the site) may be a
very sensitive index of
bioavailability and biological response.
Limitations
Relationship between biomarkers and
population-level effects in the field
are not well defined.
Biomarkers are still lacking for most
of the compounds of interest at HWSs.
Require particular care in sample
handling as well as added time and
expense.
For mobile species, difficult to define
"exposure;" may require destructive
sampling.
Important to carefully define
reference conditions, a problem
common to all field studies.
The major limitation in applying biomarkers in ecological assessments is the current
lack of accepted, standardized, and tested markers for many of the HWS
contaminants of interest. While a number of biomarkers are sufficiently developed
for use at this time, many others are still under development and require further
research. In addition, for most biomarkers, the relationship between a measured
biomarker response and population-level effects has not been defined. Biomarkers
are highly sensitive indices of exposure and sublethal response, but, within the
context of an ecological assessment, their relevance is most evident when biomarker
studies are conducted jointly with toxicity testing and field surveys.
3-12
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3.5.3 Field Surveys
Field surveys involve the measurement of the structural and functional
characteristics of populations and communities at the HWS. Recommended methods
for field surveys are outlined in Chapter 8 for aquatic ecosystems (section 8.2),
terrestrial vegetation (section 8.3), terrestrial vertebrates (section 8.4), and
terrestrial invertebrates (section 8.5).
The advantages and limitations of using field surveys in ecological assessments are
reviewed in Table 3-4. While toxicity tests may infer potential population- and
community-level effects, field surveys are the only means for demonstrating actual
population- and community-level effects at the HWS. Survey data identify the
"problem" and the extent of the problem. Organisms are exposed in the "real world,"
and measured effects represent an integrated response to the temporal and spatial
variations in exposure and contaminant concentrations in the field. With survey
data alone, however, the causes for observed effects are difficult to determine. As
noted in the preceding sections, causality is established best by a combination of
approaches, including chemical sampling, toxicity testing, biomarkers, and field
surveys.
Results from field surveys and measures of ecological status are often highly
variable, reflecting the high degree of variability (both spatial and temporal) in
natural communities and, in some cases (e.g., fish communities in lakes), the
problems inherent in sampling the biological community. As a result of this high
background variability, fairly extensive sampling may be needed to measure the
ecological characteristics of interest with a sufficient level of precision to detect
"effects" related to the HWS. Careful attention to sampling design (Chapter 4) is
3-13
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required to ensure that the survey results satisfy the objectives (and data quality
objectives) of the HWS evaluation. Procedures for quality assurance/quality control
exist for field surveys, but they are not nearly as well established or clear-cut as are
protocols for other components of the ecological assessment.
Table 3.4 Advantages and Limitations of Field Surveys in Ecological
Assessments
Advantages
Characterizes the basic ecology of
the site, identifying important
resident species and community types;
based on results from the field
survey, relevant species for use in
toxicity testing and biomarker
analyses can be identified.
Potentially demonstrates definitive
ecological effects in the field,
delineating zones of effect and no
apparent effect.
Field responses integrate
temporal and spatial variations
in exposure and contaminant
concentrations.
Information on the status of
terrestrial vegetation can be
obtained from aerial photographs,
eliminating the need to visit the HWS
to survey terrestrial vegetation.
Limitations
Results from field surveys may
be highly variable, requiring
extensive sampling to measure
ecological status with sufficient
precision for detection of effects;
as a result, the absence of a measurable
effect cannot always be interpreted as no
effect.
With survey data alone, causes for
observed effects are difficult to
determine.
Results represent only a snapshot
of the ecological status at the time of
the survey.
Procedures for QA/QC are not
well established; difficult to
measure precision and accuracy.
3.6 SUMMARY
Key questions of interest for ecological assessments at HWS and recommended
approaches for addressing these questions are summarized in Table 3-5.
3-14
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CHAPTER4
FIELD SAMPLING DESIGN
By
Donald L. Stevens, Jr., Eastern Oregon State College, La Grande, OR.
4.1 GENERAL STATISTICAL CONSIDERATIONS
Each hazardous waste site (HWS) considered for ecological assessment will, to some
extent, present unique problems in sampling design and data analysis because of
differences in site characteristics and potential contaminants. No single field
sampling design can be suitable for every HWS. A competent statistician should
always be consulted prior to designing any laboratory or field study and collecting
data.
Field sampling activities must be coordinated between sample collection for chemical
analysis, laboratory toxicity testing, and field survey activities. Sample collection
and field survey activities should be coordinated in space and time. The following
three types of information are necessary to establish a relationship between toxic
wastes and ecological effects: (1) chemical analysis of the appropriate media are
necessary to establish the presence, concentration, and variability of toxic chemicals;
(2) ecological surveys are necessary to establish that the toxic effects have occurred;
and (3) toxicity tests are necessary to establish that the adverse effects can be caused
by the toxicity of the wastes. Even with this information, relationships between toxic
wastes and ecological effects may be difficult to determine. Comparisons of these
three data types are greatly simplified when the data collection activities are
coordinated. Space and time coordination of data collection is necessary to eliminate
variation in the analytical results associated with the difference in geographical
regions and changes in concentration and toxicity over time.
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Due to the complexities inherent in statistical sampling design, this chapter will not
attempt to present specific field sampling designs appropriate for an HWS. The
following discussion focuses on general approaches and issues in field sampling
design.
1.1.1 Theoretical Considerations
The ecological assessment will draw on both laboratory and field data. Most of the
field data will be observational data, or what Hurlburt (1984) terms results from
mensurative experiments. Generally, different methods are used to analyze data
from field studies than laboratory studies, primarily because most field data are not
generated by randomized controlled experiments. This has the following two major
implications: (1) many commonly used statistical analysis techniques, e.g., analysis
of variance (ANOVA), or hypothesis tests, are not applicable or are restricted in
interpretation; and (2) inferences of causality are usually not possible from
observational field data alone.
It is worthwhile to review the essentials of classical experimental design to
appreciate these two points. Consider the simplest case, where one wishes to
determine if a particular treatment has an effect. A target population of subjects is
identified, and two groups are selected at random from the target population. The
treatment is administered to one group, and the other group serves as the control. A
response is measured for each group, and the difference in the average response is a
measure of the effect of the treatment. The significance of the difference can be
established by standard hypothesis tests. Moreover, the random assignment of
subjects to treatment and control groups permits an inference of causality: one can
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claim that the observed difference is in fact due to the treatment and not to some
preexisting difference between the groups.
In an ecological assessment, the treatment and control groups are not selected at
random from some target population, since, in fact, the HWS site was not selected at
random. No amount of careful matching of a reference area outside the HWS can
compensate for the lack of random selection. A statistically valid test of the
hypothesis that any observed difference between the HWS and the reference site is
due to the HWS is not possible. One can test, however, the hypothesis that the two
sites are different, but that difference cannot be attributed to the presence of the
HWS. In statistical terms, the effect of the HWS is completely confounded with
preexisting differences between the HWS and a reference site.
This does not mean that a firm case cannot be made that an HWS has had an adverse
ecological effect. However, in doing so, it must be recognized that the HWS itself
represents an experimental unit that cannot be replicated. Some care must be
exercised to avoid "pseudoreplication" (Hurlburt 1984). In essence, pseudoreplication
is testing an hypothesis about treatment effects with inappropriate statistical design
or analysis methods. It is as much a problem of misspecification or misunderstanding
of the hypothesis being tested as of methodological errors. For the case at hand,
pseudoreplication can be avoided by recognizing that the hypothesis of an effect of
the HWS cannot be tested by statistical means. The hypothesis of a difference
between a reference site and the HWS can be tested. Of course, establishing a
difference is an essential step in the process of demonstrating an adverse ecological
effect. If there is no detectable difference, then there is no cause to establish. Non-
statistical methods must be used to establish that the difference is caused by the
presence of the HWS.
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Methods used to establish causality may make use of statistical techniques, such as
regression or correlation. For example, regression can be used to show that toxicity
increases along with the concentration of some chemical known to originate from the
HWS. The regression merely describes the relationship, there is no implication of a
causal link. The presence of a strong relationship is evidence that the link exists.
4.1.2 Practical Considerations
A major step in assessing ecological effect at an HWS will be the choice of a reference
site for comparison. The case for causality can be strengthened by selecting the
reference site to be as similar as possible to the HWS. In making the selection,
physical similarities (e.g., elevation, landscape shape, soils), environmental
similarities (e.g., precipitation, temperature, wind patterns, external sources of
pollution), and ecological similarities (e.g., habitat type, habitat disturbance) should
all be considered. If the site is aquatic, then parameters such as stream order, flow
rate, and stream hydrograph should be considered. Additional references on site
selection are presented in Chapters 6 through 8.
Every effort should be made to ensure that the samples are collected, stored, and
processed under a uniform protocol. The same volume or weight should be collected
and the samples should be stored in identical containers. The samples should be
processed as soon as possible, and the time between collection and processing should
be as uniform as possible.
A guiding principle is that one should avoid the possibility of creating a handling
effect that is confounded with an effect being measured. If delays in sample
processing are unavoidable, the samples should be processed either in a random order
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or with a balanced intermixture of treatment and controls. If more than one field
team is to be used, the sample locations assigned to a team should be distributed
randomly over the site.
The field technicians should have explicit, detailed instructions on the sampling
protocol. The instructions should include not only the actual sample collection
procedure, but also details of sample site location. Since the sample sites will likely
be located at random, occasionally there will be some sites selected that cannot be
sampled. For example, the presence of a large boulder just below ground surface may
preclude soil sampling. Contingency procedures should be established to cover such
events.
4.2 SAMPLE DESIGN DEVELOPMENT
The most important consideration in the design of any sampling plan is a clear,
precise statement of the objective of the sampling (see Chapter 3). This should
include a statement of the general question that is to be addressed, along with
specific working hypotheses that can be used to guide the design development,
description of the specific endpoints to be assessed, and specification of the
measurements to be made and the data to be collected. Potential questions that
might influence the design of a sampling plan include: "What are the effects on
terrestrial or aquatic organisms; what is the severity of maximum effects; and what
is the spatial distribution of effects?" Because a unified sampling approach is
essential, all anticipated measurements should be considered before attempting to
design the sampling plan. Chemical concentrations must relate to observed effects,
so it would not make sense to sample once to determine spatial distribution of
chemical concentration, and to make a second sample to determine distribution of
ecological effects. Eventually, measures of intensity of insult will be tied to measures
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of effect, and the most direct means of accomplishing that is to have all samples taken
at the same location. All available information should be considered in designing the
sampling plan.
The sample design will be largely determined by the measurement endpoints. The
selection of such endpoints should be made early in the design process, and the design
built around that selection. Statistical consideration should be given to the selection
of endpoints. From a statistical standpoint, a good endpoint should have the
following two properties: (1) a low natural variability, and (2) a monotonic response
that is steep relative to the natural variability. Natural variability contributes to the
standard error of any statistic (e.g., a mean or a regression coefficient) computed from
ihe data. Lower natural variability permits reliable inferences with smaller sample
sizes.
Data analysis techniques that will be used directly affect the sample design, and vice
versa. Different sample designs are optimal for estimating LC50 isopleths than for
estimating the average LC50.
4.3 SELECTION OF SAMPLE DESIGN
The selection of an appropriate sample design is dependent upon a number of
variables such as the objective of the study, prior knowledge of the physical and
chemical characteristics of the HWS, the data analysis technique of interest, and the
degree of sensitivity necessary to validate the study. This section will review a
number of candidate sampling design methods. Additional information can be found
in Bratcher (1970), Cochran (1977), and Green (1979).
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4.3.1 Terminology
The sampling design process begins with definition of the target population. In
statistical terminology, the basic entity that is to be measured is called a population
element. In many cases, elements are selected for measurement in groups, called
sampling units. In field sampling, the collection of points that comprise a particular
area might be considered the population elements. For sampling purposes, the area
might be divided into subregions, such as quadrats. The quadrats would then be the
sample units.
Once the sampling units have been identified, they must be arranged, at least
conceptually, in some manner so that they become available for sampling. Such an
arrangement is called a population frame (Cochran 1977). Construction of the
population frame is frequently one of the more challenging aspects of constructing a
good sample. Conceptually, there are numerous ways to arrange sample points. A
frequently used method is to arrange the points in a grid pattern, with the points
equidistant in an X-Y coordinate system. An alternative method is to arrange the
points along a transect, with the sample points equidistant along a straight line. The
sample points may be chosen randomly within the area of interest. Each of these
methods is discussed further below.
4.3.2 Non-Random Methods
A number of techniques are available for selecting particular sample locations. A
frequently used method in field sampling is to select sites based on scientific
judgment. For instance, sites may be selected that are thought to be representative
or typical based on the preliminary survey; or presumably-sensitive sites may be
chosen. Such judgmental selection may sometimes be the best way of estimating an
average or detecting an effect. However, a serious flaw of such methods is that the
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quality is highly dependent upon the skill of the person making the selection. The
estimates may be very good and very accurate, but there is no means to assess their
goodness or accuracy.
A second method is to locate the sample sites in a regular pattern, either at the nodes
of a grid or at regular locations along a transect. This method has the advantages of
good spatial coverage and greater objectivity. There are, however, two major
disadvantages: a regular sample spacing may miss a periodic pattern; and again,
there is no inherent means of assessing the precision of the sample.
4.3.3 Kandom Methods
Statistical theory provides a means of evaluating precision only if the sample
selection is random. In simple random sampling, every sampling unit in the
population frame has the same chance of being included in the sample. Simple
random sampling is conveniently used with a list frame where the entire target
population can be enumerated. With the sampling units numbered sequentially,
selection can be done with the aid of a random number table or with computer-
generated random numbers. Simple random sampling has the advantage of
objectivity as well as several important statistical advantages. First, most statistics
(e.g., means and regression coefficients) generated from the sample data are unbiased
estimates of the corresponding parameters of the whole sample region. Second, the
statistical analysis of data from points located completely at random is comparatively
straightforward. Finally, and most important, the method provides built-in
estimates of precision. Some drawbacks are that completely random sampling may
miss important characteristics of the site, spatial coverage tends to be non-uniform,
and many points may be in areas of little interest.
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4.3.4 Stratified Sampling
Some of the difficulties mentioned above may be partially overcome through the use
of stratified sampling. Stratification consists of dividing the target population into
several groups, or strata, and then selecting independent samples from each stratum.
Stratified sampling is most often used to increase precision by sampling more
intensively the more variable portions of a target population. However, it can also be
used to allocate more sampling effort to important subpopulations without losing the
ability to make entire population projections. For instance, it may be prudent to
sample regions of known or suspected high chemical concentrations more intensively
than regions of lower concentration.
The techniques discussed in the preceding paragraph can be combined in a variety of
ways to incorporate the best features of each. A good sample design has at least the
following features: (1) samples are located so that they provide the maximum amount
of information about the site; (2) sample points have a uniform spatial distribution;
and (3) an internal method for estimating precision is available as an adjunct to the
design.
If the preliminary survey has provided a rough indication of the regions of interest,
then the sample should be allocated so that critical regions are well characterized.
Once that is done, then points within an identified subregion should be located
according to a regular grid pattern. In order to preserve the randomness essential for
estimates of precision, the grid should be oriented at random on the site. This can be
accomplished by locating two points at random, and positioning the grid so that both
points lie on a grid line and the first point lies on an intersection of grid lines. The
coordinates of the points selected at random should be chosen using a table or
computer-generated list of random numbers.
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4.4 DETERMINATION OF SAMPLE SIZE
One of the first questions often asked of a statistician is: "How many samples should I
take?" Unfortunately, there is no simple and strictly correct answer. Generally
speaking, the precision of an estimate, whether it be an estimate of a mean or an
estimate of the slope of a regression line, is expressed in terms of a standard error.
The standard error is determined by four factors: inherent population variability,
sample size, sampling design, and the data analysis method. In principle, one can
determine a sample size by deciding on the required precision and using the known
relationships between standard error, sample size, population distribution, and
analysis method. However, the exact relationships are usually complex and depend
on unknown population characteristics such as the population variance. Thus, some
approximate guidelines are usually applied. Other things being equal, the standard
error will be roughly inversely proportional to the square root of sample size.
Increasing the sample size from, for instance, 10 to 40, will double the precision
(halve the uncertainty). A further reduction by a factor of 0.5 would require a sample
size of 160. The gain in precision for smaller samples will be relatively rapid.
A second consideration in selecting sample size is the balance between Type I errors
(rejecting a true null hypothesis) and Type II errors (accepting a false null
hypothesis). Consider the comparison of a reference site to the HWS by a test of
significance for a difference between the two, and suppose that an adverse effect
corresponds to a decrease in the average. The null hypothesis is that the mean
response at the HWS is the same as the mean response at the reference (REF) site
(H(j:m||WS = mKFF), and the alternative is that the mean response at the HWS is less
than (or greater than) the mean response at the reference site (HA: ninws < mKKK^
The Type I error rate, i.e., the significance level of the hypothesis test, is controlled by
specifying the minimum observed difference between m,|WS and mKKF that will lead to
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rejection of HQ. The Type n error rate is frequently expressed in terms of the power of
a test, which is the probability of falsely accepting the null hypothesis. The power is
determined by the test method, the significance level, the sample size, the sampling
method, and the population variance. In an ecological assessment, the power is at
least as important, and possibly more important, than the significance level. The
consequences of rejecting the hypothesis of no effect when in fact there is an adverse
effect may be more severe, economically and socially, than the consequences of
remediation on a site that may not have needed it.
Most of the statistical tests used in the assessment of an HWS will involve
comparisons of two sample means: one from the HWS and one from a reference site.
Determination of sample size requires the specification of test method, the power, the
significance level, and magnitude of the difference to be detected. For purposes of
illustration, suppose that the means are to be compared using a t-test. If the value of
the population standard deviation, s, is known (not estimated from the data), the
necessary sample can be calculated from the following formula:
n = 2(Za +Zb)2(s/d)2
where:
n = sample size
Za = normal score corresponding to the significance level
Zb = normal score corresponding to the Type II error
d — size of the difference to be detected
s = population standard deviation.
For ease in calculation of sample size, the values of (Za + Zb)2 are given in Table 4-1
for various values of the significance level and the power for a one-tailed test.
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Table 4-1. Multipliers of 2(s/d)2for Determination of Sample Size
Significance level
.2
.1
.05
.01
.75
2.3
3.8
5.4
9.0
Power
.8
2.8
4.5
6.2
10.0
.9
4.5
6.6
8.6
13.0
.95
6.2
8.6
10.8
15.8
For example, suppose the population standard deviation is known to be 7.5, and a
difference of 10 or larger is deemed to be important. Further, suppose a 90% chance
of detecting that difference at a 5% significance level is needed. The required sample
size is calculated as follows:
n = (2)(8.6)(7.5/10)2 = 9.675, rounded up to 10.
This method should be used only if the population standard deviation is known and
not estimated from the data. If the standard deviation must be estimated from the
data, the sample size should be inflated accordingly. An approximate adjustment can
be made by first calculating the sample size as above, and then multiplying by a
factor of (n + 3)/(n + l). In the example above, if 7.5 were an estimate instead of a
known population standard deviation, the appropriate sample size would be
n' = 9.675(10 + 3)/(10 + l) = 11.43, rounded up to 12.
Another important consideration in picking a sample size is that statistical methods
for "large" samples tend to be much simpler than for small samples. Although the
dividing line between large and small is not firm, a sample size of 30 to 50 is
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generally sufficient to use large sample methods. A sample size of ten should be
treated as a small sample.
4.5 REFERENCES
Bratcher, T.L., M.A. Moran, and W.J. Zimmer. 1970. Tables of sample size in the
analysis of variance. Pages 156-164. In: Journal of Quality Technology.
Cochran.W.G. 1977. Sampling Techniques. John Wiley & Sons. New York, NY.
Green, R.H. 1979. Sampling Design and Statistical Methods for Environmental
Biologists. John Wiley and Sons, New York, NY. 257 pp.
Hurlburt, S.H. 1984. Pseudoreplication and the design of ecological field
experiments. Ecological Monographs. 54:187-211.
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CHAPTERS
QUALITY ASSUKANCK AND DATA QUALITY OBJKCTIVKS
By
William Warren-Hicks, Kilkelly Environmental Associates, Raleigh, NC
5.1 QUALITY ASSURANCE
Agency policies require that all EPA laboratories, program offices, and regional
offices participate in a well managed quality assurance (QA) program when
environmental data is collected. This policy extends to those monitoring and
measurement efforts supported or mandated through contracts, regulations, and/or
other formal agreements. The intent is to develop a unified approach to QA to ensure
the collection of data that are scientifically sound, legally defensible, and of known
quality.
Quality assurance practices include all aspects of laboratory and field procedures
that affect the accuracy and precision of the data, such as sample handling and
storage, condition of monitoring equipment, field and laboratory conditions, record
keeping, and data evaluation. The importance of QA in the ecological assessment of a
hazardous waste site (HWS) cannot be over stressed. A QA plan should be developed
for all data generating activities associated with ecological assessments at HWSs
(U.S. EPA 1987).
Specific, formal QA procedures have been well defined for some disciplines (e.g.,
aquatic toxicity testing) and are under development in other disciplines (e.g.,
vertebrate field surveys). Due to this inconsistency, applicable QA recommendations
and references have been included within the individual sections of this manual. For
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those sections with little QA information, the reader should refer to the Quality
Assurance Guidelines for Biological Testing (U.S. EPA 1978).
5.2 DATA QUALITY OBJECTIVES (I)QOs)
Environmental data play a critical role in the ecological assessments of HWSs. Due
to the importance of data collection in the decision making process, the methods used
to design data collection programs should place substantial emphasis on defining the
regulatory objectives of the program, the decision that will be made with the data
collected, and the possible consequences of an incorrect decision. A design process
that fails to explore these issues and focuses only on collecting the "best possible
data" can result in serious problems. Data collection programs based on technical
merit alone do not always ensure that adequate information is obtained from a
decision-making perspective.
This chapter provides a brief overview of the role of data quality objectives (DQOs) in
the design of data collection programs. For a more thorough discussion see U.S. EPA
I987a and 1987b.
5.2.1 Overview of DQOs and the DQO Process
The Quality Assurance Management Staff (QAMS) has proposed an approach to
designing environmental data collection programs based on the development of
DQOs. The DQO process does not use a pre-established budget as the sole constraint
on the design of a data collection program. Rather, equal consideration is given to
defining the quality of the product needed, i.e., the degree to which total error in the
results derived from data must be controlled to achieve an acceptable level of
confidence in a decision that will be made with the data. The DQO process provides a
logical, objective, and quantitative framework for finding an appropriate balance
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between the time and resources that will be used to collect data and the quality of the
data needed to make the decision. Therefore, data collection programs based on
DQOs may be more likely to meet the needs of decision makers in a cost effective
manner.
DQOs are statements of the level of uncertainty that a decision maker is willing to
accept in results derived from environmental data, when the results are going to be
used in a regulatory or programmatic decision (e.g., defining that a new regulation is
needed, setting or revising a standard, or determining compliance). To be complete,
these quantitative DQOs must be accompanied by clear statements of the following:
• the decision to be made,
• why environmental data are needed and how they will be used,
• time and resource constraints on data collection,
• descriptions of the environmental data to be collected,
• specifications regarding the domain of the decision, and
• the calculations, statistical or otherwise, that will be performed
using the data in order to arrive at a result.
Developing DQOs should be the first step in initiating any significant environmental
data collection program that will be conducted by or for the EPA. The DQO process
consists of three stages with several steps in each stage (Figure 5-1). The first two
stages result in proposed DQOs, with accompanying specifications and constraints for
designing the data collection program. In the third stage, potential designs for the
data collection program are evaluated. The following section provides a brief
overview of the three stages.
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STAGE 1
IDENTIFY DECISION TYPES
• IDENTIFY AND INVOLVE DATA USERS
• EVALUATE AVAILABLE DATA
• DEVELOP CONCEPTUAL MODEL
• SPECIFY OBJECTIVES/DECISIONS
STAGE 2
IDENTIFY DATA USES/NEEDS
• IDENTIFY DATA USES
• IDENTIFY DATA TYPES
• IDENTIFY DATA QUALITY NEEDS
• IDENTIFY DATA QUANTITY NEEDS
• EVALUATE SAMPLING ANALYSIS
OPTIONS
• REVIEW PARCC PARAMETERS
STAGE 3
DESIGN DATA COLLECTION PROGRAM
• ASSEMBLE DATA COLLECTION
COMPONENTS
• DEVELOP DATA COLLECTION
DOCUMENTATION
Figure 5-1. The DQO three-stage process.
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5.2.2 The Three Stages of the DQO Process
The following discussion presents a brief overview of the three stages within the DQO
development process.
5.2.2.1 Identify Decision Types
Stage I is the responsibility of the decision maker. The decision maker states an
initial perception of what decision must be made, what information is needed, why
and when it is needed, how it will be used, and what the consequences will be if
information of adequate quality is not available. Initial estimates of the time and
resources that can reasonably be made available for the data collection activity are
presented.
5.2.2.2 Identify Data Uses and Needs
Stage II is primarily the responsibility of the senior program staff, with guidance and
oversight from the decision maker and input from the technical staff. The
information from Stage I is carefully examined and discussed with the decision
maker to ensure that senior program staff understand as many of the nuances of the
program as possible. After this interactive process, senior program staff discuss each
aspect of the initial problem, exercising their prerogative to reconsider key elements
from a technical or policy standpoint. The outcome of their work, once explained and
concurred upon by the decision maker, leads to the generation of specific guidance for
designing the data collection program. The products of Stage n include proposed
statements of the type and quality of environmental data required to support the
decision, along with other technical constraints on the data collection activity that
will place bounds on the search for an acceptable design in Stage IH. These outputs
are proposed DQOs.
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5.2.2.3 Design the Data Collection Program
The responsibility of the technical staff and the decision maker during Stage HI is to
assure the outputs from Stages I and n are understood. The objective of Stage in is
to develop data collection plans that will meet the criteria and constraints
established in Stages I and n. All viable options should be presented to the decision
maker. It is the prerogative of the decision maker to select the final design that
provides the best balance between time and resources available for data collection
and the level of uncertainty expected in the final results.
5.3 REFERENCES
United States Environmental Protection Agency. 1978 Environmental Monitoring
Series. Quality assurance guidelines for biological testing. EPA/600/4-78/043.
Environmental Monitoring Support Laboratory, Las Vegas, NV.
United States Environmental Protection Agency. 1987. Quality Assurance Program
Plan. Environmental Research Laboratory, Corvallis OR.
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CHAPTERS
TOXICITY TESTS
By
Benjamin R. Parkhurst, Western Aquatics, Inc., Laramie, WY.
Greg Linder, NSI Technology Services Corporation,
Corvallis Environmental Research Laboratory, Corvallis, OR.
Karen McBee, Department of Zoology,
Oklahoma State University, Stillwater, OK
Gabriel Bitton, Department of Environmental Engineering Sciences,
University of Florida, Gainesville, FL.
Bernard J. Dutka, Canada Center for Inland Waters,
Burlington, Ontario, Canada.
Charles W. Hendricks, U.S. Environmental Protection Agency,
Corvallis Environmental Research Laboratory, Corvallis, OR.
6.1 GENERAL OVERVIEW OF TOXICITY TESTS -- Benjamin R. Parkhurst
and Greg Linder
6.1.1 Introduction
Toxicity to aquatic and terrestrial organisms including microbial populations is a
potential concern at hazardous waste sites. Toxicity tests, when combined with
chemical analyses, may show that adverse effects were caused by toxic chemicals
originating from the hazardous waste site. This information, used in conjunction
with field surveys which show that adverse ecological effects have occurred, can be
used to establish a link between hazardous wastes and adverse ecological responses.
Without field and laboratory data, other potential causes of the observed effects, such
as habitat alteration or natural variability, which are not directly related to the toxic
effects of the hazardous wastes, cannot be eliminated.
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This chapter reviews the application of environmental toxicology to hazardous waste
site evaluations. This information would be used to help assess the potential role of
toxic hazardous wastes in causing adverse ecological effects.
6.1.2 Alternative Approaches to Assessing Toxicity
The toxicity of environmental media potentially contaminated by hazardous wastes
can be estimated using two approaches: a toxicity-based approach or a chemistry-
based approach. In the toxicity-based approach, toxicity tests directly measure toxic
effects. Toxicity testing involves the measurement of a biological effect (e.g., death)
associated with exposure to complex mixtures in instances when the mechanisms of
the observed effect are not readily apparent and the specific causes of the effect are
often unknown. The toxicity-based approach was developed for measuring and
regulating the toxicity of complex effluents discharged to surface waters (U.S. EPA
1985). It has also been used to identify and characterize toxic wastes under Resource
Conservation and Recovery Act (RCRA) regulations (Millemann and Parkhurst
1980) and the Superfund Acts (Greene et al. 1988).
In the chemistry-based approach, chemical analyses and laboratory-generated water
quality (or air, soil, or sediment) criteria are used to estimate toxicity. For example,
if concentrations of specific chemicals in surface waters (or air, soil, or sediment)
exceed criteria values, then the concentrations are considered to be toxic. The
chemistry-based approach is also used for regulating waste water discharges under
the Clean Water Act and to characterize toxic wastes under RCRA and Superfund.
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Rationale for using the toxicity-based approach include:
Water and air quality criteria are available for relatively few chemicals
potentially present in hazardous wastes. Soil and sediment quality criteria are
not yet available for any chemicals.
Water, air, soil, and sediment quality criteria do not account for additive,
synergistic, or antagonistic interactions among toxic chemicals in a complex
mixture.
Toxicity tests measure the aggregate toxicity of all constituents in a complex
mixture, including additive, synergistic, and antagonistic effects.
Chemical analyses for complex mixtures (many chemicals present), especially
for organics, can be more expensive than toxicity testing.
The specific chemicals analyzed in complex mixtures may not include many
toxic chemicals actually present.
It is not always clear from chemical data which compounds are causing toxicity
in a complex hazardous waste mixture.
The bioavailability of toxic chemicals is evaluated with toxicity tests but not
with chemical analyses; therefore, chemical data may over- or under-estimate
the toxicities of single chemicals.
The chemistry-based approach may be appropriate for:
• Simple mixtures (few chemicals present), where chemical analyses can be less
expensive than toxicity testing;
• Specific problem chemicals, such as carcinogens or bioaccumulative chemicals,
which can be directly measured; and
• Designing treatment systems, which are more easily designed to remove
specific chemicals than to reduce a generic parameter such as toxicity.
Both of these approaches complement each other, and depending on site-specific
conditions, either or both may be appropriate for assessing the toxicity of
environmental media contaminated by hazardous wastes. However, it is now
generally considered that for complex chemical mixtures of unknown composition,
such as hazardous waste site samples, the toxicity-based approach is better for
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estimating potential toxicity (Bergman et al. 1986; U.S. EPA 1985; U.S. FWS 1987;
Greene et al. 1988).
6.1.3 Toxicity Data
Toxicity tests can provide data on the acute (short-term) and chronic (long-term)
toxicity of contaminated media to aquatic and terrestrial biota. These tests are
generally conducted using standard, laboratory test species; but in some cases, tests
on resident species may be appropriate. If the test species are representative of
sensitive, resident species, the toxicity data may provide an assessment of the
potential for causing the adverse effects measured in field surveys.
Toxicity tests are generally run in toxicology laboratories on samples collected at the
site. Most tests are static or static-renewal tests. Flow-through aquatic or
atmospheric tests may also be conducted on-site in a mobile laboratory; alternatively,
in situ toxicity tests, can be done to provide realistic, continuous exposures to
ambient concentrations of hazardous wastes. For m situ toxicity tests, test
organisms are exposed on site by placing them into containers, establishing and
monitoring vegetation plots, marking and then recapturing animals or a similar
approach. The test species can be either standard laboratory or resident species.
Three types of endpoints are derived from the acute and chronic toxicity tests:
(1) percent survival of the test organisms in 100% site sample (water, soil, or
sediment) in laboratory tests or in situ exposures; (2) a concentration-percent
survival relationship for laboratory tests run at several test concentrations of the
surface water, soil, or sediment; and (3) estimates of LC50s (e.g. mortality), EC50s
(e.g. growth and reproduction), MATCs, etc. Methods for analyzing these different
types of toxicity data are discussed by Peltier and Weber (1985), Horning and Weber
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(1985), Rand and Petrocelli (J.985), Dixon et al. (1985), Finney (1978), and
Montgomery and Peck (1982).
The survival data for 100% test concentrations and the m situ exposure data provide
information on the direct toxicity of ambient concentrations of hazardous waste
chemicals. These data can be directly compared to survey data to assess probable
sources and causes of toxic effects. For example, if a 100% concentration of the test
material in a laboratory (or in situ) exposure caused mortality to fathead minnows,
and the fish community of the site is affected, then there is a high probability that
toxicity is causing the adverse effects. The concentration-percent survival
relationship could be used to extrapolate the toxicity data to sites with decreasing
concentrations of the hazardous waste materials. The LC50 and MATC estimates are
most useful for comparisons of toxicity among different samples or sites.
Acute tests measure lethal effects, but sublethal effects (e.g., behavior) can also be
measured. Acute toxicity test results are usually expressed as LC50s (the
concentration of a chemical or mixture in the exposure medium which is estimated to
be lethal to 50% of the test organisms), EC50s (the concentration of a chemical or
mixture in the exposure medium that is estimated to have a sublethal effect to 50% of
the test organisms), or LD50s (the dose of a chemical or mixture in the organism that
is estimated to be lethal to 50% of the test organisms) for the test duration. For
example, the 96-hour LC50 is the estimated concentration that will kill 50% of the
test organisms in 96 hours of exposure. Other effect levels besides 50%, (e.g., the
LCI) can be estimated. Concentration versus effect relationships can be determined
by analyzing the data using various regression techniques (Finney 1978;
Montgomery and Peck 1982; Dixon et al. 1985).
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LCSOs are generally used in reference to aquatic toxicity test results in which
exposure is measured as the concentration of the toxic material. LC50s are also used
in reference to terrestrial toxicity test results with atmospheric gases and soils.
LDSOs are generally used in reference to laboratory toxicity tests with chemicals that
are ingested or assimilated by animals or plants. In such tests, exposure is measured
as the dose of the chemical the organism receives.
Chronic tests potentially detect both chronic lethal and sublethal toxicity, such as
effects on growth and reproduction. Chronic test results can be expressed in the same
manner as acute test results, but they are often expressed as estimates of acceptable
concentrations or toxicity threshold concentrations. For example, the MATC
(maximum acceptable toxicant concentration) is usually presented as two test
concentrations. One, the NOEC (no-observed-effects-concentration), is the highest
test concentration that caused no statistically significant toxic effects. The NOEC is
an estimate of an acceptable concentration. The second, the LOEC (lowest-observed-
effects-concentration), is the lowest concentration that caused statistically
significant toxic effects. These two values, the NOEC and LOEC, span the toxicity
threshold for the chemical. The GMATC (geometric mean of the MATC, i.e., the
NOEC and LOEC) is an estimate of the chronic toxicity threshold. Peltier and Weber
(1985) and Horning and Weber (1985) provide detailed discussions of these toxicity
values and methods for their calculation.
6.1.4 Integration of Toxicity Tests with Field Surveys
Field surveys can identify adversely affected communities and can provide
information for assessing adverse ecological effects potentially caused by hazardous
wastes. However, field surveys alone can not identify causes of effects. Toxicity tests
in conjunction with appropriate chemical data can establish potential causes. The
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actual causes may be hazardous wastes, but effects could also be caused by habitat
degradation, external sources of toxic chemicals, natural variability, etc.
In general, toxicity data and field survey results should be integrated using, for
example, exploratory data analysis. These preliminary analyses should be
considered part of the site assessment, but the relationships between the toxicity-
derived and field-derived data sets will be correlative and suggest cause-effect
relationships. Possible cause and effect relationships can be supported by chemical
analyses. In complex mixtures, however, it may be impossible to determine which
chemical or chemicals are causing toxicity. Various fractionation and toxicity
identification techniques are used to more completely evaluate the causative toxic
chemicals in complex mixtures (Parkhurst 1986; U.S. EPA 1985; U.S. EPA 1988).
6.1.5 State of the Science
The state of the science for environmental toxicology is reviewed briefly below. The
discussion is largely based on aquatic toxicology, since this area is generally more
developed than others. However, most of the discussion should be relevant to other
areas of environmental toxicology.
6.1.5.1 Test Species
Toxicity tests that are used to identify probable sources and causes of toxic effects at
hazardous waste sites should use species representative of the ecosystem being
assessed. It is not necessary to use test species from the ecosystem in question, as
long as the species used are representative of the ecosystem. Sensitivities of aquatic
biota to toxic chemicals vary widely among species. Sensitivities vary less within
taxa (i.e., among species of the same genera) and within similar classes of chemicals
such as non-pesticide organics, pesticides, inorganics, and metals (LeBlanc 1984;
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Slooff et al. 1986). Kenaga (1979) reported that, given the LC50 for a particular
chemical and species, relatively reliable LC50s can be calculated (through the use of
empirically derived equations) for the effect of the same chemical on other species.
LeBlanc (1984) found that algae, invertebrates, and fish responded similarly to non-
pesticide organics, but the sensitivities of fish and invertebrates to pesticides were
not highly correlated. A high correlation was determined in sensitivities offish and
invertebrates to metals, but the degree of sensitivity varied by an order of magnitude.
These studies indicate that the comparative sensitivities of aquatic organisms
depend on their phyletic relationships and on the type of chemical (Slooff et al. 1986).
6.1.5.2 Use of Acute Toxicity Data to Predict Chronic Toxicity
It appears that for similar classes of chemicals and similar taxa, acute-to-chronic
ratios established for one species and chemical can be used to estimate the chronic
toxicity of the chemical to another species. Such extrapolations should only be made
for the same types of tests conducted under the same conditions (e.g., water quality,
life stage).
Kenaga (1979) reported that the LC50 is not useful for predictions of chronic toxicity.
However, Slooff et al. (1986) found that the uncertainty in predicting chronic toxicity
from acute toxicity data for a given species is smaller than the uncertainty in
predicting acute toxicity between species. The U.S. EPA (1986) makes extensive use
of species acute-to-chronic ratios in the derivation of water quality criteria for toxic
chemicals.
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6.1.5.3 Use of Short-Term Tests to Predict Chronic Toxicity
Several short-term tests have been designed to estimate chronic toxicities. Tests
such as the 7-day Ceriodaphnia sp., 7-day fathead minnow, 21-day IX magna tests,
and 30 to 90 day fish early life stage (ELS) tests, are widely used to predict the
chronic toxicities of chemicals and mixtures (Mount and Norberg 1984, 1985; Rand
and Petrocelli 1985; McKim 1985; Urban and Cook 1986; ASTM 1988). Life-stage
sensitivities vary greatly within species. Fry and larvae are often the most sensitive
stages for fish, while eggs are relatively resistant. Beyond the fry or larval stage,
sensitivity often decreases as size increases. Consequently, in full life cycle
exposures, the sensitivity of early life stages will largely determine the sensitivity of
the species to the chemical. Thus, ELS tests generally provide good estimates of the
effects of full life cycle chronic exposures (McKim 1977, 1985; Macek and Sleight
1977). Kenaga (1979) also found that MATCs derived from critical life stages
(usually eggs and fry) of fish appear to be good substitutes for MATCs derived from
complete life cycle toxicity tests. These tests are generally considered to provide good
estimates of chronic toxicity endpoints in much less time and at much less cost than
full life cycle tests. Consequently, more materials and species can be tested. Field
validation studies have supported the validity of using these short-term tests to
predict population- and community-level effects in situ (U.S. EPA 1985).
6.1.5.4 Extrapolation of Laboratory Results to Predict In Situ Toxicity
Laboratory acute and chronic tests appear to be reasonable models of toxicity in
receiving waters under similar exposure conditions (U.S. EPA 1985). Parkhurst
(1987) found that laboratory test results could provide good estimates of in situ
toxicity for the same species, if the laboratory test conditions (e.g., water quality, test
species strain and size) closely simulated in situ conditions. The degree of correlation
is directly related to the amount of similarity between laboratory and field
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conditions. Laboratory tests may be conservative estimators of in situ toxicity
because in nature many chemicals degrade, transform, complex, precipitate, or
adsorb, which reduces their bioavailability (Kimerle et al. 1986).
6.1.5.5 Use of Single-Species Test Results to Predict Population, Community,
and Ecosystem Effects
A concern frequently raised in the use of single-species toxicity tests is that these
tests fail to measure higher-level ecological effects, such as effects on interspecies
interactions, ecosystem structure, and ecosystem function (Cairns 1985).
Consequently, assessments based on single-species toxicity tests may not adequately
predict ecosystem-level effects.
However, from the standpoint of assessing causes of adverse ecological effects, it is
not critical that single-species tests measure effects on ecosystem structure and
function. What is important is that assessments based on single-species tests identify
the probable sources and causes of toxic effects to ecosystem structure and function.
It is presently unknown whether interactions between species within a community
are more sensitive than the most sensitive component species (Mount 1985).
However, since all biological functions within an ecosystem are carried out by specific
organisms, community sensitivity should only be an expression of individual species
sensitivity. Thus, any function within an ecosystem should not be more sensitive
than the species that perform those functions. For single-species tests to be used to
adequately predict the probable sources and causes of these community functions
requires the use of adequately sensitive single-species tests.
Slooffs (1985) analysis of data for 38 compounds indicates that concentrations that
are acutely toxic to single species are usually not much greater than concentrations
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that are toxic at the ecosystem level. Whereas, concentrations that are toxic in
chronic single-species tests are, in most cases, overprotective of ecosystems. These
results imply that single-species tests have a certain predictive capability for higher-
order response levels.
At present, it appears that assessments of sources and causes of adverse ecological
effects based on toxicity tests with representative, sensitive, single species should be
adequate to identify causes of toxicity at the population, community, and ecosystem
level. If anything, assessments based on single-species test results appear to be
conservative estimators of higher-level effects. While work to date generally
suggests that assessments based on single-species tests will not lead to false
negatives, more field evaluations are necessary to support the hypotheses regarding
the robust characteristics of toxicity assessments.
6.1.5.6 Multi-Species Toxicity Tests
Multi-species tests are defined as tests that include more than one species in the test
chamber (Cairns 1985). Definitions and classifications for different types of multi-
species tests are not standardized. Multi-species tests include tests with two species,
such as predator-prey and competition tests; model ecosystems such as microcosms,
mesocosms, macrocosms, limnocorrals, and artificial streams; and field studies in
natural surface water bodies. Good reviews of multi-species test methods can be
found in Hammons (1981) and Cairns (1985).
Use of multi-species tests as research tools is widely accepted, but their use in impact
assessments has been limited, since it remains unclear whether such tests will
improve the results of the assessments. Historically, support for multi-species tests
in ecological assessments of toxic effects has been based, in part, on their
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hypothesized greater sensitivity than single-species tests. There is no consensus,
however, that multi-species tests are more sensitive than the individual species that
comprise those test systems. Because nearly all community functions can be
adequately performed by numerous species, the most important reason to use multi-
species tests may be that single-species tests are likely to be too sensitive. Multi-
species tests seem to be more important when undisturbed function and structure is
the goal, rather than, for example, when a sport fishery for an introduced species is
the goal (Mount 1985).
Microcosms and other model ecosystem tests have received limited use in toxicity
assessments, and their applicability appears to be much narrower. Multi-species
tests may be best suited for supplying information on a site- or subregion-specific
basis (Kooijman 1985).
Since, in the overall ecological assessment process, aquatic field surveys are used to
assess ecological effects, multi-species tests are not necessary to test for higher-level
ecological effects. A battery of sensitive single-species tests is adequate for
identifying sources and probable causes of toxicity at hazardous waste sites.
6.1.6 References
American Society for Testing and Materials (ASTM). 1988. 1988 Annual Book of
Standards. Section 11, Water and Water Engineering, Vol. 11.04. American Society
for Testing and Materials, Philadelphia, PA.
Bergman, H.L., R.A. Kimerle and A.W. Maki, eds. 1986. Environmental Hazard
Assessment of Effluents. Pergamon Press, Elmsford, NY.
Cairns, J., Jr., ed. 1985. Multispecies Toxicity Testing. Pergamon Press, Elmsford,
NY.
Dixon, W.J., M.B. Brown, L. Engelman, J.W. Frane, M.A. Hill, R.I. Jennrich, and
J.D. Toporek. 1985. BMDP Statistical Software. University of California Press,
Berkeley, CA. 734pp.
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Finney, D.J. 1978. Statistical Method in Biological Assay, Third Edition. Charles
Griffin and Company, Ltd., London.
Greene, J.C., W.J. Warren-Hicks, B.R. Parkhurst, G.L. Linder, C.L. Bartels, S.A.
Peterson, and W.E. Miller. 1988. Protocols for Acute Toxicity Screening of
Hazardous Waste Sites, Final Draft. U.S. Environmental Protection Agency,
Corvallis, OR. 145pp.
Hammons, A.S., ed. 1981. Ecotoxicological Test Systems: Proceedings of a Series of
Workshops. EPA/560/6-8/-004. Office of Toxic Substances, U.S. Environmental
Protection Agency, Washington, DC.
Horning, W.B., n, and C.I. Weber. 1985. Short-term methods for estimating the
chronic toxicity of effluents and receiving waters to freshwater organisms.
EPA/600/4-85/014. Environmental monitoring and Support Laboratory, Office of
Research and Development, U.S. Environmental Protection Agency, Cincinnati, OH.
Kenaga, E.E. 1979. Aquatic test organisms and methods useful for assessment of
chronic toxicity of chemicals. Pages 101-111. In: Dickson, K.L., A.W. Maki and J.
Cairns, Jr., eds. Analyzing the Hazard Evaluation Process. Water Quality Section,
American Fisheries Society, Bethesda, MD.
Kimerle, R.A., W.J. Adams and D.R. Grothe. 1986. A tiered approach to aquatic
safety assessment of effluents. Pages 247-264. In: H.L. Bergman, R.A. Kimerle and
A.W. Maki, eds. Environmental Hazard Assessment of Effluents. Pergamon Press,
Elmsford, NY.
Kopijman, S.A.L.M. 1985, Toxicity at population level. Pages 143-164. In: J.
Cairns, Jr., ed. Multispecies Toxicity Testing. Pergamon Press, Elmsford, NY.
LeBlanc, G.A. 1984. Interspecies relationships in acute toxicity of chemicals to
aquatic organisms. Environmental Toxicology and Chemistry. 3:47-60.
Macek, K.J. and B.H. Sleight. 1977. Utility of toxicity tests with embryos and fry of
fish in evaluating hazards associated with the chronic toxicity of chemicals to fishes.
Pages 137-146. In: F.L. Mayer and J.L. Hamelink, eds. Aquatic Toxicology and
Hazard Evaluation. ASTM STP 634. American Society for Testing and Materials,
Philadelphia, PA.
McKim, J.M. 1977. Evaluation of tests with early life stages of fish for predicting
long-term toxicity. J. Fish Res. Board Can. 34:1148-1154.
McKim, J.M. 1985. Early life stage toxicity tests. Pages 58-95. In: Rand, G.M. and
S.R. Petrocelli, eds. Fundamentals of Aquatic Toxicology: Methods and Applications.
Hemisphere Publishing Corp., New York, NY.
Milleman, R.E. and B.R. Parkhurst. 1980. Comparative toxicity of solid waste
leachates to Daphnia magna. Environ. Internat. 4:255-260.
Montgomery, D.E. and E.A. Peck. 1982. Introduction to Linear Regression. John
Wiley and Sons, New York, NY. 504 pp.
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Mount, D.I. 1985. Scientific problems in using multispecies tpxicity tests for
regulatory purposes. Pages 13-18. In: J. Cairns, Jr., ed. Multispecies Toxicity
Testing. Pergamon Press, Elmsford, NY.
Mount, D.I. and T.J. Norberg. 1984. A seven-day life cycle cladoceran toxicity test.
Env. Tox. Chem. 3:425-434.
Mount, D.I. and T.J. Norberg. 1985. A new subchronic fathead minnow (Pimephales
promelas) toxicity test. U.S. Environmental Protection Agency, Environmental
Research Laboratory, Duluth, MN.
Parkhurst, B.R. 1986. The role of fractionation in hazard assessments of complex
effluents. In: H.L. Bergman, R.A. Kimerle and A.W. Maki, eds. Environmental
Hazard Assessment of Effluents. Pergamon Press, Elmsford, NY.
Parkhurst, B.R. 1987. A comparison of laboratory and in situ bioassays for
evaluating the toxicity of acidic waters to brook trout. Ph.D. Dissertation, University
of Wyoming, Laramie, WY.
Peltier, W. and C.I. Weber. 1985. Methods for Measuring the Acute Toxicity of
Effluents to Aquatic Organisms. Third Edition. EPA/600/4-85/013. Environmental
Monitoring and Support Laboratory, Office of Research and Development, U.S.
Environmental Protection Agency, Cincinnati, OH.
Rand, G.M. and S.R. Petrocelli, eds. 1985. Fundamentals of Aquatic Toxicology:
Methods and Applications. Hemisphere Publishing Corp., New York, NY.
Slooff, W. 1985. The role of multispecies testing in aquatic toxicology. Pages 45-60.
In: J. Cairns, Jr., ed. Multispecies Toxicity Testing. Pergamon Press, ElmsTord, NY.
Slooff, W., J.A.M. van Oers and D. de Zwart. 1986. Margins of uncertainty in
ecotoxicological hazard assessment. Environmental Toxicology and Chemistry.
5:841-852.
U.S. Environmental Protection Agency. 1985. Technical support document for water
quality-based toxics control. Office of Water, U.S. Environmental Protection Agency,
Washington, DC.
U.S. Environmental Protection Agency. 1986. Quality criteria for water 1986.
EPA/440/5-86/001. Office of Water Regulations and Standards, U.S. Environmental
Protection Agency, Washington, DC.
U.S. Environmental Protection Agency. 1988. Methods for aquatic toxicity
identification evaluations. Phase I: Toxicity characterization procedures (Draft)
Office of Research and Development, U.S. Environmental Protection Agency,
Washington, DC.
U.S. Department of Interior. 1987. Type B technical information, Injury to Fish and
Wildlife Species, CERCLA Project 301. Washington, DC.
Urban, D.J and N.J. Cook. 1986. Hazard evaluation division standard evaluation
procedure: Ecological risk assessment. EPA/540/9-85/001. Office of Pesticide
Programs, U.S. Environmental Protection Agency, Washington, DC.
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6.2 AQUATIC TOXICITY TESTS » Benjamin R. Parkhurst
6.2.1 Introduction
Aquatic toxicology has been widely used to assess toxic effects of complex chemical
mixtures to aquatic ecosystems (Bergman et al. 1986). Development of standardized,
consensus methods for aquatic toxicity testing is more advanced than other areas of
environmental toxicology. Most tests developed for testing complex mixtures are
directly applicable to hazardous waste site testing, with few modifications. A
sufficient number of standardized, "off-the-shelf tests are presently available to fill
most testing needs for ecological assessments of hazardous waste sites.
6.2.2 Aquatic Toxicity Test Methods
The methods available for hazardous waste site assessments are grouped into two
categories: (1) Class I methods are off-the-shelf techniques that are widely accepted
and ready for general use; and (2) Class n methods are less widely used, or being
developed as applied methods pertinent to toxicity assessments for HWSs.
To meet the goal of yielding the most information on a cost-effective basis and being
easily interpreted by decision makers, toxicity tests used in hazardous waste site
assessments should use standardized, generally accepted methods that can be
performed with a reasonable amount of time, money, effort, and expertise. Many
aquatic toxicity tests have been standardized, and tests are presently available to
meet most testing needs for hazardous waste site assessments. The sediment toxicity
tests discussed in this chapter, although not yet standardized, are in widespread use
and are considered applicable for general use.
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6.2.2.1 Test Species
Species used in aquatic toxicity tests may include virtually any species that can be
maintained in laboratory (or in situ) exposure chambers. However, as discussed in
section 6.2.3.3, it is usually not necessary to conduct tests on resident species. The
tests recommended in the following subsections use primarily standard laboratory
test species.
6.2.2.2 Dilution Water
Of special concern is the source and quality of dilution water used in toxicity tests.
Two options are available: (1) use site dilution water, collected upstream of the
potential source of hazardous waste toxicity; or (2) use a reconstituted dilution water,
which is similar to on-site water in respect to pH, hardness, alkalinity, and salinity
(Peltier and Weber 1985; Weber et al. 1988). Choice of method will depend on site-
specific considerations. It is generally preferable to use site dilution water; however,
if this water is toxic, it may not be usable; alternatively, the toxicity of the dilution
water can be factored into the analysis of the toxicity of the test material (U.S. EPA
1985).
6.2.2.3 Laboratory and QA/QC Requirements
Peltier and Weber (1985), Horning and Weber (1985), and Weber et al. (1988) provide
detailed descriptions of laboratory and QA/QC requirements for aquatic toxicity
testing. Virtually all tests can be run in either on-site or off-site laboratories.
6.2.2.4 Class 1 Methods
6.2.2.4.1 Acute Toxicity Methods. Many acute toxicity test methods have been
developed for both single chemical and complex mixture testing (OECD 1984; U.S.
EPA 1978a-b, 1982a-c, 1985; Peltier and Weber 1985; Rand and Petrocelli 1985;
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ASTM 1988; Greene et al. 1988). Acute test methods directly applicable to hazardous
waste site assessments are those used for whole effluent testing and whole sediment
testing.
(A) Acute Toxicity Methods: Aqueous Samples. Standardized, consensus
methods for conducting acute aquatic toxicity tests are available for a large
number of marine and freshwater fish, invertebrates, and plants. Inter- and
intra-laboratory comparisons have demonstrated that the reproducibility of
standardized toxicity tests can be as good as routine chemical analyses (U.S. EPA
1985). The following three tests are recommended.
(1) Peltier and Weber (1985). This manual describes flow-through, static-
renewal, and static methods for measuring the acute toxicity of effluents to a
wide variety of freshwater and marine fish as well as invertebrates. Static-
renewal or static procedures are generally used to test hazardous waste sites.
ASTM (1988) also describes similar methods for acute toxicity testing of
effluents and surface waters.
(2) Greene et al. (1988). This manual describes short-term methods
specifically designed for measuring the toxicity of solid and aqueous samples
from hazardous waste sites to Daphnia magna. IX pulex, algae (Selenastrum
capricornutum). and fathead minnows (Pimephales promelas). The toxicities
of solid samples to aquatic species are tested by preparing elutriates (see
section 6.3) for testing. Except for the preparation of the elutriates, these
methods are similar to Peltier and Weber (1985).
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(3) ASTM (1988). This manual describes a method for conducting static acute
toxicity tests with larvae of four species of marine bivalve mollusks, which are
not included in Peltier and Weber (1985).
(B) Acute Toxicity Methods: Sediment Samples. No standardized, consensus
sediment toxicity tests are yet available. However, several test methods are in
widespread use and are undergoing standardization by ASTM. In addition, the
tests listed in subsection 6.2.2.4.1 (A) are applicable to sediment testing with
minor modifications (see ASTM 1988).
6.2.2.4.2 Chronic Toxicity Methods. Chronic tests are, by definition, of longer
term than acute tests; but to be useful in the decision making process for hazardous
waste site assessments, information on toxicity must be obtained in a relatively short
time. Relatively few standardized, consensus methods are presently available for
doing chronic toxicity tests, primarily due to a lack of knowledge for culturing many
species through complete life cycles in the laboratory. A lack of knowledge of the
basic biology of many present and potential test species impedes the use of additional
species (Loewengart and Maki 1985). However, the reproducibility of chronic toxicity
tests can also be good (Parkhurst et al. 1981; U.S. EPA 1985).
Chronic toxicity tests that are of long duration will have less utility in assessing the
effects of hazardous waste sites than tests of short duration. In recent years, there
has been considerable effort devoted by the EPA and others to develop short-term
tests that accurately estimate the chronic toxicity of effluents and receiving waters.
These tests, recommended below, are directly applicable for hazardous waste site
evaluations.
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(A) Chronic Toxicity Methods: Aqueous Samples.
(1) Horning and Weber (1985). This manual describes four short-term tests
useful for estimating the chronic toxicity of waters contaminated by hazardous
wastes to three freshwater species: (1) the alga, Selenastrum capricornutum;
(2) fathead minnows; and (3) Ceriodaphnia dubia. These procedures are
presently applied to test the chronic toxicities of a wide variety of effluents and
should be applicable to most hazardous waste site assessments.
(2) Weber et al. (1988). This manual describes marine and estuarine tests,
analogous to the freshwater tests described above, for sheepshead minnow
(Cyprinodon variegatus), inland silverside (Menidia beryllina), the mysid
(Mysidopsis bahia). the sea urchin (Arbacia punctulata). and the alga
(Champia parvula).
(3) ASTM (1988). The ASTM 1988 Annual Book of Standards describes life-
cycle toxicity tests for Daphnia magna and saltwater mysids, and early life
stage tests for a variety offish species. These tests are of longer duration (21 to
120 days, depending on the species) than those described above. They may be
desirable for answering questions of special interest at some hazardous waste
sites.
(B) Chronic Toxicity Methods: Sediment Samples. No standardized,
consensus methods for chronic toxicity testing of sediments are yet available.
6.2.2.5 Class 11 Methods
6.2.2.5.1 Acute Toxicity Methods: Aqueous Samples. Although acute, aquatic
toxicity test methods are continually being refined and improved, the test methods
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listed in section 6.2.2.4.1 (A) above are sufficient to conduct hazardous waste site
assessments at this time.
In situ toxicity tests are an alternative testing procedure that would provide realistic,
continuous exposures to ambient concentrations of hazardous waste chemicals at
lower cost than with a mobile laboratory. Test organisms (e.g., fish) are placed in
cages in site waters to test toxicity in situ (Johnson et al. 1987; Parkhurst 1987).
These tests are relatively simple to perform, but the methods lack standardization.
6.2.2.5.2 Acute Toxicity Methods: Sediment Samples. Acute, sediment toxicity
tests are under development, but are currently restricted to macroinvertebrates for
both freshwater and marine testing. Standardization of several methods is under
way by ASTM. However, some methods (freshwater midge, freshwater and marine
amphipods), have undergone some standardization and are in sufficiently widespread
use to be considered ready for general use. Currently, the draft ASTM methods are
recommended for sediment toxicity tests for freshwater and marine sediments.
(Copies of these drafts may be obtained by contacting the chair of ASTM
subcommittee E-47.03 for Sediment Toxicology at ASTM Headquarters in
Philadelphia, PA).
6.2.2.5.3 Chronic Toxicity Methods: Aqueous Samples. Many chronic tests
methods are potentially available for hazardous waste site assessments (see Rand
and Petrocelli 1985), but most are of too long duration for practical use. Several
standardized chronic toxicity test methods are under development by ASTM
Committee E-47; however, the methods listed in section 6.2.2.4.2 (B) should be
adequate for doing chronic toxicity assessments at most hazardous waste sites.
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6.2.2.5.4 Chronic Toxicity Methods: Sediment Samples. No standardized or
consensus chronic sediment toxicity tests are yet available for either freshwater or
marine testing. However, some non-standardized chronic sediment tests are
available (see Swartz 1987 for a review of test methods).
6.2.3 Methods Integration
The sequential approach outlined below is one of many available to those who use
these methods and may suggest appropriate toxicity tests for hazardous waste site
evaluations and for integrating methods. The approach consists of the following
steps: (1) identify surface waters; (2) assess adverse ecological effects; (3) conduct
acute toxicity tests; (4) evaluate acute toxicity; (5) conduct chronic toxicity tests; and
(6) evaluate chronic toxicity. These steps are discussed in the following subsections.
6.2.3.1 Identify Surface Waters
For each candidate site for an ecological assessment, identify all surface waters that
potentially contain aquatic biota. If surface waters are not present or if, because of
habitat or flow limitations, they can not support a significant aquatic community,
then there is no need for aquatic toxicity testing. If surface waters are present and
they sustain or could sustain an aquatic community potentially affected by hazardous
wastes, then toxicity testing is appropriate to assess the probable sources and causes
of adverse ecological effects.
6.2.3.2 Assess Adverse Ecological Effects
The aquatic field survey methods described in section 8.2 provide the data necessary
to assess adverse ecological effects potentially caused by hazardous wastes. The
survey identifies specific, adversely affected aquatic communities and the extent of
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the effect. At this point, the actual cause of those impacts are unknown, but may
include toxic hazardous wastes.
6.2.3.3 Conduct Acute Toxicity Tests
If adversely affected aquatic communities are identified, conduct acute toxicity tests
on potentially contaminated surface water and sediment samples, using a battery of
tests and test species, including species representative of each community. If
adversely affected communities are not found, testing may be desirable to confirm the
lack of toxicity.
As noted in section 6.2.2.1, species selected as test organisms do not have to include
resident species, but should include those standard, laboratory test species that are
taxonomically, ecologically, and/or physiologically most similar to resident species.
For example, Daphnia spp. could be surrogates for resident zooplankton,
Selenastrum capricornutum could be a surrogate for resident algae, fathead minnows
could be surrogates for resident warmwater fish, Lemna minor could be a surrogate
for resident aquatic macrophytes, etc. It may not be necessary to conduct tests for
surrogates of communities for which no ecological effects were identified in the
aquatic surveys. For example, if aquatic macrophytes communities are not adversely
affected, it may not be necessary to do aquatic macrophyte toxicity tests. Again, if
adversely affected communities are not apparent, testing may still be desired to
confirm the lack of toxicity.
6.2.3.4 Evaluate Acute Toxicity
The acute toxicity test results provide quantitative information on the direct toxicity
of ambient concentrations of hazardous waste chemicals. These data can be directly
compared to aquatic survey data to assess probable sources and causes of toxic effects.
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For example, if 100% solution causes mortality to fathead minnows in the laboratory
or in situ, and the fish community of the site is adversely affected, then there is a high
probability that toxicity is causing the effect. The concentration-percent survival
relationship could be used to extrapolate the toxicity data to downstream sites with
decreasing concentrations of the hazardous waste solutions. The LC50 data would be
most useful for comparisons of acute toxicity among different samples or sites.
6.2.3.5 Conduct Chronic Toxicity Tests
If no acute toxicity is detected, but adverse ecological effects are apparent, then
chronic toxicity tests should be run. Chronic tests may also be run to confirm the
presence or absence of toxicity, regardless of the presence of adverse ecological effects.
Refer to section 6.2.2.4 for guidance on selection of tests to run.
6.2.3.6 Evaluate Chronic Toxicity
Chronic tests potentially detect both chronic lethal and sublethal toxicity, such as
effects on growth or reproduction. These data are used to assess probable causes and
sources of adverse ecological effects in the same manner as for acute toxicity data.
Methods for analyzing and interpreting chronic toxicity data are provided in Chapter
9.
6.2.4 Case Studies
A series of studies conducted by the EPA have established that the results of ambient
toxicity tests are generally significantly correlated with effects to periphyton,
zooplankton, benthic macroinvertebrates and fish (Mount et al. 1984; Mount and
Norberg-King 1985; Mount et al. 1986a; Mount et al. 1986b; Norberg-King and
Mount 1986; Mount et al. 1986c; Mount and Norberg-King 1986).
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6.2.5 References
American Society for Testing and Materials (ASTM). 1988. 1988 Annual Book of
Standards. Section 11, Water and Water Engineering, Vol. 11.04. American Society
for Testing and Materials, Philadelphia, PA.
Bergman, H.L., R.A. Kimerle and A.W. Maki, eds. 1986. Environmental Hazard
Assessment of Effluents. Pergamon Press, Elmsford, NY.
Greene, J.C., W.J. Warren-Hicks, B.R. Parkhurst, G.L. Linder, C.L. Bartels, S.A.
Peterson, and W.E. Miller. 1988. Protocols for Acute Toxicity Screening of
Hazardous Waste Sites, Final Draft. U.S. Environmental Protection Agency,
Corvallis, OR.
Horning, W.B., n, and C.I. Weber. 1985. Short-term methods for estimating the
chronic toxicity of effluents and receiving waters to freshwater organisms.
EPA/600/4-85/014. Environmental Monitoring and Support Laboratory, Office of
Research and Development, U.S. Environmental Protection Agency, Cincinnati, OH.
Johnson, D.W., H.A. Simonin, J.R. Colquhoun, and F.R. Flack. 1987. In situ toxicity
of fishes in acid waters. Biogeochemistry. 3:181-208.
Loewengart, G. and A.W. Maki. 1985. Multispecies toxicity tests in the safety
assessment of chemicals: Necessity or curiosity? Pages 1-12. In: J. Cairns, Jr., ed.
Multispecies Toxicity Testing. Pergamon Press, Elmsford, NY.
Mount, D.I., N. Thomas, M. Barbour, T. Norberg, T. Roush, and R. Brandes. 1984.
Effluent and ambient toxicity testing and instream community response on the
Ottawa River, Lima, Ohio. EPA/600/2-84/080. Permits Division, Office of research
and Development, Duluth, MN.
Mount, D.I. and T.J. Norberg-King, eds. 1985. Validity of effluent and ambient
toxicity tests for predicting biological impact, Scippor Creek, Circleville, Ohio.
EPA/600-3085/044. U.S. Environmental Protection Agency.
Mount, D.I. and T. Nprberg-King. 1986. Validity of effluent and ambient toxicity
tests for predicting biological impact, Kanawha River, Charleston, West Virginia.
EPA/600/3-86/006. U.S. Environmental Protection Agency.
Mount, D.I., A.E. Steen, and T. Norberg-King. 1986a. Validity of effluent and
ambient toxicity tests for predicting biological impact, Back River, Baltimore
Harbor, Maryland. EPA/600/8-86/001. U.S. Environmental Protection Agency.
Mount, D.I. , T. Norberg-King, and A.E. Steen. 1986b. Validity of effluent and
ambient toxicity tests for predicting biological impact, Naugatuck River, Waterbury,
Connecticut. EPA/600/8-86/005. U.S. Environmental Protection Agency.
Mount, D.I. , A.E. Steen, and T. Norberg-King. 1986c. Validity of effluent and
ambient toxicity tests for predicting biological impact, Ohio River, Wheeling, West
Virginia. EPA/600/3-85/071. U.S. Environmental Protection Agency.
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Norberg-King, T. and D.I. Mount. 1986. Validity of effluent and ambient toxicity
tests for predicting biological impact, Skeleton Creek, Enid, Oklahoma. EPA/600-
3085/044. U.S. Environmental Protection Agency.
Organization of Economic Cooperation and Development (OECD). 1984. Guidelines
for testing chemicals. Section 4: Health effects. Director of Information, OECD, 2,
Rue Andre-Pascal, 75775 Paris CEDEX 16, France.
Parkhurst, B.R. 1987. A comparison of laboratory and in situ bioassays for
evaluating the toxicity of acidic waters to brook trout. Ph.D. Dissertation, University
of Wyoming, Laramie, WY.
Parkhurst, B.R., J.L. Forte and G.P. Wright. 1981. Reproducibility of a life cycle
toxicity test with Daphnia magna. Bulletin of Environmental Contamination and
Toxicology. 26:1-8.
Peltier, W. and C.I. Weber. 1985. Methods for Measuring the Acute Toxicity of
Effluents to Aquatic Organisms. Third Edition. EPA/600/4-85/013. Environmental
Monitoring and Support Laboratory, Office of Research and Development, U.S.
Environmental Protection Agency, Cincinnati, OH.
Rand, G.M. and S.R. Petrocelli, eds. 1985. Fundamentals of Aquatic Toxicology:
Methods and Applications. Hemisphere Publishing Corp., New York, NY.
Swartz, R.C. 1987. Toxicological methods for determining the effects of
contaminated sediments on marine organisms, Chapter 14. In: Dickson, K.L., A.L.
Maki and W.A. Brungs, eds. Fate and Effects of Sediment-Bound Chemicals in
Aquatic Systems. Pergamon Press, New York, NY.
U.S. Environmental Protection Agency. 1978a. Directory of short term tests for
health and ecological effects. EPA/600/1-78/052. U.S. Environmental Protection
Agency, Washington, DC.
U.S. Environmental Protection Agency. 1978b. Short-term tests for health and
ecological effects. Part 1: Program overview and Part 2: Directory of tests.
EPA/600/9-78/037. Office of Research and Development, U.S. Environmental
Protection Agency, Washington, DC.
U.S. Environmental Protection Agency. 1982a. Environmental effects test
guidelines. EPA/560/6-82/002. U.S. Environmental Protection Agency, Washington,
JJv^.
U.S. Environmental Protection Agency. 1982b. Pesticide assessment guidelines.
EPA/540/9-82/018 through 028. Office of Pesticide Programs, U.S. Environmental
Protection Agency, Washington, DC.
U.S. Environmental Protection Agency. 1982c. Toxic substances test guidelines.
EPA/6-82-001 through 003. Office of Toxic Substances, U.S. Environmental
Protection Agency, Washington, DC.
U.S. Environmental Protection Agency. 1985. Technical support document for water
quality-based toxics control. Office of Water, U.S. Environmental Protection Agency,
Washington, DC.
Weber, C.I., W.I. Horning, D.J. Klemm, T.W. Neiheisel, P.A. Lewis, E.L. Robinson, J.
Menkedick, and F. Kessler. 1988. Short-term methods for estimating the chronic
toxicity of efluents and receiving waters to marine and estuarine organisms. (Draft)
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EPA/600/4-87/028. Environmental Monitoring and Support Laboratory, Office of
Research and Development, U.S. Environmental Protection Agency, Cincinnati, OH.
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6.3 TERRESTRIAL TOXICITY TESTS -- Greg Under and Karen McBee
6.3.1 Introduction
Terrestrial toxicity tests for soils and sediments from hazardous waste sites are less
developed than aquatic toxicity tests (Fava et al. 1987). Although few terrestrial test
methods have been standardized (OECD 1984), methods-standardization efforts have
been initiated by the U.S. EPA (Greene et al. 1988a). The laboratory toxicity tests
discussed in this section evaluate both the direct (e.g., soils and sediments) and
indirect (e.g., laboratory-derived eluates from soils) toxicity of soil or sediment
samples.
6.3.2 Terrestrial Toxicity Test Methods
6.3.2.1 Class I Methods
The toxicity tests summarized below represent a battery of Class I, single-species
bioassays that have been used in toxicity assessments for hazardous waste site-soil
and sediment samples (see Figure 6-1). For the most part, they are short-term tests
for assessing the acute toxicity of soils or sediments. Standardized tests for assessing
chronic toxicity are currently unavailable except for an algal toxicity test included in
the terrestrial test battery. Complete listings of laboratory facilities and test
requirements for Class I tests are found in Greene et al. (1988a). Summary outlines
of these terrestrial toxicity tests follow. For additional information, consult Greene
et al. (1988b), Peltier and Weber (1985), and Horning and Weber (1985).
6.3.2.1.1 Soil and Sediment Preparations. Soil and sediment samples from
hazardous waste sites are heterogeneous mixtures of natural chemicals in the
substrate matrix (e.g., clays and silts, and sands in varying proportions) (Bohn et al.
1979; Brady 1974), along with anthropogenic chemicals that may be present as
contaminants (Morrill et al. 1982). Field sampling of soils and sediments is the most
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Soil and
Sediment
Sample
Soil and
Sediment
Eluate
Surface Water
and
Ground Water
Earthworm
Seed Germination
Root Elongation
Cladoceran
Algae
Fish
Eisenia
foetida
Latuca
sativa L.
Latuca
iativa L.
Daphnia
magna
Selenastrum
capricornutum
Pimephales
promelas
Figure 6-1. Battery of single-species bioassays for various types of
environmental samples.
critical step in any terrestrial toxicity assessment, but particularly for those
assessments that derive toxicity estimates from samples sent to off-site laboratories.
Transit times and storage conditions during shipment potentially confound toxicity
estimates generated by laboratories located great distances from the site itself.
Depending upon site-specific considerations, soil and sediment samples should be
taken at the same sites and times as chemical samples.
Earthworm and seed germination tests (see Figure 6-1) require the site sample to be
screened through a 1/4" soil sieve prior to testing. The samples are mixed with
artificial soil to produce a series of test soil concentrations. Greene et al. (1988a)
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should be consulted for complete details on sample preparation, testing, and data
analysis.
6.3.2.1.2 Eluate Preparations from Site Soils and Sediments. Eluates are
prepared from untreated site soils and sediments to evaluate the mobility of chemical
constituents in hazardous wastes. Site samples are mixed with four milliliters of
deionized water per gram (dry weight) soil or sediment. The slurry is then mixed in
total darkness for 48 hours at 20° ± 2°C. After mixing, the resulting eluate is
centrifuged and then filtered through a 0.45 pm cellulose acetate or glass fiber filter.
Original sample moisture is incorporated into the eluate sample during its
preparation. Hence, a constant "solute/solvent" ratio is assured during the extraction
of any site sample.
6.3.2.1.3 Terrestrial Bioassays Performed on Site Soils and Sediments. Brief
outlines of test procedures are presented in groups according to the type of sample
being analyzed, as follows: (1) direct measures of soil and sediment toxicity derived
from terrestrial bioassays, including a 14-day earthworm test and a 5-day seed
germination test; and (2) indirect measures of toxicity derived using aquatic and
terrestrial test systems, including a 4-day Selenastrum capricornutum test, the 2-day
daphnid (Daphnia magna or Daphnia pulex) and fathead minnow (Pimephales
promelas) tests, and the 5-day root elongation test.
(A) Eisenia foetida (Earthworm) 14-day Soil Acute Toxicity Test.
Earthworms improve soil aeration, drainage, and fertility within terrestrial
environments (Edwards and Lofty 1972) and are considered representative soil
macroinvertebrates. The test represents a modification of a method developed by
Goats and Edwards (1982). Eisenia foetida is used in these tests since it is easily
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cultured in the laboratory, reaches maturity in 7 to 8 weeks at 25"C, and is
responsive to a wide range of toxicants. Earthworms are exposed to toxicant
solubles in soil moisture and by direct contact with or ingestion of chemicals
adsorbed on soil (Callahan et al. 1985).
Test soil concentrations should include a range of site soil or sediment
concentrations (e.g., 80%, 40%, 20%, 10%, 5% and 0% site-sample, dry weight site
sample/total dry weight). Artificial soil used in these preparations consists of 10%
sphagnum peat, 20% colloidal kaolinite clay, and 70% grade-70 silica sand by
weight. The site sample is incorporated into the artificial soil to yield a
homogeneous exposure medium with the desired site soil or sediment
concentrations. Soil moisture is adjusted to assure that the percent soil hydration
is similar in all test concentrations. Once exposure systems are prepared, ten
adult earthworms are added to three replicate chambers, and incubated at 20" ±
2"C for 14 days. Mortality is noted at the end of 14 days, and appropriate
statistical techniques are applied to derive the LC50.
(B) Seed Germination Toxicity Test. This test measures the effects of
hazardous wastes on seed germination, a critical stage in the developmental
biology of plants. The test outlined in Greene et al. (1988a) represents a
modification of the method of Thomas and Cline (1985). The primary test species
is lettuce (Butter Crunch), Lactuca sativa L., although others can be used.
The test procedure involves grading the seeds and then preparing exposure
systems using Petri dish bottoms and Ziploc bags. Treatments are set up to cover
a range of test soil concentrations (e.g., 80%, 40%, 20%, 10%, 5%, and 0% site
sample mixed with artificial soil). Test soils are loaded into Petri dish bottoms,
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and 40 seeds are planted per dish. After seeding, 16-mesh silica sand is layered
over the seeds, and the Petri dish is irrigated to 85% water holding capacity. The
Petri dish is then placed upright in a Ziploc bag and sealed, leaving as much air
space as possible inside. The sealed bags are placed in a growth chamber for 120
hours (24° ± 2°C); the first 48 hours are completed in total darkness and the
balance 16:8 hours light:dark. After 120 hours, the number of seeds that have
germinated in each dish is determined by counting the number of seedlings that
emerge above the soil surface. The LC50 is derived from statistical analysis on
the count data at 120 hours.
6.3.2.1.4 Aquatic Bioassays Performed on Eluates.
(A) Selenastrum capricornutum Toxicity Test. The ecological significance of
unicellular algae is widely recognized, particularly in regard to its function in
primary production and oxygen evolution. Algal communities may be inhibited or
stimulated by water quality changes.
The test involves adding algal cells to a series of concentrations of site surface
water, groundwater or site soil/sediment eluate. The typical test yields an
estimate of the EC50, as well as an evaluation of lethality. Following inoculation,
test flasks are incubated for 96 hours at 24°± 2°C and 4304 ± 430 lux
(continuous). Cell counts, measured manually or by electronic particle counters,
yield direct measures of algal biomass based upon cell counts and mean cell
volumes. ECSOs are estimated using appropriate statistical methods.
(B) Daphnia magna or D. pulex Toxicity Test. Soil and sediment eluates can
be tested using either Daphnia magna or IX pulex. Species of choice is dependent
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upon the hardness of the sample being tested; for samples with hardness less than
80 mg/L only IX pulex should be used as test species.
The test uses neonates less than 24-hour old, which are exposed to test
concentrations ranging from 100% to 0% site sample (control). The tests are
conducted at 22° ± 2°C (16:8 hours, light:dark); replicates of 10 neonates each are
placed into test chambers. Mortality is assessed at the end of the 48-hour
exposure and the LC50 is calculated.
(C) Fathead Minnow Short-Term Toxicity Test. Fathead minnows
(Pimephales promelas) are exposed for 48-hours to a logarithmic series of site-
sample eluates; hence, the method (adapted from Peltier and Weber 1985;
Horning and Weber 1985; and ASTM 1985) yields estimates of the acute toxicity
of site-sample eluates.
Exposures are performed at 20° ± 2°C (16:8 L:D), and use ten, 3 to 5 day-old
fathead minnows per test chamber. Mortality is measured at the termination of
the test, and LC50s are calculated as percent site-sample.estimates (LC50s),
expressed as percent site sample associated with 50% mortality.
(D) Root Elongation Toxicity Test. Root elongation is an important early
developmental event in the growth and survival of plants. Unlike the seed
germination test, the root elongation test evaluates only the water soluble
constituents of a sample. As a general rule, root elongation is more sensitive than
seed germination. This test may be done with a number of economically
important species that germinate and grow rapidly, e.g., lettuce (butter crunch,
Lactuca sativa L.).
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The test is done with graded seeds, which are placed in Petri dishes. A
logarithmic series of test concentrations plus controls (water samples, or soil or
sediment eluates) is prepared and added to filter paper-lined Petri dish bottoms.
The test solutions are absorbed by the filter paper in each Petri dish. The seeds
are placed on the filter papers and incubated in a darkened, humid container at
24U ± 2°C for 120 hours. At the end of the test, root length is measured, and an
estimate of the EC50 is calculated.
6.3.2.1.5 Quality Assurance/Quality Control. Quality assurance/quality control
(QA/QC) measures must be specified prior to initiating toxicity assessments.
Depending upon the site-specific DQOs, and the role that either laboratory or m situ
toxicity tests share in the ecological assessment for the site, project personnel must
delineate QA/QC guidelines appropriate to the assessment process. For laboratory
toxicity tests, a minimum QA/QC program must include specifications for: (1)
sampling and handling hazardous wastes; (2) the sources and culturing of test
organisms; (3) instrument condition and calibration; (4) use of reference toxicants,
adequate controls, and exposure replication; (5) recording keeping; and (6) data
evaluation (see Horning and Weber 1985). QA/QC guidelines for Class I tests are
found in Greene et al. (1988a).
6.3.2.2 Class II Methods
The methods discussed in the following sections are potential candidates for
evaluating waste site toxicity either in the laboratory or field. For use in the field, in
situ toxicity tests are being developed and evaluated; some in situ techniques have
been applied to waste site evaluations to a limited extent (e.g., Rowley et al. 1983). In
situ techniques applied on a site-specific basis may help integrate laboratory toxicity
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data with field-derived estimates of exposure, and subsequently yield an estimate of
the hazard associated with a particular waste site.
Generally, in situ methods use resident species that naturally occur on or near a
waste site, and can be captured to evaluate toxicity or exposure. Various levels of
biological organization can be measured through in. situ methods, ranging from
cellular and molecular levels through population levels of organization. Depending
upon the data quality objectives (DQOs, see Section 5) for the field assessment, the
information gathered may yield either high or low resolution evaluations.
6.3.2.2.1 Chromosomal Aberration Assay. The chromosome aberration assay
(CA) has been successfully used to assess genotoxic effects in mammals at four
different hazardous waste sites (McBee 1985; McBee et al. 1987; Tice et al. 1987;
Thompson et al. 1988) two of which are Superfund sites. This assay examines mitotic
cells arrested at metaphase for alterations and/or rearrangements in the
chromosomes. The occurrence of chromosomal aberrations correlates well with the
presence of mutagens and is closely associated with carcinogenesis. This type of
assay is widely used and accepted for in vivo analysis of clastogenic mutagens.
Standardized protocols for assays conducted with laboratory species are available
from several sources including Brusick (1980) and EPA (1985). These protocols have
been successfully adapted for in situ use with several wild mammal species (Baker et
al. 1982; McBee et al. 1987; Thompson et al. 1988) and should be readily adaptable to
other species. Although background values for chromosome aberrations are
available for a few species of wild mammals, it is still essential that studies at HWSs
be designed to include concurrent chromosomal aberration analysis at carefully
matched reference sites.
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6.3.2.2.2 Terrestrial Vertebrate Acute and Subacute Toxicity Tests. Routine
test methods (e.g., ASTM 1988; Buttler 1987; Cholakis et al. 1981; McCann et al.
1981; Schafer and Bowles 1985) that address chemical effects on avian and small
mammal models have been developed in response to FIFRA and TSCA. Although
only a few tests have been completed on hazardous waste site samples, the potential
application of these methods to ecological assessments at hazardous waste sites can
not be overlooked. For example, ASTM (1988) contains standard methods for
conducting avian acute toxicity tests; on a site-specific basis, these methods may be
amenable to hazardous waste site toxicity assessments. Similarly, ASTM (1985)
contains standard practices for conducting acute toxicity tests with amphibians.
EPA has produced toxicity test guidelines (1982a-c) for regulatory mandates other
than hazardous wastes. Numerous short-term toxicity tests are now being developed
that may be available for site evaluations (e.g., ASTM 1988); although they cannot be
unequivocally endorsed, they deserve attention when DQOs and site-specific
ecological assessments are being developed.
6.3.2.2.3 Terrestrial Invertebrate Toxicity Tests. Most terrestrial invertebrate
toxicity test methods have been developed and used in regulatory programs other
than hazardous waste site investigations. Most of these are laboratory tests with few
(if any) field evaluations. Nonetheless, the methods warrant consideration since they
may be useful in evaluating the ecological effects associated with hazardous waste
sites. Candidate test methods include: (1) laboratory tests with crickets (Acheta
deomesticus) (Walton 1980) or grasshoppers (Thomas et al. 1983) in either acute or
short-term chronic testing formats; (2) in situ or laboratory toxicity tests with
harvester ants (Pogonomyrmex spp.) (Gano et al. 1985); (3) in situ or laboratory
toxicity tests with honey bees (Apis spp.) (Thomas et al. 1983, 1984; Bromenshenk
1985); and (4) laboratory tests with nematodes such as Caenorhbditis elegans (e.g.,
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Popham and Webster 1979, 1982) or Panagrellus spp. (e.g., Samoiloff et al. 1980).
Any of these tests may be valuable for site assessments, particularly in regard to
longer-term effects (e.g., genotoxicity or mutagenicity). While the invertebrate
species available for toxicity testing are relatively limited at present, critical species
have been identified (Wilson et al. 1987) and should be considered during the
development of DQOs for any particular site.
6.3.2.2.4 Short-Term Plant Toxicity Assessment Methods. Currently,
standardized terrestrial toxicity tests for plants are limited. The most promising
methods still requiring standardization and/or evaluation include the following: (1)
Tradescantia toxicity tests (stamen hair mutagenicity assay and micronuclei
formation) (e.g., Grant and Zura 1982; Lower et al. 1983; Ma and Harris 1985; Lower
et al. 1988); (2) the hexaploid virescent wheat assay for detecting cytogenetic effects
(Redei and Sandhu 1988; Lower et al. 1988); and (3) the soil fungi response (e.g.,
sclerotia formation) tests (Thomas et al. 1983). The Tradescantia toxicity tests offers
the opportunity for integration of laboratory and field tests, especially when resident
species can be used as in situ biological indicators. The hexaploid virescent wheat
assay has been used primarily in laboratory settings for evaluating clastogenicity
from exposure to single chemicals and multi-chemical mixtures. Soil fungi response
testing has been used in site evaluations on a limited basis to assess formation in
response to complex chemical mixtures. This type of testing may complement other
Class I microbial tests.
6.3.3 Methods Integration
As summarized in Figure 6-2, hazard assessment considers toxicity and exposure
functions implicit to site evaluations. Ecological assessments at hazardous waste
sites can potentially contribute to estimates of exposure. Depending upon the
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toxicity assessment methods indicated by the site- specific DQOs, the field methods
employed should, as a minimum requirement, yield samples that assure adequate
toxicity estimates for the site.
Hazard
Assessment
Toxicity
Assessment
Exposure
Assessment
Figure 6-2. Considerations in ha/ard assessment.
A primary rationale for performing toxicity tests arises from the complexity of the
systems being evaluated (Miller et al. 1985). The value of comparative toxicity data
bases and the role of toxicity test batteries in site evaluation can be illustrated
through case studies (also see Section 9). For example, Thomas, et al. (1986) used
Class I tests for a toxicity assessment of Rocky Mountain Arsenal, near Denver,
Colorado (see Table 6-1). The toxicity of soils from the site was evaluated, and the
role of toxicity tests for site evaluations was demonstrated. For example, the test
results distinguished between the toxicity from exposures to site soil (direct test
systems) and that associated with exposures to water soluble soil contaminants
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(indirect test systems). Similarities and differences among endpoints for the two
types of test systems were related to site-specific characteristics such as soil type and
potential for groundwater contamination. Similarly, direct assessments of soil
toxicity provided short-term measures of biological effects; Thomas, et al. (1986)
analyzed these within comparative contexts as part of their evaluation of hazardous
waste effects on soil biota. Although fewer terrestrial tests were conducted than
aquatic tests, comparisons between direct estimates of soil toxicity (e.g., earthworm
mortality and seed germination) also contributed to the site assessment for Rocky
Mountain Arsenal. Again, different sensitivity and resistance patterns were evident
from such a comparative approach.
In general, site-specific toxicity potentials may be suggested by comparing estimates
of toxicity derived from indirect and direct test systems. These toxicity estimates will
be of greater relevance when field surveys are completed in conjunction with toxicity
tests. Additionally, interspecies variability and differences in biological responses
become apparent in exposures to complex chemical mixtures and afford preliminary
observations regarding contaminant characteristics. For example, on the bases of
chemical analyses, site history, and known biological responses to single-compounds,
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Table 6-1. EC50 Response of Percent Inhibition Caused by Chemical
Contaminants in Rocky Mountain Arsenal Soil Klutriate,
Wastewater, and Ground Water Samples (modified after Thomas,
etal. 1986)
Test
Rocky Mountain
Arsenal sample
number
085
092
F basin water
F basin wellwater
1-5
6
7
8
9
Major
contaminants Algaea Daphniaa
Heavy metals,
pesticides
Heavy metals,
pesticides
Heavy metal,
DIMP, other
organics
DIMP, other
organics
Unknown
Unknown
Unknown
Unknown
Unknown
8.3
6.4
0.002
27
S
S
NE
S
S
86
25
0.003
21
72
94
NE
NE
NE
Seed
REb germinationEarthworm
NE
61
1.0
12
72e
—
32
19
26
—
—
0.5d
---
9U-
100
100
92
13
>25c
<5.0
—
—
62
55
<25
58
NE
NE, no biologically significant toxicity observed; DIMP,
diisopropylmethylphosphonate; S, growth stimulation.
-------�
6.3.4 References
American Society for Testing and Materials (ASTM). 1985. Standard practice for
conducting acute toxicity tests on aqueous effluents with fishes, macroinvertebrates,
and amphibians. ASTM Committee E-47, American Society for Testing and
Materials, Philadelphia, PA.
American Society for Testing and Materials (ASTM). 1988. ASTM Book of
Standards. Section 11, Water and Environmental Technology, Vol. 11.04. Pesticides;
Resource Recovery; Hazardous Substances and Oil Spill Response; Waste Disposal;
Biological Effects. American Society for Testing and Materials, Philadelphia, PA.
Baker, R.J., M.W. Haiduk, L.W. Robbins, A. Cadena, and B.F. Koop. 1982.
Chromosomal studies of South American bats and their systematic implications.
Special Publication. Pymatuning Laboratory. Ecol. 6:303-327.
Bohn, H.L., B.L. McNeal, and G.A. O'Connor. 1979. Soil chemistry. John Wiley &
Sons, New York, NY.
Brady, N.C. 1974. The Nature and Properties of Soils. MacMillan Publishing Co.,
Inc., New York, NY.
Bromenshenk, J.J., S.R. Carlson, J.C. Simpson, J.M. Thomas. 1985. Pollution
monitoring in puget sound with honey bees. Science 227:632-634.
Brusick, D. 1980. Protocol 13: Bone marrow cytogentic analysis in rats. In:
Principles of Genetic Toxicology. Plenum Press. New York, NY.
Buttler, B. 1987. Peromyscus (Rodentia) as environmental monitors: A
bibliography. Canadian Union College, Biology Department, College Heights,
Alberta, Canada.
Callahan, C., L.K. Russell, and S.A. Peterson. 1985. A comparison of three
earthworm bioassay procedures for the assessment of environmental samples
containing hazardous wastes. Biol. Pert. Soils. 1:195-200.
Cholakis, J.M., M.J. McKee, L.C.K. Wong, and J.D. Gile. 1981. Acute and subacute
toxicity of pesticides in microtine rodents. Pages 143-154. In: D.W. Lamb and E.E.
Kenaga, eds. Avian and Mammalian Wildlife Toxicology: Second Conference. ASTM
STP 757. American Society for Testing and Materials, Philadelphia, PA.
Edwards, C.A., and J.R. Lofty. 1972. Biology of Earthworms. Chapman and Hall,
Ltd., London.
Fava, J.A., W.J. Adams, R.J. Larson, G.W. Dickson, K.L. Dickson, and W.E. Bishop.
1987. Research priorities in environmental risk assessment. Workshop Report.
Society of Environmental Toxicology and Chemistry, Rockville, MD.
Gano, K.A., D.W. Carlile, and L.E. Rogers. 1985. A harvester ant bioassay for
assessing hazardous chemical waste sites. PNL-5434. Pacific Northwest Laboratory,
Richland.WA.
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Goats, G., and C.A. Edwards. 1982. Testing the toxicity of industrial chemicals to
earthworms. Pages 104-105. In: Rothamsted Exp. Station Report, 1982.
Grant, W.F., and K.D. Zura. 1982. Plants are sensitive in situ detectors of
atmospheric mutagens. Pages 407-434. In: J.A. Heddle, ed. Mutagenicity: New
Horizon in Genetic Toxicology, Academic Press, New York, NY.
Greene, J.C., C.L. Bartels, W.J. Warren-Hicks, B.R. Parkhurst, G.L. Linder, S.A.
Peterson, and W.E. Miller. 1988a. Protocols for short-term toxicity screening of
hazardous waste sites. U.S. Environmental Protection Agency, Corvallis, OR.
Greene, J.C., W.E. Miller, M. Debacon, M.A. Long, and C.L. Bartels. 1988b. Use of
Selenastrum capricornutum to assess the toxicity potential of surface and ground
water contamination caused by chromium waste. Environ. Toxicol. Chem. 7:35-39.
Horning, W.B., and C.I. Weber. 1985. Short-term methods for estimating the chronic
toxicity of effluents and receiving waters to freshwater organisms. EPA/600/4-
85/014. Environmental Monitoring and Support Laboratory, Office of Research and
Development, U.S. Environmental Protection Agency, Cincinnati, OH.
Lower, W.R., V.K. Drobney, B.J. Aholt, and R. Politte. 1983. Mutagenicity of the
environments in the vicinity of an oil refinery and a petrochemical complex. Terat.
Carcinog. Mutagen. 3:65-73.
Lower, W.R., S.S. Sandhu, and M.W. Thomas. 1988. Utility of in situ assays for
detecting environmental pollutants. In: Proceedings, U.S. EPA Fourth Annual
Symposium: Waste Testing and Quality Assurance, Washington, DC.
Ma, T.-H. and M.M. Harris. 1985. In situ monitoring of environmental mutagens.
Hazard Assess. Chem. 4:77-105.
McBee, K. 1985. Chromosomal aberrations in resident small mammals at a
petrochemical waste dump site: A natural model for analysis of environmental
mutagenesis. Ph.D. disseration. Texas A&M University, College Station, TX.
McBee, K., J.W. Bickhma, K.W. Brown, and K.C. Donnelly, 1987. Chromosomal
aberrations in native small mammals (Peromyscus leucopus and Sigmodon hispidus)
at a petrochemical waste disposal site: I. Standard karyology. Arch. Environ.
Contam. Toxicol. 16:681-688.
McCann, J.A., W. Teeters, D.J. Urban, and N. Cook. 1981. A short-term dietary
toxicity test on small mammals. Pages 132-142. In: D.W. Lamb and E.E. Kenaga,
eds. Avian and Mammalian Wildlife Toxicology: Second Conference. ASTM STP 757,
American Society for Testing and Materials, Philadelphia, PA.
Miller, W.E., S.A. Peterson, J.C. Greene, and C.A. Callahan. 1985. Comparative
toxicology of laboratory organisms for assessing hazardous waste sites. J. Environ.
Qual. 14:569-574.
Morrill, L.G., B.C. Mahilum, and S.H. Mohiuddin. 1982. Organic compounds in soil:
Sorption, degradation, and persistence. Ann Arbor Science Publishers, Inc. The
Butterworth Group, Ann Arbor, MI.
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Peltier, W.H., and C.I. Weber. 1985. Methods for Measuring the Acute Toxicity of
Effluents to Freshwater and Marine Organisms. Third Edition. EPA/600/4-85/013.
US Environmental Protection Agency, Environmental Monitoring and Support
Laboratory, Cincinnati, OH.
Popham, J.D., and J.M. Webster. 1979. Cadmium toxicity in the free-living
nematode Caenorhabditis elegans. Environ. Res. 20:183-191.
Popham, J.D., and J.M. Webster. 1982. Ultrastructural changes in Caenorhabditis
elegans (nematc
SafV 6:183-189.
elegans (nematoda) caused by toxic levels of mercury and silver. Ecotoxicol. Environ.
if.
Redei, G.P., and S.S. Sandhu. 1988. Aneuploidy detection with a short-term
hexaploid wheat assay. Mutat. Res., Special Issue on Aneuploidy. In Press.
Rowley, M.H., J.J. Christian, D.K. Basu, M.A. Pawlikowski, and B. Paigen. 1983.
Use of small mammals (voles) to assess a hazardous waste site at Love Canal,
Niagara Falls, New York. Arch. Environ. Contam. Toxicol. 12:383-397.
Samoiloff, M.R., S. Schulz, Y. Jordan, K. Denich, and E. Arnott. 1980. A rapid
simple long-term toxicity assay for aquatic contaminants using the nematode
Panagrellus redivivus. Can. J. Fish. Aquat. Sci. 37:1167-1174.
Schafer, Jr., E.W. and W.A. Bowles, Jr. 1985. Acute oral toxicity and repellency of
933 chemicals to house and deer mice. Arch. Environ. Contam. Toxicol. 14:111-129.
Thomas, J.M., and J.E. Cline. 1985. Modification of the Neubauer technique to
assess toxicity of hazardous chemicals. In: soils. Environ. Toxicol. Chem. 4:201-207.
Thomas, J.M., J.F. Cline, C.E. Cushing, M.C. McShane, J.E. Rogers, L.E. Rogers, J.C.
Simpson, and J.R. Skalski. 1983. Field evaluation of hazardous waste site
bioassessment protocols, Volume 1. PNL-4614. Pacific Northwest Laboratory,
Richland WA.
Thomas, J.M., J.F. Cline, K.A. Gano, M.C. McShane, J.E. Rogers, L.E. Rogers, J.C.
Simpson, and J.R. Skalski. 1984. Field evaluation of hazardous waste site
bioassessment protocols, Volume 2. PNL-4614, Vol. 2. Pacific Northwest
Laboratory, Richland, WA.
Thomas, J.M., J.R. Skalski, J.F. Cline, M.C. McShane, J.D. Simpson, W.E. Miller,
S.A. Peterson, C.A. Callahan, and J.C. Greene. 1986. Characterization of chemical
waste site contamination and determination of its extent using bioassays. Environ.
Toxicol. Chem. 5:487-501.
Tice, R.R., E.G. Ormiston, R. Boucher, C.A. Luke, and D.E. Paquette. 1987.
Environmental biomonitoring with feral roden species. In: Short-term bioassays in
the analysis of complex environmental mixtures. V. (Sandhu, S.S., D.M. Demarine,
M.J. Mass, M.M. Moore, and J.L. Mumford, eds.) Plenum Press. New York, NY.
Thompson, R.A., G.D. Schroder, and T.H. Connor. 1988. Chromosomal aberrations
in the cotton rat, Sigmodon hispidus, exposed to hazardous waste. Envirn. Molec.
Mutagen. 11:359-367.
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U.S. Environmental Protection Agency. 1985. Toxic Substances Control Act Test
Guidelines; Final Rules. 40 CFR parts 796, 797, and 798.
U.S. Environmental Protection Agency. 1982a. Environmental effects test
guidelines. EPA 560/6-82/002. U.S. Environmental Protection Agency, Washington,
DC.
U.S. Environmental Protection Agency. 1982b. Pesticide assessment guidelines.
EPA/ 540/9-8/018 through 028. Office of Pesticide Programs, U.S. Environmental
Protection Agency, Washington, DC.
U.S. Environmental Protection Agency. 1982c. Toxic substances test guidelines.
EPA/ 6/82/001 through 003. Office of Toxic Substances, U.S. Environmental
Protection Agency, Washington, DC.
Walton, B.T. 1980. Differential life-stage susceptibility of Acheta deomesticus to
acridine. Environ. Entomol. 9:18-20.
Wilson, M.V., E.R. Ingham, C.D. Mclntire, and M.L. Scott. 1987. Report on the
selection of several potentially critical terrestrial systems. Department of Botany
and Plant Pathology, Oregon State University, Corvallis, OR.
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6.4 MICROBIAL TOXICITY TESTS -- Gabriel Bitton, Bernard J. Dutka,
and Charles W. Hendricks
6.4.1 Introduction
Microbes are ubiquitous in the environment and have the capacity to process
substrates found in water and soil for their own maintenance and growth but also
carry out critical functions necessary for ecosystem stability, some of which are
beyond the ability of higher life forms. Because of these unique physiological
characteristics, certain microbial species have been utilized in both short-term
toxicological testing and to study the effects of pollutants on the cycling of carbon,
nitrogen, sulfur, and phosphorus in ecosystems.
Short-term microbial tests are based on inhibition of activities of bacteria, algae, and
fungi, and are versatile and cost-effective assessment tools (Hicks and Van Voris
1988; Bitton and Dutka 1986; Dutka and Bitton 1986; Liu and Dutka 1984). Because
they are simple, rapid, and relatively inexpensive procedures, they are readily
adaptable to miniaturization and automation. Microbial test methods have been
developed that assess the toxicity of domestic and industrial effluents, discharges,
and waste products. However, with the increasing awareness of the long-term effects
of chemicals discharged into aquatic systems and landfill sites, recent research
efforts have been directed to the development of short-term bioassay tests to alert
regulatory and monitoring agencies, as well as dischargers, of the presence of
toxicants in effluents and the aquatic ecosystem (Bulich 1979; Dutka and Kwan
1988).
Ecological effects tests are mainly used to measure the acute toxicity of chemicals to
bacteria and other organisms that represent various trophic levels that mediate the
cycling of nutrients. These tests aid in the estimation of effects to the stability of
6-44
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ecosystems. These tests can readily be used to assess a wide range of toxicants in
waters, soil, sediments, sewage effluents and leachates, either directly or after
concentration and/or extraction.
Various microbial toxicity assays have been identified as Class I methods for
conducting ecological assessments at hazardous waste sites because these procedures
are widely accepted and the methods are of known quality; Class H methods have not
been thoroughly investigated under field conditions, but warrant consideration
within a site-specific context.
6.4.2 Microbial Toxicity Test Methods
6.4.2.1 Sample Preparation
6.4.2.1.1 Aqueous Samples. Leachate or surface water samples are usually tested
in their natural state or concentrated. Concentration procedures (such as flash
evaporation are commonly used, but the procedure may result in the loss of volatile
toxicants. Samples may be refrigerated and tested within two to three days of
collection, or frozen at -60° C if there is a longer time delay.
6.4.2.1.2 Sediment Samples. Sediments may be collected by Ekman dredge, Ponar
grab or other suitable instruments. At each site the collected surface layers (1 to 2
cm) are pooled (usually in a stainless steel bowl), and mixed, and aliquots are
dispensed in appropriate containers and stored at melting-ice-temperature until
extraction procedures can be initiated.
6.4.2.1.3 Extraction Procedures. Two simple commonly used extraction
procedures, water extraction and organic solvent extraction, are performed
sequentially on the same sediment sample.
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(A) Water Extraction. A portion of sediment (e.g., 100 g) is extracted with very
high quality deionized-filtered water. The sample is mixed with water in a 1:1
ratio, shaken vigorously for three to five minutes, then spun at 5000 rpm in a
refrigerated centrifuge for 10 minutes. The supernatant is used for toxicity
screening tests immediately or frozen until required (Dutka et al. 1988).
(B) Solvent Extraction. The 100 g portion of the above water-extracted
sediment is freeze-dried, then weighed on fired aluminum foil (i.e., 550° C
overnight). The weighed, freeze-dried sediment is added along with 250 ml
dichloromethane (DCM) into a 1-L Erlenmeyer flask, which has been rinsed twice
with DCM, and shaken approximately 24 hours on a Burrel wrist action shaker at
position 2. After settling overnight, the sediment-solvent mixture is filtered
overnight through washed Na2SC>4. One ml of 100% DMSO is added to the filtrate
and the mixture is evaporated in a rotary evaporator to 1.0 ml. The sample is
transferred into a test tube along with 2 ml DCM rinsings (twice) of the flask. The
DCM is evaporated under nitrogen in a water bath to 1.0 ml. This 1.0 ml of 100%
DMSO is used in all toxicity screening tests at the 1% level. A solvent blank is
prepared for each series of tests containing 250 ml DCM plus 1.0 ml of 100%
DMSO evaporated to 1.0 ml DMSO. A method blank is also prepared as control,
containing 250 ml DCM plus 1.0 ml DMSO, shaken, filtered and evaporated as per
the procedure for the total sample (Dutka and Kwan 1988). DMSO sample
preparations may be preserved by freezing at -60° C and may be stored at least
four months until analyzed.
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Other procedures can be used to concentrate water and extract sediments for
toxicant activity tests. The procedures outlined above are provided as one
approach.
6.4.2.2 ATP Assays
Adenosine triphosphate (ATP), a product of catabolic reactions, is found in all living
cells. The fact that ATP is rapidly destroyed after cell death makes it ideal for
distinguishing between live and dead cells. The basic assay of ATP consists of
measuring the light emission following the reaction of firefly luciferin with ATP in
the presence of luciferase and Mg2+ (Holm-Hansen 1973).
6.4.2.2.1 Class 1 ATP Tests
The recommended ATP assay for conducting environmental assessments at
hazardous wastes sites is the ATP-TOX system test, developed by Xu and Dutka
(1987). Concentrations of ATP in bacterial cells remain relatively constant and
stable throughout all phases of growth (D'Eustachio and Johnson 1968); thus,
bacterial densities can be estimated by measuring the ATP content of the test system.
Growth inhibition usually occurs when rapidly growing bacterial cells are exposed to
toxicants. After several life cycles, the toxic effect can be estimated by comparing
sample cell growth to a control by measuring the ATP content.
6.4.2.3 Enzymatic Activity
Since enzymes are key catalysts for metabolic reactions in cells, their inhibition by
environmental toxicants could be the underlying cause of toxicity to the cells.
Enzyme inhibition as a basis for toxicity testing has been explored for a wide range of
enzymes with special emphasis on the dehydrogenase enzymes (Bitton and Koopman
1986; Christensen et al. 1982). Other enzymes studied include ATPases, esterases,
6-47
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phosphatases, amylase, protease, beta-glucosidase, urease, and luciferase (Obst et al.
1988). Although enzymes are quite sensitive to heavy metals, they generally display
little sensitivity to organic toxicants.
One approach to toxicity testing has been to measure the effect of toxicants on the de
novo enzyme biosynthesis in microorganisms. The classic example is the inducible
enzyme system beta-galactosidase, which is controlled by the cluster of genes known
as the lac operon (Jacob and Monod 1961). Toxicity assays based on the inhibition of
beta-galactosidase in R coli have been developed and found to respond well to
toxicants (Button et al. 1988; Reinhartz et al. 1987). The test based on the inhibition
of beta-galactosidase activity is only sensitive to heavy metals, but the one based on
enzyme biosynthesis responds to both organic and inorganic toxicants (Button et al.
1988).
A modification of this test system has also been used for genotoxicity. This test is
based on the induction of the gene sfiA, which is controlled by the general represser of
the SOS system in K coli. Expression of the sfiA is monitored by a gene fusion with
lacZ gene for beta-galactosidase. Comparison of test results with the Ames test
showed that most of the mutagenic compounds ( 90% of 83 chemicals of several
different classes) were also SOS inducers (Quillardet and Hofnung 1985).
6.4.2.3.1 Class 1 Enzymatic Activity Test.
The Toxi Chromotest and SOS Chromotest are effective for conducting
environmental assessments of hazardous waste sites, and consist of colorimetric
assays of microbial enzymatic activities after incubating various concentrations of
water or sediment and soil extracts with the special test strain K coli (K-12 PQ37).
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These tests, which are available under the trade names of Toxi Chromotest and SOS
Chromotest (Orgenics Ltd., Yavne, Israel, and distributed by Colonies Corp., Boulder,
CO), provide data on acute toxicity and potential genotoxic effects.
6.4.2.3.2 Class II Enzymatic Activity Test.
A variety of techniques are available to measure changes in dehydrogenase activity
as a result of chemical effect on microorganisms. These include measuring color
changes of tetrazolium dyes and resazurin, and the direct inhibition of specific
dehydrogenase enzymes (Bitton and Koopman 1986). The latter method is well
standardized and is available in kit form from Sigma Chemical Co., St. Louis, MO.
The in vitro dehydrogenase activity test measures the reduction of NADP to NADPH
using glucose-6-phosphate as substrate. NADPH can be measured colorimetrically or
with a spectrophotometer. In the colorimetric test, NADPH in the presence of
phenazine metasulfate reduces a blue dye to a colorless state. The rate of the
disappearance of the blue color is proportional to the dehydrogenase activity. The
spectrophotometric test is based on the increased absorbance of NADPH at 340 nm.
6.4.2.4 Bioluminescence Assays
Bioluminescence is a branch of the electron transport system, and several
investigators have described toxicity assays based on inhibition of this system
(Bulich 1984,1986). The first commercial toxicity test using bioluminescent bacteria
was developed atBeckman Instruments, Carlsbad, CA (Bulich 1979,1982). The test,
now marketed by Microbics Corp. (still under the trade name of Microtox), utilizes
freeze-dried cultures of the marine bacterium Photobacterium phosphoreum and is
based on the inhibition of bioluminescence by toxicants. The results of several
studies of pure compounds and complex chemical mixtures have revealed that
6-49
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Microtox is in general agreement with the standard fish and invertebrate bioassays
(Curtis et al. 1982; Sanchez et al. 1988).
The presence of 2% sodium chloride in the assay medium can be a problem with
Microtox assay. The salt concentration (1 to 7% NaCl) in the assay milieu may
readily affect the toxicity of heavy metals such as cadmium or zinc (Hinwood and
McCormick 1987). It was proposed that 20.4% sucrose should be added to the assay
medium in lieu of 2% NaCl to provide osmotic protection to Photobacterium
phosphoreum. Heavy metal toxicity was higher in the presence of sucrose (Hinwood
and McCormick 1987). Another concern is that Microtox may not be sensitive to
extremely hydrophobic compounds (Hermans et al. 1985).
Notwithstanding these problems, Microtox is a Class I bioluminescence assay for use
in conducting environmental assessments of hazardous waste sites. Algal-Tox is
recommended as a Class It test. Brief descriptions of these methods are presented in
the following subsections.
6.4.2.4.1 Class I Bioluminescence Test.
Beckman Instruments, Inc., has developed a test for measuring acute toxicants in
water and sediment and soil extracts which utilizes specialized strains of luminescent
bacteria (Photobacterium phosphoreum). This test measures the effect of toxic
materials (and stimulants) on the metabolism of the culture. Any alteration of
cellular metabolism affects the intensity of light output from the organism. When
these changes in light output are sensed, the presence and relative concentration of
toxicants can be obtained by establishing EC50 levels from plotted data. The EC50 is
defined as that concentration of toxicant causing a 50% reduction in light intensity.
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6.4.2.4.2 Class II Bioluminescence Test.
The algal ATP toxicant screening test is based on the inhibition of ATP production in
cultures of the green alga Selenastrum capricornutum (Blaise et al. 1986). The ATP
content of the stressed Selenastrum is measured by the procedure described in Turner
(1983). The results are reported as a percentage of relative light output (RLO) of the
non-stressed controls (100%).
6.4.2.5 Microbial Growth Assays
Algae and photosynthetic bacteria appear to be more susceptible to the action of
chemicals than other toxicity test species (e.g., heterotrophs), probably because many
of the compounds that have been tested inhibit photosynthesis. Actinomycetes and
saprophytic fungi appear to be more resistant to the action of xenobiotics and an
increase in their number was detected for many of the compounds tested (Simon-
Sylvestre and Fournier 1979). Similar observations have been made for
heterotrophic bacteria. In general, compounds such as fungicides have a broad
inhibitory effect, causing reduced population densities among all microbial groups.
For certain groups of heterotrophic bacteria, this effect can be transient and
populations will recover to pretreatment population densities, or above. This
increase is usually attributed to the utilization of microbial cells killed by xenobiotic
by the surviving organisms.
Microbial populations in the rhizosphere comprise a particularly important soil
microbial community. Because of their unique relationship to the plant root zone
that they colonize, rhizosphere microbial populations differ from those in soil not
directly associated with roots (Gerhardson and Clarholm 1986). Because of their close
association with plants, nutrients are available for the mutual benefit of both
populations.
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Trappe et al. (1984) have reviewed much of the literature on the effects of
agricultural chemicals on mycorrhizal fungi and concluded that observable effects
are variable and appear to depend on the type of compound as well as on the type of
mycorrhizal fungi. The effects of heavy metals on mycorrhizae are also relatively
unknown. However, chromium and cadmium have been shown to be inhibitory
(Simon-Sylvestre and Fournier 1979; Babich and Stotzky 1985).
It is difficult to quantify accurately microbial populations in situ because the
ecological and physical factors that control the growth of microorganisms in water
and soil are not well understood. Therefore, a completely accurate environmental
assessment of the effects of xenobiotics on microbial populations and communities is
not currently possible. Consequently, the quantification of microbial populations in
soil and water as a measure of the effect of xenobiotics on microorganisms is often
disregarded (Greaves 1982). Changes in microbial populations, if detectable, can,
however, serve as a guide to the interpretation of metabolic data, such as respiration
or nitrogen transformations (Grossbard 1976). In addition, results obtained from
changes in species composition can aid in the interpretation of data obtained in the
environmental assessment.
As a result of these observations, direct microbial growth measurements are not
definitive although excellent Class I type methods are available (APHA 1985; ASTM
1987; US EPA 1978). Two microbial assays are discussed below to augment Class I
ATP, enzyme activity, and bioluminescence assays discussed in the preceding
sections of this chapter.
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6.4.2.5.1 Microbial Growth Tests.
A. Population Density Measurements. The quantitative estimation of
microbial populations provides a general indication of ecosystem stability. While
numbers of particular species may vary, a significant reduction or increase in
numbers is useful in the interpretation of other information about the site.
Particularly important organisms include the rhizosphere bacteria, mycorrhizal
fungi and free-living organisms in soil and water at the site. For each group of
organisms, a specific growth medium must be used, but standard techniques are
available for both water (APHA 1985) and soil (Black 1965).
The traditional approach to toxicity testing is to measure the effect of toxicants on
growth inhibition of pure bacterial cultures or mixtures of microorganisms
originating from various sources (Alsop et al. 1980; Trevors 1986). The turbidity
of the bacterial suspensions is read initially and after 16-hour incubation at room
temperature. In the Netherlands, a standard toxicity test is based on growth
inhibition of Pseudomonas fluorescens ATTC 13525 (Trevors 1986). More
recently, a miniaturized six-hour test based on the growth inhibition of
Aeromonas punctata was found to be more sensitive than other bacterial tests
evaluated (Slabbert 1988).
B. Spirillium volutans. This test is based on loss of coordination and subsequent
loss of bacterial motility in the presence of toxicants (Bowdre and Krieg 1974). It
has been extensively used to measure environmental toxicants as well as the
toxicity of heavy metal mixtures (Dutka and Kwan 1988) and has been found to
be in good agreement with the Daphnia bioassay (Sanchez et al. 1988).
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6.4.3 "Ecological Effect" Tests
Nutrient cycling is one of the most ecologically significant and potentially most
sensitive processes within terrestrial ecosystems. Soil processes involving nutrients,
especially those of carbon, nitrogen, phosphorus, and sulfur are important to the well-
being and health of ecosystems and contribute to soil stability, soil fertility, and plant
productivity. The movement of nutrients in an ecosystem includes cycling within the
below-ground and above-ground portions and also between the two components. Such
processes are performed by an array of microorganisms including free-living and
symbiotic bacteria and fungi, algae, various protozoans, and higher plants and
animals.
Because the majority of biochemical transformations in soil result from microbial
activity (Alexander 1977), there is concern that waste materials that can affect
microbial life may also alter cycling of nutrients in the environment and ultimately
affect soil fertility and plant productivity. For example, processes such as
nitrification and sulfur oxidation are mediated exclusively by specific groups of
microorganisms, and the rates at which their metabolic processes occur is indicative
of their activity. The major limitations of assays based on these processes are that (1)
little information is available about the specific organism or group of organisms that
may be affected by the toxicant, and (2) other tests must be performed if that
information is desired (e.g., direct plate count). Nevertheless, these techniques are
especially useful in programs designed to assess toxicity (Barkay et al. 1986; Van
Voris et al. 1985).
Four nutrient cycling processes that are valuable in the environmental assessment of
hazardous waste sites are carbon, nitrogen, sulfur, and phosphorus transformations.
6-54
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Carbon transformations - The relationship between specific chemicals and their
effect on respiration is unclear from the literature; but in general, low concentrations
of recalcitrant compounds (such as chlorinated aromatic hydrocarbons) exert little
effect on microbial respiration. At higher concentrations, however, chlorinated
aromatics are toxic to microorganisms (Boyd and Shelton 1984), and result in
respiration inhibition. Less persistent organic compounds, such as the carbamate
and phenylurea pesticides, appear to suppress respiration, but the nonselective
fungicides appear to do so to the greatest extent (Parr 1974). At low concentrations,
other organic xenobiotic compounds have been shown to stimulate oxygen
consumption (Grossbard 1976).
Because the respiratory response to toxicants may be either inhibitory or
stimulatory, the technique should be used in conjunction with other procedures. The
stimulatory effect has been observed even after an initial inhibitory effect and could
result from a waste that is biodegradable (Bitton and Dutka 1986), or from the
uncoupling of oxidative phosphorylation from the electron transport chain (Bartha et
al. 1967), or from the degradation of those organisms that may have been originally
sensitive to the waste chemicals (Jenkinson and Powlson 1976).
Respiration is a convenient parameter to consider as a basis for toxicity testing using
pure cultures of aerobic bacteria or mixtures of indigenous microorganisms. Several
approaches are available for measuring respiration rates, including manometric
techniques, titrimetric method, electrolytic respirometers, oxygen electrodes, and
immobilized microorganisms (King and Dutka 1986). Toxicity tests based on
inhibition of microbial respiration have long been favored for monitoring sewage
treatment plants and polluted surface waters. However, these tests do not appear to
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be the most sensitive for measuring the impact of toxicants on aquatic and soil
environments.
Soil respiration does provide an overall indication of the effects of toxicants on soil
microbial activities. However, it is also important to determine their effects on the
utilization of specific carbon compounds. The initial decomposition of cellulose is
generally attributed to soil fungi, and fungicidal compounds appear to have the
greatest impact on cellulose degradation (Grossbard 1976). Nonfungicidal
compounds, such as herbicides and heavy metals, have also been shown to inhibit
cellulose degradation (Wainwright 1978; Martin et al. 1982).
Nitrogen transformations - The transformation of organic nitrogen to inorganic
forms is an important microbial function contributing to the fertility of soil and is a
microbial process that has become a significant indicator in assessing the effects of
toxicants. The major nitrogen transformations mediated by soil microorganisms
include ammonification, nitrification, denitrification, and nitrogen fixation.
Nitrobacter has been proposed as a bioassay organism for measuring the toxicity of
industrial effluents (Williamson and Johnson 1981) and pesticide impact on soils
(Mathes and Schulz-Berendt 1988). While nitrification appears to be the most
sensitive part of the nitrogen cycle to the action of toxicants, chlorinated
hydrocarbons appear to have minimal effect when applied at low rates. However,
chronic effects may result from repeated application of these pesticides. Studies by
Carlisle and Trevors (1986) and Rhodes and Hendricks (1988) have shown that
nitrification is sensitive to some herbicides, but more information is needed
concerning the chronic versus acute effects of toxicants on microorganisms in soils.
Degradation products of chlorinated compounds may also influence nitrification
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(Corke and Thompson 1970). In general, nitrification is inhibited by the action of
heavy metals (Giashuddin and Cornfield 1979; Rother et al. 1982; Chang and
Broadbent 1982; Bewley and Stotzky 1983). The comparative toxicity of metals to
nitrification follows the sequence, Hg > Cr > Cd > Ni > Cu > Zn > Pb (Liang and
Tabatabai 1978).
Sulfur and phosphorus transformations - Sulfur enters soil primarily in the form of
plant residues, animal wastes, chemical fertilizers, and rainwater, and a large part of
the sulfur in the soil profile is present in organic matter. Sulfate is the principal
plant-available source of sulfur. The oxidation of sulfur to sulfate and the reduction of
sulfate are particularly important (Alexander 1977; Granat et al. 1976).
Certain pesticides have been shown to decrease sulfur oxidation when added to soils.
Tu and Miles (1976) reported that 2000 ppm Aldrin and Eldrin decreased the rate of
sulfur oxidation for 2 months, whereas Audus (1970) reported no effect at this
concentration. Herbicides such as Paraquat and 2,4-D have been shown to decrease
the oxidation of sulfur, although it is not known if the decrease was the result of a
direct action on the principal organisms responsible for oxidation or an indirect effect
caused by the loss of plant exudates after the death of the plant (Tu and Bollen 1968).
Phosphorus exists in soils as inorganic forms and as organic forms that undergo
mineralization (Alexander 1977). Wainwright and Snowden (1977) showed that
fungicides increased slightly the level of CaC12-extractable phosphorus in soils,
resulting in increased solubilization of added insoluble phosphates. These increases
were associated with an increase in the population of phosphorus-solubilizing
bacteria after soil treatment. The application of insecticides and herbicides has been
shown to have little effect on either phosphorus mineralization from organic matter
6-57
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or solubilization from inorganic forms (Smith and Weeraratna 1974; Tyunyayeva et
al. 1974), but heavy metals appear to inhibit microbially mediated cycling of
inorganic phosphorus (Juma and Tabatabai 1977; Capone et al. 1983).
At present no Class I ecological effects methods are available, but two Class n assays
are discussed below to augment the core group of recommended microbial assays.
6.4.3.1 Class II Ecological Effect Tests.
6.4.3.1.1 Nitrification Inhibition. The biological oxidation of ammonia to nitrate in
soil is facilitated by two groups of chemolithotrophic bacteria: ammonium oxidizers
and nitrite oxidizers. Inhibition of either of these groups may significantly alter the
dynamics of the soil nitrogen pool. These organisms grow slowly and are difficult to
maintain in pure culture. Consequently, most studies utilize nitrifying bacteria
naturally present in soil and focus on the impact of toxicants on nitrification rates.
Currently, three techniques are used to examine effects of chemicals on nitrification.
These are the continuous flow method (Rhodes and Hendricks 1989), the perfusion
column (Lees and Quastel 1946), and the static batch culture (Black 1965).
The assays are performed by adding various concentrations of an extract from a
contaminated soil or dilutions of a water sample to a nitrifying soil culture. After
incubation, static soil cultures are extracted and filtered. Extraction is not necessary
for the perfusion and continuous-flow cultures, and the eluates can be analyzed
directly without further preparation.
Ammonia, nitrate, and nitrite are measured by standard techniques using automated
analysis (U.S. EPA 1979). With these procedures, detection levels for nitrite and
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nitrate are 0.005 mg/L and 0.01 mg/L for ammonia. When necessary, dilution of soil
extracts can be prepared with deionized water.
6.4.3.1.2 Mineralization of Organic Sulfur. The organic forms of sulfur are found
extensively in the terrestrial environment, particularly in algae and green plants.
Plants are able to degrade sulfolipid primarily to 6-sulfo-6-deoxyglucose. This
compound serves as a primary substrate for sulfur-metabolizing soil microflora. The
mineralization of organic sulfur compounds can be an effective means for evaluating
the response of microorganisms to toxic chemicals in the environment. While this
assay is highly sensitive, it does require the use of scintillation counting equipment
found in well equipped laboratories.
This procedure (Strickland and Fitzgerald 1983) utilizes the 35S042 isotope of 6-sulfo-
6-deoxyglucose (Sulfoquinovose). This substrate is incubated with soil for various
time periods and extracted to recover mineralized organic and inorganic fractions.
These fractions are measured for total radioactive sulfur, from which the rate of
mineralization is determined.
To measure the effects of toxicants on the rate of sulfur mineralization, various
dilutions of contaminated water or soil extracts are added to an actively growing
culture undergoing sulfur mineralization.
6.4.4 Case Study: Battery Approach to Toxicity Testing
Some investigators have suggested that a core group of toxicity tests should be used
to assess the toxicity of environmental samples (Calleja et al. 1986; Qureshi et al.
1982). An integrated approach to ecotoxicity testing has been followed by
researchers from Environment Canada (Blaise et al. 1985; Blaise et al. 1988).
6-59
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Plotkin and Ram (1984) demonstrated the usefulness of the battery approach for
measuring the toxicity of landfill leachates. They recommended a series of toxicity
tests with organisms (bioluminescent bacteria, algae, daphnid, and fish) belonging to
different trophic levels. A battery of indicator tests was also evaluated at several
sites, including landfill sites (Burton and Stemmer 1988). The tests included several
enzymatic assays (alkaline phosphatase, protease, amylase, arylsulfatase,
dehydrogenase, beta-galactosidase, beta-glucosidase), heterotrophic 14c uptake,
zooplankton, amphipods, and fish. This approach was recommended for routine
ecotoxicity testing.
A battery concept was also adopted for testing the toxicity of sediment extracts
(Dutka and Kwan 1988; Giesy et al. 1988). Dutka and Kwan (1988) studied the
toxicity of sediments from Lake Ontario, Port Hope Harbour, Canada. Sediments
were extracted with very high quality deionized-filtered water or with a solvent
(extraction with dichloromethane followed by evaporation and resuspension in
dimethylsulfoxide). The toxicity of the sediment extracts was tested using five
toxicity assays: Microtox, Spirillium volutans, algal inhibition, ATP-Tox, and
Daphnia magna acute mortality test. The toxicity of the sediment water extract was
detected only through the Daphnia magna bioassay. However, all the microbial tests
showed toxicity in the solvent extracts. This points out the importance of the
extraction liquid for sediments and probably soils in toxicity tests. The selection of
specific tests to be used in the battery of toxicity screening assays is also critical. For
example, a Canada-wide study of water and sediment samples has revealed the
importance of test battery makeup, sample type, and extraction procedure (Dutka
1988). For water samples and water extracts of sediments, the optimum tests were
Daphnia magna and algal inhibition assays. However, for solvent extracts of
sediments, the preferred battery was composed of Microtox and algal inhibition tests.
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These studies showed that Microtox bioluminescent bacteria readily respond to
hydrophobic compounds from the sediments extracted with dichloromethane.
With careful selection of toxicity screening tests, the battery testing approach will
undoubtedly be refined in the near future as our knowledge on the individual toxicity
tests expands. It will provide a rapid and low cost means of assessing chemical
toxicity in the environment.
6.4.5 References
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Bitton, G., and B.J. Dutka, eds. 1986. Toxicity Testing Using Microorganisms, Vol.
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Bitton, G., and B. Koopman. 1986. Biochemical tests for toxicity screening. Pages
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Blaise, C., G. Sergy, P. Wells, N. Bermingham, and R. Van Coillie. 1988. Biological
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Bulich, A.A. 1982. A practical and reliable method for monitoring the toxicity of
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Bulich, A.A. 1984. Microtox: A bacterial toxicity test with several environmental
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Procedures Using Bacterial Systems. Marcel Dekker, New York, NY.
Bulich, A.A. 1986. Bioluminescent assays. Pages 57-74. In: G. Bitton and B. J.
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FL.
Burton, G.A., Jr., and B.L. Stemmer. 1988. Evaluation of surrogate tests in toxicant
impact assessments. Tox. Assess. 3:255-269.
Calleja, A., J.M. Baldasano, and A. Mulct. 1986. Toxicity analysis of leachates from
hazardous wastes via Microtox and Daphnia magna. Toxicity Assess. 1:73-83.
Capone, D.G., D.D. Reese, and D.P. Kiene. 1983. Effects of metals on methanogensis,
sulfate reduction, carbon dioxide evolution, and microbial biomass in an anoxic salt
marsh sediment. Appl. Environ. Microbiol. 45:1586-1591.
Carlisle, S.M., and J.T. Trevors. 1986. Effects of the herbicide glyphosate on
nitrification, denitrification, and acetyl reduction in soil. Water Air Soil Polut.
29:189-203.
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Chang, F.H. and F.E. Broadbent. 1982. Influence of trace metals on some soil
nitrogen transformations. J. Environ. Qual. 11:1-4.
Christensen, G.M., D. Olson, and B. Reidel. 1982. Chemical effects on the activity of
eight enzymes: A review and a discussion relevant to environmental monitoring.
Environ. Res. 29:247-255.
Corke, C.T. and F.R. Thompson. 1970. Effects of some phenylamide herbicides and
their degradation products in soil nitrification. Can. J. Microbiol. 16:567-571.
Curtis, C., A. Lima, S.J. Lorano, and G.D. Veith. 1982. Evaluation of a bacterial
bioluminescence bioassay as a method for predicting acute toxicity of organic
chemicals to fish. Pages 170-178. In: J.G. Pearson, R.B.Foster and W.E. Bishop, eds.
Aquatic Toxicity and Hazard Assessment, STP 766, American Society for Testing
and Materials., Philadelphia, PA.
D'Eustachio, A.J. and D.R. Johnson. 1968. Instrumental approach to rapid
microbiology. Internal Pub., E.I. Dupont Nemours and Co., Wilmington, DE.
Dutka, B.J. 1988. A proposed ranking scheme and battery of tests for evaluating
hazards in Canadian waters and sediments. National Water Research Institute,
Environment Canada, Contribution 88-80, Burlington, Ontario, Canada.
Dutka, B.J., and G. Bitton, eds. 1986. Toxicity Testing Using Microorganisms, Vol.
2. CRC Press, Boca Raton, FL.
Dutka, B.J., and K.K. Kwan. 1988. Battery of screening tests approach applied to
sediment extracts. Toxicity Assess. 3:303-314.
Dutka, B.J., K. Jones, K.K. Kwan, H. Bailey and R. Mclnnis. 1988. Use of microbial
and toxicant screening tests for priority site selection of degraded areas in water
bodies. Water Res. 22:503-510.
Dutton, R.J., G. Bitton, and B. Koopman. 1988. Enzyme biosynthesis versus enzyme
activity as a basis for microbial toxicity testing. Toxicity Assess. 3:245-253.
Gerhardson, B. and M. Clarholm. 1986. Microbial communities and plant roots.
Pagesl9-34. In: V. Jensen, A. Kjoller, and L.H. Sorensen eds.. Microbial
Communities in Soil. Elsevier, NY.
Giashuddin, M. and A.H. Cornfield. 1979. Effects of adding nickel (as oxide) to soil
on nitrogen and carbon mineralization at different pH levels. Environ. Pollut. 19:67-
70.
Giesy, J.P., R.L. Graney, J.L. Newsted, C.J. Rosiu, A. Benda, R.J. Kreis, Jr., and F.J.
Horvath. 1988. Comparison of three sediment bioassay methods using detroit river
sediments. Environ. Toxicol. Chem. 7:483-498.
Granat, L., R.O. Hallberg, and H. Rodhe. 1976. The global sulfur cycle. In: B.H.
Svensson and R. Soderlund, eds. Nitrogen, Phosphorus, and Sulfur - Global Cycles,
SCOPE Report 7. Ecol. Bull. (Stockholm). 22:23-73.
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Greaves, M.P. 1982. Effect of pesticides on soil microorganisms. Pages 613-630. In:
R.G. Burns and J.H. Slater, eds. Experimental Microbial Ecology. Blackwell
Scientific Publications, London.
Grossbard.E. 1976. Effects on the soil microflora. Pages 99-147. In: L.J. Audus, ed.
Herbicides: Physiology, Biochemistry, and Ecology. Academic Press, New York, NY.
Hermans, J., F. Busser, P. Leevwangh and A. Musch. 1985. Quantitative structure-
activity relationships and mixture toxicity of organic chemicals in Photobacterium
phosphoreum: The Mirotox test. Ecotoxicol. Environ. Safety. 9:17-25.
Hicks, R.J. and P. Van Voris. 1988. Review and Evaluation of the Effects of
Xenobiotic Chemicals on Microorganisms in Soil. Report 6186. Pacific Northwest
Laboratory,U.S. Department of Energy, Battelle Memorial Institute, Richland, WA.
Hinwood, A.L., and M.J. McCormick. 1987. The effect of ionic solutes on ECso values
measured using the Microtox test. Toxicity Assess. 2:449-461.
Holme-Hansen, O. 1973. Determination of total microbial biomass by
measurements of 90 adenosine triphosphate. In: Stevenson L.H. and R.R. Lowell,
eds. Estuarine Microbial Ecology. University of South Carolina Press, Columbia,
SC.
Jacob, F. and J. Monod. 1961. Genetic regulatory mechanisms in the synthesis of
proteins. J. Mol. Biol. 3:318-356.
Jenkinspn, D.S., and D.S. Powlson. 1976. The effects of biocidal treatments on
metabolism in soil. Part V: A method for measuring soil biomass. Soil Biol. Biochem.
8:209-213.
Juma, N.G., and M.A. Tabatabi. 1977. Effects of trace elements on phosphatase
activity in soils. Soil Sci. Soc. Amer. J. 41:343-346.
King, E.F., and B.J. Dutka. 1986. Respirometric techniques. Pages 75-113. In: G.
Bitton and B. J. Dutka, eds. Toxicity Testing Using Microorganisms, Vol. 1. CRC
Press, Boca Raton, FL.
Lees, H. and J.H. Quastel. 1946. Biochemistry of nitrification in soil. I. Kinetics of,
and the effect of poisons on, soil nitrification, as studied by a soil perfusion technique.
Biochem. J. 40:803-814.
Liang, C.N., and M.A. Tabatabai. 1978. Effects of trace elements on nitrification in
soils. J. Environ. Qual. 7:291-293.
Liu, D. and B.J. Dutka, Eds. 1984. Toxicity Screening Procedures Using Bacterial
Systems. Marcel Dekker, New York, N.Y.
Martin, M.H., E.M. Duncan, and P.J. Coughtrey. 1982. The distribution of heavy
metals in a contaminated woodland ecosystems. Environ. Pollut. Sci. B 3:147-157.
Mathes, K. and V.M. Schulz-Berendt. 1988. Ecological risk assessment of chemicals
by measurements of nitrification combined with a computer simulation model of the
N-cycle. Toxicity Assess. 3:271-286.
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Obst, U., A. Holzapfel-Pschorn, and M. Wiegand-Rosinus. 1988. Application of
enzyme assays for lexicological water testing. Toxicity Assess. 3:81-91.
Parr, J.F. 1974. Effects of pesticides on microorganisms in soil and water. Pages
315-340. In: W.D. Guenzi, ed. Pesticides in Soil and Water. Soil Sci. Soc. Amer.,
Madison, WL
Plotkin, S., and N.M. Ram. 1984. Multiple bioassays to assess the toxicity of a
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R.B. Foster, and W.E. Bishop, eds. Aquatic Toxicology and Hazard Assessment, 5th.
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CHAPTER?
BIOMARKERS
By
Richard T. DiGiulio, School of Forestry and Environmental Studies,
Uuke University, Durham, NC.
7.1 INTRODUCTION
The concept of "biomarkers" has recently received considerable attention among
ecotoxicologists as a potentially powerful approach for assessing environmental
degradation, particularly due to anthropogenic contaminants. The underlying
concept is that selected endpoints measured in individual organisms, typically
comprised of biochemical or physiological responses, can provide sensitive indices of
exposure or, more importantly, sublethal stress. In this chapter, selected biomarkers
for exposure, including bioaccumulation, and sublethal stress are described. The
biomarkers described have been selected based on their present availability for
routine monitoring and their applicability to hazardous waste site evaluations. The
former criterion greatly limits the number of biomarkers warranting discussion at
this time. However, it must be kept in mind that this approach comprises an
extremely active area of research and, consequently, the list of available biomarkers
will be considerably expanded in the next several years.
When monitoring for adverse environmental effects due to toxicants emanating from
hazardous waste sites, it should be noted that biomarkers cannot be used currently to
ascertain effects at the biological levels of organization of greatest ecological concern,
(i.e., population, community, and ecosystem levels). However, carefully selected
biomarkers may serve as very sensitive monitoring tools for detecting exposure and
sublethal stress and provide examples, an early warning system for adverse
ecological effects and an approach for delimiting zones of impact. Furthermore, there
7-1
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is concern over the sensitivity of the endpoints available for determining population-
ecosystem level effects. Endpoints such as density, diversity, or nutrient cycling
rates typically display such high natural variability that contaminant-mediated
impacts may have to be severe for them to show change. The often greater sensitivity
of biomarkers may be due to lower inherent variability, as well as their typically
closer relationships to mechanisms of action. Additionally, the biomarker approach
has considerable potential for assisting with human health hazard assessments,
where individual organism responses are of great concern. In this context, animals
inhabiting waste sites, or exposed to waste site media, can serve as sentinels for
health effects in humans.
Criteria for useful biomarkers include sensitivity, reliability, feasibility, and
applicability to hazardous waste site environments. The issue of sensitivity is
particularly important because a key rationale using biomarkers, particularly for
sublethal stress, is the potential they have for detecting effects at earlier stages than
most other approaches. In this regard, biomarkers that are closely related to
biochemical mechanisms of action are likely to be more sensitive than more general
indices of stress. However, "nonspecific" indices of stress may still be useful,
particularly when mechanisms are unknown or do not yield usable markers. In the
context of hazardous waste sites, biomarkers that are relatively compound- or mode
of action-specific, as well as more nonspecific indices, are both likely to be useful.
Given the very complex nature of some hazardous waste site contaminant mixtures,
nonspecific indices may prove to be more useful than they are often considered.
The biomarker approach is readily incorporated into both laboratory toxicity testing
and field studies. Many laboratory studies can easily be designed to allow for the
examination of selected biomarkers. Any required modification in the design of
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laboratory studies will depend on the biomarkers selected for examination.
Important considerations here include tissue requirements (for example, some
markers may require more tissue than normally provided in some routine toxicity
tests) and duration of exposure (some biomarkers require longer exposure times than
provided by acute toxicity tests). Biomarker measurements can also be made in
conjunction with field studies that provide for sampling of organisms. Such studies
may involve either sampling of free-living organisms or in situ exposures of
"controlled" organisms. Important general considerations here include the
availability of suitable reference sites, the frequent necessity of destructive
sampling, and the considerable care generally required in sample handling.
Biomarkers can play an important role in integrating results from laboratory and
field studies. For example, dose-response relationships can be elucidated in
laboratory studies for selected biomarkers (such as bioaccumulation, enzyme
activities, etc.). Then, the subsequent measurement of the biomarkers in field
studies will provide important information regarding "effective" (i.e., causing effects)
environmental concentrations of contaminants on the site(s) of interest. Conversely,
the measurement of an array of biomarkers in conjunction with field studies can
direct the choice of which biomarkers are examined in detailed laboratory studies.
Many biomarkers that are considered to be feasible and applicable to hazardous
waste sites are described in the following sections of this chapter. A few biomarkers
that are included may be insufficiently developed for routine monitoring, but may be
useful in particular situations. The biomarkers that are discussed have been chosen
from other potential techniques based on the criteria described previously; however,
a degree of subjectivity was also operative. Individuals using this approach are
encouraged to watch both for the full development of additional biomarkers and for
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other, existing biomarkers of utility for a particular problem at a site under
investigation. The biomarkers described in this chapter have been divided into the
following two major categories: (1) markers for exposure, and (2) markers for
sublethal stress. However, overlap between these categories occurs and is noted.
7.2 BIOMARKERS FOR EXPOSURE
The most direct way to assess exposure to contaminants is to measure tissue residues,
a key component of bioaccumulation. When feasible, this approach is recommended.
However, when measuring tissue residues is not feasible such as with compounds
that do not readily bioaccumulate (due to rapid metabolism, for example) or with
complex mixtures that require time and cost intensive analyses that may not identify
all toxic chemicals, indirect measures of exposure may be required or preferred. An
additional attraction of indirect measures, which are typically biochemical
endpoints, is that they indicate a biological response to the exposure that is often of
toxicological significance; tissue residues alone convey no such information. Such
biochemical endpoints blur the distinction between indices of exposure and response,
and are more integral to the concept of "biomarkers" than tissue residues.
7.2.1 Direct Indices of Exposure
The following discussion of biomarkers for exposure is divided into a section dealing
with direct measures (i.e., bioaccumulation) and a section dealing with indirect
measures (i.e., biochemical responses). These categories are further subdivided into
separate subsections for the two classes of compounds of greatest concern at waste
sites -- trace metals and organics. Class I and Class n test methods are identified,
where appropriate.
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In each subsection, techniques for measuring biomarkers are discussed, along with
considerations regarding species and tissue selection, data analysis and
interpretation, and quality assurance and quality control. At the conclusion of each
biomarker-toxicant section, example case studies are provided.
7.2.1.1 Class 1 Methods: Trace Metals
7.2.1.1.1 Species Selection. In monitoring bioaccumulation of trace metals (and
perhaps many organics as well), the appropriate species and tissues to analyze are
often more difficult questions to resolve than the analytical technique. Decisions
here, particularly regarding species selection, will be largely influenced by the
ecology of the site and information about contaminating metals. It is important to
note, however, that trace metals generally do not display biomagnification, and
physical positioning in the environment appears more important than trophic
position in determining exposure. Typically, soil- or sediment-inhabiting organisms
display the greatest tissue concentrations of contaminating metals (for example see
Mathis et al. 1979). Therefore, for biomonitoring of trace metal contamination, soil-
associated terrestrial organisms or tissues (such as earthworms, small burrowing
mammals, and roots of plants) and benthic aquatic organisms (including bivalves,
bullheads, and rooted macrophytes) are often chosen. Mercury, due to its propensity
to undergo methylation and thereby become relatively lipophilic, is an exception and
has demonstrated biomagnification (Jernelov 1972). For this metal, therefore,
species occupying higher trophic positions are generally preferred. It is important to
keep in mind the distinction between bioaccumulation and effects during species
selection. Those organisms demonstrating the greatest tissue residues are by no
means necessarily those most likely to be affected. Species sensitivity, when known,
may also play a key role in selecting organisms for residue analysis. (In addition, see
Section 8.5.2.2.1.)
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7.2.1.1.2 Tissue Selection. Typically in animals the liver is the tissue of choice,
often followed by the kidneys, for assessing bioaccumulation of metal. Some
exceptions are brain tissue, an important accumulation site for methyl mercury, and
bone, a useful tissue for monitoring long-term accumulation of lead. Additionally,
blood lead concentrations are used to assess recent exposures and also comprise very
useful supporting information when blood delta-ALAD measurements (see section
7.2.2.1.1) are made. If trophic transfers of metals are of interest, whole body
concentrations may be important. In plants, roots typically accumulate the highest
concentrations of soil- or sediment-borne metals. In the context of trophic transfers,
other plant parts may be more important.
7.2.1.1.3 Methods. Most trace metals bioaccumulate and lend themselves readily to
direct measurement. Atomic absorption spectroscopy (AAS) has been the method of
choice for most metals, and standard methods for AAS analyses in biological media
are readily available. More recently, inductively-coupled plasma (ICP) spectroscopy
has received considerable attention and is used by some laboratories for routine
analyses. Neutron activation analysis (NAA) provides another methodology that is
very sensitive for some elements. However, NAA is very expensive and has limited
availability; therefore, it is not recommended for routine monitoring of the nature
covered by this document. Unlike AAS, ICP and NAA have the capability of
simultaneous, multi-element sample analysis, which is often important for
environmental monitoring. ICP, however, is not as sensitive a technique for many
metals as AAS (particularly Homeless AAS). While AAS and ICP involve rather
sophisticated instrumentation, trace metal analysis is not inherently difficult, and
many laboratories are able to produce reliable data. Generally, trace metal analysis
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is considerably less time and labor intensive than organic analysis; hundreds of
samples can be analyzed in a week.
Van Loon (1985) is an excellent reference covering sample collection and preparation
as well as AAS and ICP analyses for trace metals. Sample contamination is a major
concern in trace metal analysis. Trace metals, as elements, are ubiquitous and great
care must be taken to avoid contamination during sampling, tissue dissection,
ashing, and dissolution. Van Loon (1985) describes appropriate precautions for
avoiding contamination at these various stages of metal analysis.
7.2.1.1.4 Data Interpretation. There is an extensive amount of literature on trace
metal concentrations in a wide variety of organisms. This literature can be very
useful for distinguishing between normal (i.e., background) and elevated
concentrations of metals. It is important to bear in mind, however, that a number of
factors other than environmental concentrations of bioavailable metals influence
tissue concentrations within a given species. These factors include season of the year,
nutrition, genetic variability among populations, etc. Therefore, one reliable
approach for interpreting metal concentrations observed at a waste site is generally
to compare the data to those observed in the same species from a nearby reference site
known to be minimally contaminated with the metal(s) of interest. Another
approach may be a gradient analysis from the source of contamination.
7.2.1.1.5 QA/QC Considerations. Trace metal analysis is sufficiently routine in
that standardized QA/QC procedures are followed by most laboratories performing
these analyses. These procedures include analysis of National Bureau of Standards
reference materials (including bovine liver and orchard leaves), standard additions
(spikes), routine analyses of blanks, and inter-laboratory comparisons. A very
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important consideration here is sample contamination. Since metals of interest as
contaminants are also naturally-occurring elements, trace metal analysis is much
more prone to artifactual errors due to contamination than organic analysis.
Sampling and dissecting equipment must be carefully selected and cleaned, samples
carefully handled and stored, and the most metal-free reagents practical employed in
sample digestion and analysis. The possibility of metal contamination of reagents,
particularly digesting acids, must be scrupulously checked and accounted for with
appropriate blanks. See Van Loon (1985) for discussions of this critical topic.
7.2.1.1.6 Case Studies. Many reports concerning trace metal residues in free-living
organisms have been published, and many were motivated by concerns of
environmental contamination by metals. Informative examples comprising a diverse
array of organisms include: Smith and Rongstad (1982) - small mammals; Beyer and
Moore (1980) - terrestrial insects and plants; DiGiulio and Scanlon (1984) -
waterfowl; Murphy et al. (1978) - fish; and Popham and D'Auria (1983) - bivalves.
7.2.1.2 Class I Methods: Organic Chemicals
7.2.1.2.1 Persistence. The issue of persistence is considerably more complex in
assessing exposure to organic chemicals than metals. Persistence can be viewed as a
gradient from very persistent to rapidly metabolized or excreted. For relatively
persistent compounds (including many chlorinated hydrocarbons), direct measures of
the parent compound are typically most appropriate. For rapidly metabolized
compounds such as organophosphates, indirect measures such as cholinesterases (see
Section 7.2.2.2.1) are often more appropriate. For intermediate compounds (such as
polycyclic aromatic hydrocarbons), measures of reasonably stable metabolites (see
below) can be useful. Unfortunately, for many organics occurring at waste sites
(many solvents, for example), limited information concerning persistence and
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metabolism is available. In these cases, expert opinion should be sought concerning
the most appropriate approach. Frequently, the analysis of the parent compound will
at least provide information concerning recent exposures.
7.2.1.2.2 Species and Tissue Selections. Questions concerning species and tissues
to monitor are more complex for organic compounds than for metals. Site-specific
characteristics and the particular questions being asked (trophic transfers, for
example) will direct decisions regarding species and tissue selection. In addition to
some trace metals, some common organic chemicals such as many organohalogens
biomagnify (for example, see Niethammer et al. 1984). For organic chemicals,
however, biomagnification appears to be the exception rather than the rule. When
sampling an organic chemical that does biomagnify, animals that represent higher
trophic levels may be most appropriate for analyses of tissue residues. Liver tissues
(or hepatopancreas in many invertebrates) is generally most appropriate for samples.
For persistent lipophilic compounds, fatty tissues (such as subcutaneous fat, kidney
fat, or brain) are often appropriate. Using bile for polycyclic aromatic hydrocarbon
(PAH) metabolites is discussed in section 7.2.1.2.3. In plants, roots often display the
greatest concentrations, although in many cases (such as with more volatile
compounds), leaves may be more appropriate.
7.2.1.2.3 Methods. The number of organic compounds likely to be encountered at
hazardous waste sites is far larger than the number of trace metals, and a far greater
number of techniques are available for separating and analyzing organic compounds
than metals in biological media. Gas chromatography (GO, GC linked to mass
spectroscopy (GC/MS), and high performance liquid chromatography (HPLC) are the
most commonly used analytical techniques. However, techniques for organic
analysis are far less standardized than is the case for metal analysis. Moye (1981),
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Natusch and Hopke (1983), and MacLeod et al. (1985) are useful references
regarding sample handling, preparation, and analytical procedures. However,
diverse techniques are available in this field and are being developed for many
compounds. Perhaps the best approach is to secure the services of a very reliable
laboratory equipped to perform the specific analysis required.
A relatively new technique that shows considerable promise for routine monitoring of
exposure to PAHs in vertebrates is described by Krahn et al. (1984). PAHs are
metabolized rather rapidly by vertebrates, and tissue residues of parent compounds
are not reliable as indices of exposure to this important group of contaminants.
Krahn et al. (1984) uses HPLC linked to a fluorescence detector to estimate
concentrations of PAH metabolites in bile. Different fluorescence wavelength pairs
are used to measure metabolites of different PAHs (such as naphthalene,
phenanthrene, and benzo[a]pyrene). Bile metabolites also provide a useful approach
for determining exposure to chlorinated phenolics (Oikari and Anas 1985).
Because applicable techniques are highly variable, it is difficult to estimate the time
and labor required for organic analyses. Many compounds can be measured routinely
using relatively straightforward GC techniques; others require considerably more
sophisticated MS analyses. Generally, organic analyses are considerably more time
and labor intensive than metal analyses.
7.2.1.2.4 Data Interpretation. The bulk of the discussion of data interpretation for
trace metals data (see section 7.2.1.1.4) applies to organics as well. However, the
literature dealing with data interpretation is less extensive for organics than for
trace metals. On the other hand, in contrast to trace metals, most organic
contaminants are not naturally occurring compounds, which somewhat simplifies
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data interpretation. Nevertheless, the best approach for assessing the impacts of a
particular waste site on tissue burdens of organic contaminants is again the
simultaneous collection of analogous data from a nearby reference site.
7.2.1.2.5 QA/QC Considerations. Due to the diversity and rapid evolution of
techniques applicable to environmental organic analysis, QA/QC procedures are
highly variable. In the context of monitoring at waste sites, these analyses are
generally performed under contract, and the contract initiator is strongly urged to
carefully select reputable laboratories with documented compliance to appropriate
QA/QC procedures.
7.2.1.2.6 Case Studies. As with trace metals, there is an extensive amount of
literature concerning residues of many organic compounds in environmentally-
exposed organisms. Examples include Niethammer et al. (1984) - various
organochlorines; Flickinger et al. (1980,1984) - organophosphorous compounds and
carbamates; Krahn et al. (1986) - bile metabolites of PAHs; and Oikari and
Kunnamo-Ojala (1987) - bile metabolites of chlorinated phenolics and resin acids
(using caged fish).
7.2.2 Indirect Biomarkers for Exposure
7.2.2.1 Class I and Class II Methods: Trace Metals
Given the propensity of metals to bioaccumulate as well as the availability of
sensitive and accurate techniques for their routine detection in biological samples,
indirect indices for exposure to metals are generally not necessary. However, two
biomarkers, delta-aminolevulinic acid dehydrase (delta-ALAD) and metal binding
protein, discussed in the following subsections, have received considerable attention
and may be useful in some cases.
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7.2.2.1.1 Class 1 Methods: Delta-ALAD.
(A) Species and Tissue Selection. Delta-ALAD measurements are typically
performed in red blood cells, which allows for non-destructive sampling, but which
also limits application of the technique to vertebrates. However, it can be adapted
for other species and tissues. Regarding other aspects of species selection, the
discussions under 7.2.1.1.1 and 7.2.1.1.2 apply. Species and tissue selection for
delta-ALAD assays for exposure to lead should be guided by recognition that lead
typically does not biomagnify and is typically highly associated with soil/sediment
compartments of ecosystems.
(B) Methods. The enzyme delta-ALAD catalyzes a reaction involved in heme
synthesis and is very sensitive to inhibition by inorganic lead (Goyer 1986), but is
relatively insensitive to alkylated lead (Grandjean and Nielsen 1979). Its activity
in blood has been used extensively as an index for exposure to inorganic lead in
humans and free-living animals. This technique has the advantages over direct
lead measurements of being cheaper, simpler, and less subject to the often serious
problem of lead contamination of samples. In the context of hazardous waste sites,
however, lead is often likely to be one among several metals of interest, and direct
multi-element analyses generally will be preferable. If lead is of particular
interest, delta-ALAD determinations may be useful.
Burch and Siegel (1971) is considered the standard method for this technique. The
technique employs a quite simple, rapid spectrophotometric assay that most
biochemical laboratories can readily implement.
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(C) Data Interpretation. While typically used as an index of lead exposure,
delta-ALAD activities can also provide information concerning sublethal stress
due to lead. The inhibition of this enzyme is believed to be an important
mechanism underlying lead toxicity (Goyer 1986). However, delta-ALAD
activities in the blood of some species, including mammals, have no apparent
physiological function, and inhibitions without accompanying deficits (i.e.,
hemoglobinemia) may occur (Posner 1977).
Blood lead-delta-ALAD relationships, which typically display marked inverse
correlations, have been described for a number of species. For informative
discussions concerning mammals, birds, and fish, see Hernberg et al. (1970),
Dieter and Finley (1979), and Hodson et al. (1979), respectively. Again, however,
the best approach for evaluating delta-ALAD data from a given waste site is to
employ parallel studies of a neighboring reference site.
(D) QA/QC Considerations. While this approach is not as prone to lead
contamination as direct lead analysis, similar precautions must be taken to avoid
sample contamination by this ubiquitous metal. For many common species offish
and wildlife, the literature provides baseline delta-ALAD activities that provide a
useful check for the performing laboratory.
(E) Case Studies. Excellent examples of the use of delta-ALAD for monitoring
for lead exposure in feral animals include: Mouw et al. (1975) - rats; Dieter (1979)
- ducks; Kendall and Scanlon (1982) - pigeons; and Hodson et al. (1980) - fish.
7.2.2.1.2 Class II Methods: Metal-Binding Proteins. A number of metals, notably
cadmium, copper, mercury and zinc, induce the synthesis of certain low molecular
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weight metal-binding proteins in a variety of vertebrate and invertebrate species.
Certainly the best understood proteins of this group are the metallothioneins.
Measures of these proteins have been suggested as useful markers for exposure to
certain trace metals or metal mixtures. Such measures, coupled with measurements
of metals and metal complexes (for example, complexes including both low and high
molecular weight proteins, the latter likely including "target" enzymes), may provide
powerful tools for understanding the biological significance of cases of metal
contamination.
This approach is presently not sufficiently developed to be recommended as a routine
biomonitoring tool. Sufficient understanding of the basic functions of
metallothioneins under normal conditions; as well as an understanding of the effects
of environmental variables such as season, temperature, and nutrient availability on
the metabolism of metal-binding proteins in appropriate indicator species; has not
yet been achieved. Additionally, the role of metallothioneins as an adaptive response
to metal contamination should be clarified. However, this topic comprises an area of
intense research about which those concerned with metal contamination should stay
abreast. Furthermore, investigators dealing with metal-contaminated sites who
desire in-depth information concerning physiological effects can benefit from
presently available approaches.
An excellent reference describing this approach, including a review of specific
techniques, is Engel and Roesijadi (1987). Very interesting reports demonstrating
the potential utility of vertebrate hepatic metallothionein as a biomarker include
Brown et al. (1977), Osborn (1978), and Roch et al. (1982). Since this approach is not
recommended as a routine biomarker, it will not be described in greater detail here.
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7.2.2.2 Class I and Class II Methods: Organic Chemicals
The rapid metabolism of some organics compels a greater need for indirect indices of
exposure for these compounds than for metals and persistent organics. Two such
indices -- cholinesterases and "drug-metabolizing" enzymes -- have received
considerable attention and can provide useful biomarkers.
7.2.2.2.1 Class 1 Methods: Cholinesterases.
(A) Species and Tissue Selection. This biomarker is applicable to a wide
variety of vertebrates and invertebrates, and species selection will likely vary
with site characteristics. An important consideration is the generally short half-
lives of organophosphorous compounds and carbamates in the environment and in
biological tissues. Therefore, the best test species are animals that are likely to be
exposed (either directly or through ingestion of contaminated food) soon after
these compounds are introduced into the environment.
Use of brain tissue is considered the most reliable approach for determining true
acetylcholinesterase activity; inhibition here most closely correlates with other
toxic effects, including mortality. However, plasma activities of cholinesterase
can also be very useful in vertebrates when non-destructive sampling is desired.
(B) Methods. The cholinesterases are enzymes that are very sensitive to
inhibition by organophosphorous (OP) and carbamate compounds; this inhibition
underlies the neurotoxicities of these compounds, which include many common
insecticides (Murphy 1986). Measures of these enzymes - acetylcholinestersae
(ACh-ase) in brain tissue and butylcholinesterase in plasma — have been used
extensively for monitoring exposure as well as sublethal and lethal effects in a
variety of vertebrates and invertebrates. This approach has generally been very
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successful for OPs, but less so for carbamates. This difference is due to the
reversibility of inhibition by carbamates, in contrast to the essentially
irreversible nature of OP inhibition. This technique is well refined and currently
exists as a powerful tool to monitor both exposure and effects of OPs in a variety of
animals. This is fortunate since OPs represent a group of rapidly metabolized
organics for which direct analyses can sometimes be difficult.
Ellman et al. (1961) is a generally cited reference describing the cholinesterase
assay that is currently undergoing the ASTM standardization process. Hill and
Fleming (1982) provide an excellent reference describing the use of this assay in
the context of field monitoring. Cholinesterase activity assays are quite
straightforward and rapid, and are readily performed by most laboratories
equipped for routine biochemical analyses.
(C) Data Interpretation. Relationships among tissue or media concentrations of
OPs and carbamates, cholinesterase activities, and toxic effects (particularly
mortality) have been described for a number of species (Ludke et al. 1975; Hall
and Clark 1982; Rattner and Hoffman 1984; Habig et al. 1986). Therefore, there
is extensive literature available that is useful for interpreting cholinesterase
activity data in a variety of species. For monitoring avian and fish exposures to
these compounds, greater than 20% inhibition of ACh-ase activity has been used
as an index for significant exposures and greater than 50% inhibition as
indicative of lethal exposures (Holland et al. 1967; Ludke et al. 1975; Tucker and
Leitzke 1979). As with most biomarkers, parallel studies of carefully selected
reference sites comprise the best approach for interpreting cholinesterase data
from a given waste site.
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(D) QA/QC Considerations. While cholinesterases are reasonably stable and
therefore amenable to biomonitoring, it is very important to treat all samples that
are to be compared (such as waste site versus reference site samples) as identically
as possible in order to minimize assay variability. The assay itself is relatively
straightforward, and routine QA/QC procedures generally employed by reputable
laboratories should be adequate. Additionally, the considerable amount of
literature available concerning cholinesterase activities in a variety of animals is
useful in assessing laboratory performance.
(K) Case Studies. Informative examples of the use of cholinesterase
determinations as a biomarker in field studies include: Williams and Sova (1966) -
fishes; Zinkl et al. (1979) - birds; and Custer et al. (1985) - various vertebrates.
7.2.2.2.2 Class II Methods: Mixed-Function Qxidase Activities. The study of
enzymes involved in the metabolism of lipophilic organic substrates in a wide variety
of animals has probably received more attention than any other biochemical
response-related topic in this field. These enzyme systems are often referred to as
drug or xenobiotic metabolizing systems, although endogenous compounds (such as
steroids) may also serve as substrates. These systems comprise a diverse array of
enzymes and are often divided into two groups designated "phase one" and "phase
two" enzymes (Sipes and Gandolfi 1986). Phase one enzymes typically catalyze the
introduction of a polar reactive group (such as -OH) onto the substrate. These
reactions generally increase water solubility of the substrate, but their key function
is to add or expose functional groups. In phase two reactions, an endogenous, highly
water soluble molecule (such as glucuronic acid, glutathione, or sulfate) is covalently
linked to the substrate through the functional group resulting from phase one
reactions. The conjugated products are generally far more water soluble than the
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original substrate and thus more readily excreted. Studies of the enzyme systems
have focused on liver tissue, although they occur in other organs, including kidneys,
lungs/gills, and gonads.
The microsomal mixed-function oxidase (MFO) enzymes occupy a central role in
phase one metabolism. These enzymes facilitate oxidations in which one atom of
molecular oxygen is reduced to water and the other is incorporated into the substrate
(Sipes and Gandolfi 1986). Key components of MFO systems are the terminal
oxidases, a group of hemoproteins referred to as the cytochromes P-450. The
activities of many MFO-associated enzymes and cytochrome P-450 concentrations
are markedly induced in many species by a variety of common environmental
pollutants including PAHs, PCBs, and petroleum hydrocarbons (Hodgson et al. 1980;
Payne et al. 1987). As with metallothioneins, this feature of induction underlies
interest in MFO components as a biomonitoring tool. It should also be noted that
while the MFO system may provide tools for biomonitoring, it is also of great
inherent lexicological significance. For example, it may provide animals with an
adaptive mechanism for coping with some contaminants; alternatively, it can
enhance the toxicity of some compounds, as exemplified by the transformation of
some procarcinogens to ultimate carcinogens.
While MFO inductions have been used successfully to indicate exposures of animals
to relatively low concentrations of contaminants, this approach is not presently
recommended as a routine biomarker for hazardous waste sites. As was the case for
metallothioneins, MFO activities can provide a very sensitive and useful approach
for assessing exposure to inducers in some situations. However, it is premature to
draw conclusions regarding their utility for monitoring exposure to many complex
mixtures, including types that may occur at waste sites. For example, some metals
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and solvents (e.g., carbon tetrachloride) can inhibit MFO activities. An important
area of research in this area is the study of interactions of MFO inducers and
inhibitors.
Payne et al. (1987) is an excellent review concerning the utility of this approach for
biomonitoring. This review contains numerous references to techniques pertinent to
field applications of MFO components.
7.3 BIOMARKERS FOR SUBLETHAL STRESS
Developing useful biomarkers for assessing sublethal stress is currently a very active
area of research. However, more biomarkers are developed for exposure assessment
than routine biomonitoring. A key approach in developing these biomarkers has
been the attempt to adapt techniques developed in various biomedical fields
(including toxicology, biochemistry, pathology, and immunology) to various species of
ecological concern. Consequently, many potentially useful biomarkers are available
and developed. Considerable work is needed, however, to determine which indices
show the greatest potential for environmental monitoring and then to adapt these
indices from standard mammalian models (rats and mice) to other, diverse species.
Biomarkers of sublethal stress that are considered to be sufficiently well developed
for application to waste site assessments are described in the following subsections,
which include discussions of "non-specific" and "specific" markers, where specificity
refers to particular target tissues or types of compounds.
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7.3.1 Non-Specific Biomarkers
Again, "non-specific" refers to biomarkers that are not necessarily chemical or
tissue/organ specific; although in some cases they may readily be used for specific
purposes (for example, histopathology for detecting liver injury).
7.3.1.1 Class I Methods: Histopathology
7.3.1.1.1 Species and Tissue Selection. Histopathological examinations are
generally most useful in a confirmatory role. Due to their relatively high labor and
time costs, they are often performed on a subset of organisms being analyzed for
simpler markers. Therefore, species and tissue selection is driven largely by factors
governing choices for other biomarkers, or by results from preceding biomarker
studies.
7.3.1.1.2 Methods. Routine techniques in histopathology (light microscopy, electron
microscopy, and histochemistry) can be adapted for detecting tissue injuries in any
selected species. Substantial literature exists describing various pathological effects
of a wide variety of chemicals in a large number of species. Generally, histopathology
is used to confirm the presence of damaged tissues suggested by biochemical or
physiological data, or by the presence of pathogens or chemicals producing
established histopathological effects. These techniques are often quite laborious
and/or expensive, and their utility in routine biomonitoring may be limited.
However, they do provide an important approach for confirming the presence of
suspected, key pathologies, such as neoplasms. In this role, they may be an
important component of biomonitoring strategies at waste sites. Meyers and
Hendricks (1986) is an informative review describing the application of
histopathological approaches in ecotoxicology.
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Because histopathological techniques vary considerably among different groups of
organisms, individuals considering histopathological analyses are strongly
encouraged to secure the services of reputable pathologists competent to work with
the specific species of interest. It is imperative that the proper tissue collection and
fixing techniques appropriate for a particular approach (e.g., light versus electron
microscopy, histochemistry) are employed; specific guidance should be obtained from
the laboratory that will perform the analyses. Useful references concerning tissue
preparation techniques for histopathological studies include: Pearse (1961) -
histochemistry; Humason (1962), Lillie (1965), and McDowell and Trump (1976) -
general preparative techniques for animals; Miksche and Berlyn (1976) - plant
techniques; and Hayat (1986) - preparative techniques for electron microscopy.
7.3.1.1.3 Data Interpretation. Pathologists conducting the analyses should be
relied on to interpret results. Although the parallel examination of tissues from
reference sites may be unnecessary in some cases (e.g., for histologically well-
characterized species), it will often be desirable.
7.3.1.1.4 QA/QC Considerations. Proper and consistent sampling and treatment of
samples is of particular concern to the field scientist. Due in part to the importance of
histopathology in carcinogenesis testing, QA7QC issues have received considerable
attention (Boorman et al. 1985). Reputable laboratories performing
histopathological analyses are familiar with these guidelines.
7.3.1.1.5 Case Studies. A few of the many informative studies demonstrating the
utility of histopathology in ecotoxicological studies include: Simmons et al. (1988) -
complex waste mixtures in mammals; White et al. (1978) - cadmium in birds; Hinton
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et al. (1988) - progression of neoplasia in fishes; Mix (1983) - neoplasia progression in
bivalves; and Godzik (1982) - ultrastructural effects of air pollutants in plants.
7.3.1.2 Class I Methods: Skeletal Abnormalities
7.3.1.2.1 Species Selection. Techniques for determining skeletal abnormalities are
generally applicable to any vertebrate species. It is anticipated that this approach
will typically be incorporated into more standard laboratory and field studies, which
will guide species selection.
7.3.1.2.2 Methods. A number of chemicals, including some trace metals and
organics, produce skeletal abnormalities in vertebrates. These effects are generally
most pronounced in early life stages, and studies with bird embryos and larval fish
have shown these organisms to be very sensitive to a variety of compounds. The
techniques for observing these effects appear to be generally uncomplicated and well-
researched. This approach appears to have considerable merit as a biomarker for
waste site assessments, and several techniques are currently available. With fish, its
utility may be limited to adults or to laboratory (or possibly caged, m situ) exposures,
since deformed larvae may be rapidly lost to predation in the wild. Bird eggs,
however, could be readily sampled in the field and returned to the laboratory for
examination. In ecotoxicological studies, this approach has apparently been used
mostly with birds and fish. However, the approach could be easily adapted for small
mammals.
Gross skeletal deformities are often readily observable with the naked eye. At very
early life stages, light microscopy may be required. Although simple visual
observations generally are adequate, several other powerful techniques are available
when more detailed information is desired. These include radiography (Mayer et al.
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1978), measures of mechanical properties of vertebrae (Hamilton et al. 1981), bird
embryo skeletal preparations (Karnofsky 1965), and measures of bone components
such as collagen (Flanagan and Nichols 1962).
7.3.1.2.3 Data Interpretation. Interpretation of these data is generally not
complicated (for example, simple calculations of percent deformities). However,
many genetic and environmental factors can give rise to apparently elevated rates of
abnormalities, so the parallel study of reference sites is recommended.
7.3.1.2.4 QA/QC Considerations. For the very simple techniques (e.g., visual
observations), common sense should suffice. However, for the more involved
techniques (such as radiography, collagen content, etc.), the expertise of competent
personnel is essential.
7.3.1.2.5 Case Studies. Informative examples of this approach include visually-
observable scoliosis in lead-exposed trout (Holcombe et al. 1976), microscopically-
observed deformities in mercury-exposed fish (Weis and Weis 1977), altered
mechanical properties and biochemical composition in OP-exposed fish (Cleveland
and Hamilton 1983), and various deformities in PAH-exposed mallard embryos
(Hoffman and Gay 1981). An excellent example of this approach in field monitoring
is provided by Hoffman et al. (1988), in which the authors describe various
deformities in birds inhabiting an agricultural area (Kesterson NWR, CA) impacted
by selenium-enriched drainage waters. Other useful references include Birge and
Black (1981), Hoffman and Albers (1984), and McKim (1985).
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7.3.1.3 Class II Methods: Gas Exchange Measurements in Plants
7.3.1.3.1 Species and Tissue Selection. Species selection is likely to be highly site-
specific. The instruments used in making gas exchange measurements in plants
generally appear adaptable for use with most terrestrial macrophytes and have been
used with both leaves and conifer needles.
7.3.1.3.2 Methods. Over the past several years, great improvements have been
made in portable instruments for gas analysis designed for plant studies. These
improved, easy to use instruments allow for rapid, accurate, non-destructive in situ
measurements of rates of photosynthesis and respiration, and stomatal conductance.
This approach has been recently employed to demonstrate effects of toxicants,
including air pollutants, on plants.
Two systems designed for these analyses are described by Atkinson et al. (1986) and
Davis et al. (1987). Both utilize portable instruments that monitor carbon dioxide
and water vapor concentrations in cuvettes that envelope leaves (or needles of
conifers). The instruments include attached microcomputers that essentially convert
changes in carbon dioxide and water vapor concentrations to rates of photosynthesis
(or respiration) and conductance.
Considerable care must be taken to collect accurate data. The instruments must be
carefully and routinely calibrated and environmental variables such as temperature,
humidity, and light intensity within the cuvettes must be carefully monitored and
controlled. Environmental variables often provide the greatest difficulties in using
these instruments to make site comparisons (for example, between waste and
reference sites). Supplemental lighting is often used to control this critical variable.
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When proper control of potentially confounding variables is achieved, these
instruments provide a powerful approach for assessing toxic impacts on plants.
7.3.1.3.3 Data Interpretation. The gas exchange responses of plants display high
natural variabilities. Therefore, to use this approach to obtain useful data, extra care
must be taken to match environmental conditions between waste and reference sites.
The literature referenced in section 7.3.1.3.5 of this chapter provides useful
discussions relevant to physiological bases of data interpretation.
7.3.1.3.4 QA/QC Considerations. The most critical aspects of quality control are
discussed in section 7.3.1.3.2. These and other QA/QC considerations are discussed
further in the operating manuals provided with the instruments.
7.3.1.3.5 Case Studies. The development of portable gas exchange analyzers is
fairly recent, and they are just now being used routinely in pollution studies.
Informative studies demonstrating their utility for this application include: Coyne
and Bingham (1981) - ozone; Wood et al. (1985) - fungicides; and Atkinson et al.
(1986)-sulfur dioxide.
7.3.2 Specific Biomarkers
The biomarker probably has its greatest appeal and potential in the area of indices
specific for particular groups of contaminants or for particular responses (such as
genotoxicity). However, only a few specific biomarkers appear to be developed to the
point of being available for routine monitoring at waste sites; they are described
below. Individuals interested in using the biomarker approach are encouraged to
remain informed of additional techniques forthcoming.
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7.3.2.1 Class I Methods: Delta-ALAD
This technique was described previously (see section 7.2.2.1.1). While measuring this
enzyme in blood is most often used as a biomarker for exposure to lead, it can be
considered a very sensitive marker for sublethal stress since its inhibition appears to
be a mechanism for lead toxicity (plumbism). However, inhibitions have been
observed in the apparent absence of other clinical indications of plumbism.
Additionally, the enzyme may have no physiological function in red blood cells.
Inhibitions in other tissues, such as liver and brain (Dieter and Finley 1979), have
clearer toxicological ramifications. Despite these caveats, delta-ALAD is a very
useful tool for monitoring subtle effects of lead exposure in a variety of animals.
7.3.2.2 Class I Methods: Cholinesterases
A number of common waste site chemicals are potent neurotoxins, including trace
metals (such as lead and mercury) and various solvents and pesticides.
Unfortunately, developed biomarkers for neurotoxins are rarely available for free-
living animals. A key exception is the cholinesterases, particularly ACh-ase, which
are described in 7.2.2.2.1. Measurements of ACh-ase activity in brain tissue provide
a very useful tool for assessing sublethal stress due to OPs, and to a lesser extent, to
carbamates. ACh-ase is a "model" biomarker — its inhibition is the key mode of
action for an important group of contaminants. The degree of inhibition can be linked
to clinical manifestations of neurotoxicity (altered behavior, tremors, death), and its
activity is readily measured in a variety of animals.
7.3.2.3 Class II Methods: DNA Unwinding
Perhaps the single greatest concern related to hazardous waste sites is their potential
for releasing carcinogens into the environment. It is in this regard that the
biomarker approach in sentinel species may prove most useful. The great concern
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about elevated rates of neoplasia observed in feral animals inhabiting a number of
polluted environments has led to considerable research directed at developing
techniques for assessing genotoxicity in free-living animals. Developing this
technique has generally involved adaptating existing techniques for genotoxic
evaluations in laboratory rodents and humans.
7.3.2.3.1 Species Selection. The DNA unwinding assay appears readily adaptable
to vertebrates in general. It may also be applicable to invertebrates and plants, but
no reports concerning these organisms have been observed. Species selection among
vertebrates will likely be driven largely by site-specific characteristics (for example,
which species are available for study, what types of carcinogens occur, etc.). In
polluted aquatic systems, benthic animals typically seem most prone to develop
tumors (Mix 1986).
7.3.2.3.2 Tissue Selection. The DNA unwinding assay is applicable to any likely
target tissue. Typical targets for carcinogens include livers/hepatopancreae,
lungs/gills, and gonads. In the fathead minnow experiment described below
(Shugart, 1988a), whole fish were used successfully.
7.3.2.3.3 Methods. The alkaline unwinding assay appears to be very applicable to
routine monitoring at hazardous waste sites. In this assay, DNA strand breaks due
to chemical exposures are quantified by determining the relative proportions of
single-stranded and double-stranded DNA following strand separation under
carefully defined and controlled conditions of pH and temperature. Shugart
(1988a,b) describes this technique for tissues derived from animals exposed m vivo.
He has adapted the technique of Daniel et al. (1985) that was developed for human
7-27
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cells in culture. Although Shugart originally developed the technique for fishes, it
has also been employed with birds and mammals.
This assay poses no unusual difficulties for laboratories equipped for biochemical
studies. With the exception of a fluorometer, only routine reagents and equipment
are used, and the assay is far quicker than most alternative probes available for
genotoxicity studies in higher organisms. It also appears to be quite sensitive. In a
study with benzo[a]pyrene exposure to fathead minnows at 1 yg/L, significant
increases in strand breaks were observed (Shugart 1988a). However, no
benzo[a]pyrene adducts (a common probe for this chemical) were observed.
7.3.2.3.4 Data Interpretation. While the assay is not overly complicated, its
development is far too recent for a set of "background" values (of single-strandedness)
to be available at this time. Thus, carefully designed studies, including studies at
reference sites, appear essential. The biological ramifications of various degrees of
single-strandedness are unknown at present; studies should be designed to achieve
statistically-based differences for use in interpreting future data.
7.3.2.3.5 QA/QC Considerations. The most crucial aspect of this assay appears to
be rigorous control of pH, temperature, and incubation time. Laboratories
unfamiliar with this relatively new assay will require some effort to gain proficiency.
7.3.2.3.6 Case Studies. This technique has only very recently been applied in
scenarios applicable to assessments of hazardous waste sites, and these studies have
not been published. Shugart (personal communication) has employed the technique
to detect DNA damage in fish from systems receiving drainage from waste sites at
the Oak Ridge National Laboratory and in cormorants from polluted sites at the
7-28
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Great Lakes. This laboratory recently observed enhanced DNA unwinding in
channel catfish exposed to sediments from Black Rock Harbor, Connecticut
(unpublished data); these sediments are enriched in PAHs and PCBs.
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CHAPTERS
FIELD ASSESSMENTS
By
Lawrence A. Kapustka, U.S. Environmental Protection Agency,
Environmental Research Laboratory, Corvallis, OR.
Thomas W. LaPointand James F. Fairchild, U.S. Fish and Wildlife Service,
National Fisheries Contaminant Research Center, Columbia, M U.
Karen McBee, Department of /oology,
Oklahoma State University, Stillwater, OK.
Jerry J. Bromenshenk, Division of Biological Science,
University of Montana, Missoula, MT.
8.1 INTRODUCTION » Lawrence A. Kapustka
Detailed assessments of ecological effects involves some measurement of structural
and functional relationships of biota spanning the range of individuals to ecosystems.
This is the role of aquatic and terrestrial field surveys in hazardous waste site (HWS)
assessments. Ecological field surveys are a definitive way to establish that adverse
ecological effects have occurred. Data generated from field surveys are evaluated
with data derived from chemical analysis and toxicity testing to provide an
integrated ecological assessment of the HWS.
There are several distinct reasons for implementing field surveys as assessment tools
at an HWS. First, indigenous organisms serve as continuous monitors of
environmental quality by integrating potentially wide fluctuations in contaminant
exposure. Second, an accurate field assessment of natural populations directly
measures adverse effects; thus, extrapolations from laboratory data are not necessary
for interspecies sensitivity, environmental variation, pulsed dosing, chemical
interaction (additivity, antagonism, or synergism), or bioavailability. Third, results
of the assessment of indigenous populations are directly interpretable, since effects
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are quantified on the resources actually at risk. Fourth, the results of assessments of
effects on indigenous populations are easily understood by managers, regulators, and
the general public. Thus, field surveys of indigenous organisms are useful for
identifying flora and fauna at risk as well as for direct quantification of
environmental effects.
Hazardous waste sites present unique constraints of access and risk to environmental
scientists. Some sites, because of extremely limited size and/or the nature of habitat
disturbance, do not pose substantive ecological concerns. At other sites, however,
ecological field assessments can play a major role in defining the nature of the
problems associated with the site. Furthermore, the ecological assessment should be
considered as a benchmark for evaluating the success of any remedial actions.
This chapter on field assessment focuses on sampling strategies that have been
selected for HWS assessments. The emphasis is on data acquisition. Given the
temporal limitations on data collection that often pertain to HWSs, it is important to
emphasize the influence that such sampling constraints may have on the uncertainty
associated with the resulting data. One-time sampling efforts almost always
underestimate species richness because ephemeral populations are easily missed and
quantitative estimates derived from these static samples underestimate the
dynamics of the site.
Only passing comments on data reduction are provided in this chapter. None of the
ecological divisions addressed here have universally accepted, consistently used
indices that can be used to condense the information into simple terms. Professional
expertise is usually required to interpret patterns of species assemblages and
populations.
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8.2 AQUATIC SURVEYS -- Thomas W. LaPoint and James F. Fairchild
8.2.1 Introduction
This section describes various methods and endpoints that can be used in field
surveys of aquatic organisms. Methods described consist of accepted, published
approaches (Class I) commonly used to monitor periphyton, plankton,
macroinvertebrates, and fish in a variety of aquatic habitats. The methods are
briefly described, along with common precautions and limitations relating to their
use. Endpoints consist primarily of direct and derived measures of population and
community structure, such as relative abundance, species richness, and indices of
community organization. Sources of comprehensive, detailed information are
provided in the form of references for each topic. Comprehensive documents useful in
conducting field surveys include APHA (1985), U.S. EPA (1973), Platts et al. (1983),
U.S. EPA (1987), ASTM (1987a), and Plafkin et al. (1988).
8.2.2 Endpoints
Aquatic field surveys for the biological effects of contaminants associated with an
HWS involve the measurement or monitoring of population and community
structure. Structural endpoints include relative abundance, species richness,
community organization (diversity, evenness, similarity, guild structure, and
presence or absence of indicator species), and biomass. Functional endpoints, such as
cellular metabolism, individual or population growth rates, and rates of material or
nutrient transfer (e.g., primary production, organic decomposition, or nutrient
cycling) are less commonly measured. Functional measurements are important in
interpreting the ramifications of an observed change in population or community
structure. However, functional measures are difficult to interpret in the absence of
structural information and frequently require considerable time, equipment, and
expertise. In addition, procedures for functional assessments have not been
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standardized and require considerable understanding of the system and processes
involved. Functional measures may therefore be limited in application to the
assessment of HWS effects unless conducted in a research framework.
8.2.2.1 Species Richness and Relative Abundance
Species richness (the number of species in a community) and relative abundances (the
number of individuals in any given species compared to the total number of
individuals in the community) are structural endpoints commonly measured in field
surveys of periphyton, plankton, macroinvertebrates, and fish. Estimates of relative
abundance or species richness can yield readily interpretable information on the
degree of contamination of an aquatic habitat (Sheehan and Winner 1984; Lamberti
and Resh 1985; Hellawell 1986). Loss of a particular species from an ecosystem can
be critical when that species plays an important role in community or ecosystem
functions such as predation (Paine 1969) or grazing (Giesy et al. 1979).
Measures of species richness and relative abundance are taken by sampling known
substrate areas or water volumes. Richness measures have not always been taken to
the species level, especially in monitoring invertebrate communities. Taxonomic,
fiscal, and time constraints have often predicated the need for rapid bioassessment
(e.g., Hilsenhoff 1988; Plafkin et al. 1988) involving taxonomic identifications only to
family and genus. It is probable that such identifications at lower levels of resolution
result in some loss of sensitivity to HWS effects.
8.2.2.2 Biomass
Biomass measurements, defined as the mass of tissue present in an individual,
population, or community at a given time, is another potential structural endpoint.
Biomass can be directly measured gravimetrically on wet or dry tissue. However,
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direct measurement of biomass of individuals is often time-consuming, and direct
measurements of individual biomass of phytoplankton, zooplankton, or
macroinvertebrates are impossible due to analytical insensitivity. Thus, biomass is
estimated gravimetrically by using pooled samples of individuals or by an indirect
method. Indirect estimates of invertebrate or fish biomass can be indirectly
estimated by using empirical or published length:weight regressions. However,
biomass measurements on these trophic groups are not commonly performed in
routine field surveys.
Biomass of periphyton communities is commonly measured. Measurements of
phytoplankton or periphyton biomass can be estimated on the basis of ash-free dry
mass (AFDM) or chlorophyll a content (APHA 1985). Chlorophyll measurements are
performed by solvent extraction, followed by spectrophotometry or fluorometry
(APHA 1985).
8.2.2.3 Indicator Species
The presence or absence of "indicator species" is commonly used to assess adverse
effects to ecological communities (Karr et al. 1986; Hilsenhoff 1988; Plafkin et al.
1988). The concept was originally derived from the saprobian system, in which
certain species and groups were found to generally characterize stream and river
reaches subject to organic wastewaters; increasing anthropogenic organic matter in
aquatic habitats serves to fill the energy requirements of "tolerant" species, while
reducing the numbers of "sensitive" species that respond negatively to competition,
predation, or decreased dissolved oxygen (Kolkwitz and Marsson 1902; Gaufin 1958;
Sheehan 1984).
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Experience has shown that the indicator species concept lacks broad applicability to
all types of pollution. Sheehan (1984) indicated that communities do not respond to
organic wastes (e.g., sewage) in the same way they respond to toxic chemicals.
Organic sewage stimulates certain species by increasing their food supply; other
species consequently diminish as a result of interspecific interactions. Toxic
chemicals, on the other hand, tend to affect all members of a community.
Furthermore, species selection may occur in aquatic habitats that are chronically
polluted with low levels of contaminants over sufficiently long periods. In such
instances, certain species that ordinarily appear to be quite "sensitive" may seem to
be "tolerant" due to decreases in predation or competitive pressures (Hersh and
Crumpton 1987).
However, the indicator species concept can be applied to the assessment of ecological
effects if enough care is taken to limit the breadth of its application. Some species
may be found upstream from the HWS or in habitats known to be unaffected by HWS
seepages. The indicator species concept has been applied in assessment techniques
for hazardous effluents (Courtemanch and Davies 1987) and metals (Sheehan and
Winner 1984). In a similar approach, although at lower taxonomic resolution, the
total numbers of insects in the orders Ephemeroptera, Plecoptera, and Trichoptera
are counted and referred to as the number of "EPTs" (Hilsenhoff 1988; Plafkin et al.
1988). Typically, these three orders are sensitive to metals and other inorganic
contaminants and, thus, provide an index of effect. Karr (1981) applied the indicator
species concept in the Index of Biotic Integrity (IBI), in which fish community
composition is used as a measurement of environmental quality (see section 8.2.3.4
on fish).
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8.2.2.4 Indices
Biological indices can be used to mathematically reduce taxonomic information to a
single number or index, to simplify data for interpretation or presentation. Indices
derived from direct measures of the presence of taxa have been extensively developed,
reviewed, and critiqued (Sheehan 1984; Hellawell 1986). Indices can be classified
among several types: evenness (measuring how equitably individuals in a
community are distributed among the taxa present); diversity (calculating the
abundance of individuals in one taxon relative to the total abundance of individuals
in all other taxa); similarity (comparing likeness of community composition between
two sites); and biotic indices (examining the environmental tolerances or
requirements of individual species or groups).
Although indices may aid in data reduction, they should never be divorced from the
actual data on species richness and abundance. Relying on a single index such as the
Shannon-Weiner Index is sometimes misleading. For example, a few individuals
evenly distributed among several species could give a relatively high index of
diversity, even though a habitat is grossly polluted. In addition, statistical
assumptions of independence, normality, and homogeneity of variance are frequently
invalid for these derived, proportional measures. Hence, when indices are used,
statistical transformations (e.g., arc-sine) or rank-order statistics (Siegel 1956; Green
1979; Hoaglin et al. 1985) are recommended.
8.2.2.5 Guild Structure
Community data generated at the species level can be analyzed according to guild
structure. Guilds, or functional feeding groups, are classifications based on the
manner in which organisms obtain their food and energy. Invertebrates can be
classified among such functional groups as collector-gatherers, piercers, predators,
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scrapers, and shredders (Merritt and Cummins 1984; Cummins and Wilzbach 1985);
and fish can be classified as omnivores, insectivores, and piscivores (Karr et al. 1986).
Shifts in community guild structure reflect changes in the trophic-dynamic status of
an aquatic ecosystem. For example, contaminant influences from an HWS may
eliminate or reduce periphyton and thus concomitantly reduce the relative
abundance of scrapers (herbivores) in relation to other invertebrate guilds such as
collector-gatherers. Changes may also occur within a guild, such as when a
contaminant alters the level of competition between two species that compete for a
common resource (Petersen 1986). Generally, the effects must be fairly strong to
enable the measurement of changes in guild structure.
8.2.3 Methods
8.2.3.1 Periphyton
Periphyton communities sometimes provide sensitive tools with which to detect
changes in lotic environments that result from contaminants (Lewis et al. 1986;
Stevenson and Lowe 1986; Crossey and LaPoint 1988). Monitoring may involve
sampling either natural or standardized substrates. Taxonomic composition and
relative abundance of periphyton are more variable on natural substrates than on
standardized substrates, although the variance can be reduced by carefully selecting
specific microhabitats with similar physical and chemical characteristics such as
substrate type, current velocity, depth, and ambient light (see Table 8-1 for methods)
(Stevenson and Lowe 1986). On hard substrates, data on algal abundance, biomass,
and species composition can be obtained by removing the substrate and by scraping
or brushing the flora from a measured area into a container. Alternatively, the
desired sampling area can be isolated or enclosed by using a chamber sealed to the
substrate with neoprene (or other thick rubberized material), or by using a coring
device and removing the scraped material by suction into a vial (Hamala et al. 1981).
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Collecting algae from soft sediments is much more laborious, for it involves using
vacuum suction to remove the soft organic surficial sediment layer and then sorting
through the debris for algae for quantitative counts (Stevenson and Lowe 1986).
Table 8-1. Methods for Measuring Physical and Chemical Variables
Measurement Reference
Temperature APHA (1985)
Dissolved oxygen APHA (1985)
Alkalinity APHA (1985)
Hardness APHA (1985)
Conductivity APHA (1985)
Nutrients APHA (1985)
(ammonia, nitrate/nitrite, ortho-phosphate)
Current velocity Hamilton and Bergersen
(1984)
Substrate composition Plattsetal. (1983); Hamilton
and Bergersen (1984)
Photosynthetically active radiation Li-Cor (1979)
Standardized substrates have been applied widely in environmental assessments of
periphyton colonization and community organization. Materials used as
standardized substrates include granite slabs, plastic strips, tiles, and glass slides.
Diatometers, consisting of frosted glass slides placed into a holding frame and
immersed in the water, are broadly accepted. Although diatometers are known to be
somewhat selective because not all algal taxa colonize the glass surfaces, this
disadvantage is offset by gains in sampling convenience and replicability that result
from the similarities in surface texture, surface area, colonization time, and
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microenvironmental conditions. Descriptions of diatometers and methods for their
use were given by Gale et al. (1979) and APHA (1985).
After the periphyton sample is obtained from a given sampling area, it may be
analyzed for taxonomic composition (cell number, species richness, and relative
abundance). Community indices (diversity, community similarity, etc.) can be
calculated from the taxonomic data. Standing crop (chlorophyll a or AFDM per unit
area) can be determined according to standard and accepted methods (Vollenweider
1974; APHA 1985); an Autotrophic Index (AFDM divided by chlorophyll a, both in
mg/m2) can be calculated (APHA 1985) as well as several other productivity-related
indices (cf. Crossey and LaPoint 1988). One common caution in conducting algal
surveys is that enough cells must be counted to ensure that rare species are
quantified. For example, Stevenson and Lowe (1986) recommended counting 200
cells from each sample to ensure complete enumeration of dominants, 500 cells to
ensure the inclusion of uncommon taxa, and 1000 cells to adequately record rare
species. Alternatively, they suggested that counting be continued until fewer than
one new species is encountered for each additional 100 algal cells counted.
Studies of periphyton communities should be supported by additional physical and
chemical information that sometimes influences periphyton production and
dynamics. It is desirable to collect data on substrate composition, current velocity,
temperature, photosynthetically active radiation (PAR), dissolved oxygen,
conductivity, alkalinity, hardness, and dissolved nutrients (ortho-phosphate,
ammonia, and nitrate/nitrite). Methods for measuring variables are given in Table
8-1. Although the appropriate selection of reference sites should remove sources of
covariance, it is important to document these factors for quality assurance and
interpretive purposes.
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8.2.3.2 Plankton
Many devices are available for sampling plankton, and sampling techniques for
phytoplankton and zooplankton are similar. The choice of an individual sampling
technique, sample size, and sample numbers, whether for zooplankton or
phytoplankton, will depend upon the characteristics of the aquatic habitat (in terms
of depth, density of organisms, and spatial variation). Samplers are broadly
categorized into four types: closing samplers, traps, pumps, and nets (De Bernardi
1984; APHA 1985; ASTM 1987b-d). DeBernardi (1984) published a schematic
diagram for choosing among different zooplankton sampling methods for different
types of habitats and samples.
Closing samplers (bottles or tubes) are lowered into the water to a particular depth
and closed with a drop-weight messenger; examples are the Van Dorn and
Kemmerer models (DeBernardi 1984; ASTM 1987b). These samplers take a
quantitative sample of water at a chosen depth, collecting all forms of nannoplankton
and ultraplankton. Closing samplers can be obtained or constructed for many
different volumetric requirements. A series of closing-bottle samplers can be
vertically arranged to sample simultaneously at multiple depths, to determine
plankton stratification. In shallow water, plankton stratification can be
mechanically integrated by using a depth-integrating column sampler (cf. Bloesch
1988). These types of closing samplers capture a known volume of water by
extending a tube through the water column from the surface to the bottom. The
water cores sampled typically vary in length (from one to several meters long) and
diameter (from one to several centimeters), depending upon the experimental
conditions. Because these samplers integrate plankton distributions throughout the
water column, they yield no useful information on plankton stratification.
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Traps such as the Juday, Patalas, and Schindler types, which have been used for
zooplankton sampling (DeBernardi 1984), are basically large closing-type samplers
that can be lowered into the water to sample water volumes of 10 to 30 L. The large
size of the traps is thought to reduce avoidance by the more agile zooplankters, such
as adult copepods, and to increase sampling efficiency for potentially rare species.
The maneuverability of relatively large traps can make them somewhat more
difficult to maneuver than other samplers.
Various pumps have also be been applied in plankton sampling (DeBernardi 1984;
ASTM 1987c). Pumps can be either motorized or hand-operated; but motorized
pumps are preferred because they provide uniform delivery rates. Both submersible
and boat-mounted pumps have been used. Sample size is determined by using a
flowmeter or by collecting the sample in a calibrated container. Pumps can be used to
take either discrete samples at a particular depth or integrated samples over a range
of depths. They allow a researcher to easily increase or decrease sample size by
changing the pumping time or pumping rate, and are amenable for use in a variety of
aquatic habitats. However, pumps have been criticized as being expensive and
somewhat bulky. In addition, care must be taken to insure that organisms are not
damaged by the pumping device, and that pumps are adequately flushed to prevent
cross-contamination of samples.
Conical nets are also commonly used for quantitative zooplankton sampling
(DeBernardi 1984; ASTM 1987d). Pore sizes of the nets typically range from 60 to 80
ym. Because a mesh of this size does not retain ultraplankton and nannoplankton,
net samples for phytoplankton are qualitative. Net samplers are towed with a rope
for a desired distance or time. Sample size is determined by a flowmeter, the distance
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towed, or other estimate of sample volume (such as distance multiplied by aperture
area). Net samples can be taken in either vertical or horizontal tows, depending on
the desired sampling strata. Some net samplers, such as the Birge closing net, have a
closure feature that enables the operator to sample discrete depths or distance.
Collected samples can be isolated or concentrated by using various techniques. Both
phytoplankton and zooplankton can be isolated using settling chambers (APHA
1985). Zooplankton can be isolated by using a net or other sieving device of a mesh
size compatible with the original collection method. After isolation, plankton
samples must be preserved (APHA 1985) and stored for taxonomic identification.
Species richness, relative abundance, and community indices can be determined from
the taxonomic data.
8.2.3.3 Macroinvertebrates
Benthic invertebrates are the most common fauna used in ecological assessments of
contaminants. Numerous excellent references deal with the collection,
identification, and analysis of benthic invertebrate populations (e.g., Southwood
1978; Downing 1984; Merritt and Cummins 1984; Peckarsky 1984; APHA 1985;
ASTM 1987e-i). Macroinvertebrates are operationally defined as the invertebrates
retained by screens of mesh size greater than 0.2 mm (Hynes 1971). Larger mesh
sizes (such as the 0.595 mm, U.S. Standard No. 30, APHA 1985) have been accepted
as standard for routine biomonitoring. Microinvertebrates (rotifers, nematodes,
gastrotrichs) may be of ecological interest, but their taxonomy is much less known;
consequently, their sampling is not recommended for routine environmental
assessments.
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A variety of techniques can be used to collect macroinvertebrates from aquatic
environments (see Table 8-2 for a summary of macroinvertebrate sampling methods,
including time and labor estimates.) In any given contaminant effects study, careful
consideration must be given to the comparability of samples among stations. Not
only must the type of sampling device be appropriate for the specific taxa and habitat
type, but sampling effort (e.g., sample numbers and sample sizes) must be uniform at
all stations. As in assessing contaminant effects with periphyton,
macroinvertebrates can be collected and quantified by sampling either natural or
standardized substrates.
Natural substrates can be sampled with net, grab, core, and vegetation samplers.
Hess and Surber samplers are commonly used to collect benthic invertebrate fauna in
shallow riffle habitats of streams (ASTM 1987e). These two samplers are similar in
that each encloses a defined area (0.1 m2 ) of substrate. Substrate within the confines
of the sampler is disturbed and mixed by hand or stake to a depth of 10 cm. Large
rocks within the sampled area are manually lifted from the substrate and brushed or
scrubbed at the mouth of the sampler to dislodge attached or clinging invertebrates,
which are carried downstream into the net by the current; a current velocity of at
least 0.05 m/s is required for effective use of the Surber or Hess sampler. Further
information on selecting stream-net samplers is given in ASTM (1987f).
Surber and Hess samplers generally do not operate effectively in large rivers,
estuaries, lakes, or other habitats with soft substrates because the current needed to
dislodge and wash invertebrates into the sampler net is lacking. Furthermore, water
that is is too deep flows over the top of the sampler. Consequently, core and grab
samplers are used in these habitats. These techniques are further described in a
handbook by Lind (1979).
8-14
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Corers, such as the Kajak-Brinkhurst (Downing 1984; APHA 1985) and Phleger
(APHA 1985) types, are recommended for soft substrates such as silts or clays.
Corers consist of long, open tubes and rely on gravity to penetrate the substrate.
Various closure methods are used to seal the tube before it is retrieved from a fixed
area of sediment.
Various types of grab samplers are available for sampling macroinvertebrates in
different habitats. Extensive descriptions, including discussions of advantages and
limitations of the various grab samplers, are given by ASTM (1987g). Grab samplers
operate by isolating and removing an area of substrate defined by the area of the open
jaws of the apparatus. Choice of a particular type of sampler depends on the type and
size of substrate and depth of water in the aquatic habitat. Two of the most popular
are the Ekman and Ponar types. Ekman grab samplers (ASTM 1987h; APHA 1985)
are useful for sampling relatively shallow habitats containing soft mud and silt in
water with little current. One person, using a pole mount or remote messenger, can
easily sample the benthos with an Ekman grab sampler from a boat or while wading
in shallow water. The grabs are difficult to use on pebbly or rocky bottoms because
gravel often impedes jaw closure. Ponar grab samplers (APHA 1985; ASTM 1987i)
are used to sample substrates such as sand, gravel, or small rocks in medium to deep
rivers, estuaries, and lakes. The Ponar dredge is heavy and usually requires a boat
and winch for operation.
Specialized sampling devices have been developed for sampling invertebrates on
aquatic vegetation (Downing 1984). The simplest technique is the sweep net. To
collect invertebrate fauna for qualitative samples, a researcher merely sweeps a net
at random through stands of vegetation for a given amount of time or a given number
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of sweeps. Other more quantitative devices enable a worker to isolate a standard
area of vegetation, clip or cut the plants, and remove the sample and associated
fauna. The Wilding stovepipe sampler (APHA 1985) is a metal cylinder useful for
isolating vegetation in soft sediments. A rake and net are used to remove the plants
and fauna. The Macan, Minto, and McCauley samplers are more elaborate devices
containing sharpened, horizontal cutting surfaces in conjunction with a sampling
chamber or box.
Specific cautions must be used in interpreting data on epiphytic invertebrates
(Downing 1984). Invertebrates can escape or fall from vegetation during sampling.
Also, numbers may depend on macrophyte density or surface area rather than on
surface area of sediment. Thus, comparisons of different vegetational densities
among habitats may be biased and should be interpreted with caution. However,
there may be situations in an HWS assessment, such as in littoral areas of lentic
habitats, where vegetation sampling provides useful information.
Macroinvertebrates can also be semiquantitatively collected with several different
varieties of standardized sampling substrates. Such substrates, which are placed into
aquatic environments, can be made of "artificial" components such as tempered
hardboard plates (e.g., the Hester-Dendy sampler) or of natural materials such as
wire baskets containing gravel or rocks (Rosenberg and Resh 1982; Merritt and
Cummins 1984; APHA 1985). Using standardized substrates to collect organisms
relies on the colonization behavior of macroinvertebrates. Caution must, therefore,
be used to ensure data validity; specific cautions and recommendations have been
described (APHA 1985). Optimum time for colonization of substrate samplers before
collection is six weeks. Care should be taken to ensure uniformity in colonization
time, depth, light penetration, temperature, and current velocity (see Table 8-1 for
8-17
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methods) when one makes comparisons between samples obtained with standardized
substrates. The benefit of these types of samplers is their comparability among sites
and relative ease of use. The principal drawback is their relative selectivity in types
and numbers of invertebrates collected; not all taxa are collected in the same
proportions in which they occur on natural substrates. Thus, standardized samplers
are considered semiquantitative techniques. If suitable reference sites are available,
however, one can assume that differences among sites measured are indicative of
HWS effects.
Invertebrates sampled should be isolated and preserved (APHA 1985) and identified
to the desired taxonomic level. Several useful bibliographies of invertebrate keys
have been published (U.S. EPA 1973; Merrit and Cummins 1984; APHA 1985).
Typical endpoints include relative abundance and species (or taxon) richness.
Trophic guild structure can be determined from taxonomic identifications to species
(Merritt and Cummins 1984; Cummins and Wilzbach 1985). Indices of diversity,
evenness, and community similarity can also be calculated.
8.2.3.4 Fish
Quantifying fish population responses remains an important goal of water quality
managers. Fish have been recommended for use in biomonitoring programs for at
least five reasons: (1) regulators and the general public can easily understand the
implications of the effects of pollution on fish; (2) fisheries have economic,
recreational, and aesthetic values; (3) the identification of fishes is relatively easy
(compared to that of micro- and macroinvertebrates); (4) the environmental
requirements of fish are well known; and (5) fish are perceived as "integrators" of
effects at lower trophic levels (Hendricks et al. 1980). However, the size, distribution,
and response of freshwater fishes is sometimes difficult to quantify because
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variations in spatial distribution and year classes are large (Lagler 1978). Additional
difficulties in the quantification offish populations are caused by the selectivity and
efficiency of the gears used (Hendricks et al. 1980). However, proper consideration of
these factors can allow unbiased comparisons of different habitats, leading to a
successful biomonitoring program in which fishes are useful.
Details of several techniques to quantify fish populations are described by the
U.S. Environmental Protection Agency (1973), Lagler (1978), Hendricks et al. (1980),
Hubert (1983) and Platts et al. (1983). Table 8-3 summarizes fish sampling methods.
Two techniques proven to function well in lotic environments are electrofishing and
seining. In large rivers and in lakes, most data on fish abundance and distribution
are provided by electrofishing or passive netting with gill, trammel, or fyke nets
(Lagler 1978).
Electrofishing is based on the principle that when a direct current is applied between
two electrodes in water, fish migrate toward the anode in a galvanotaxic response;
the fish are momentarily stunned and can be easily captured with a dip net. The fish
recover when removed from the electric field and can be readily identified, measured,
weighed, and returned to the water. Electrofishing gear ranges from small, backpack
electrofishing units suitable for small, wadeable streams to large, boat-mounted rigs
for large rivers and lakes. Choices of electrode design, current settings, and pulse
width depend on resistivity (related to hardness, ionic strength, and turbidity) of the
water and thus should be optimized (Lennon 1959). Results from electrofishing
surveys are expressed as catch per unit effort (e.g., numbers or biomass collected per
15 minute interval). Proper safety precautions must be considered and applied when
electrofishing; refer to Sowards (1961) for a discussion of safety considerations.
Hendricks et al. (1980) recommended the judicious use of "deadman's" switches,
8-19
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safety rails, felt-soled rubber boots, rubber gloves, and life jackets. Additionally,
operators should be trained in electrofishing techniques, cardiopulmonary
resuscitation, and electrical theory and safety.
Seines consist of long lengths of netting rigged with Styrofoam or plastic floats at the
top and lead-weighted line at the bottom; a seine is usually operated by manually
pulling vertical poles tied to each end of the net. Seining is most effective in streams,
ponds, and nearshore areas of lakes and impoundments. In large lakes or marine
waters where obstructions are few or lacking, large subsurface trawls can be pulled
by boats to collect fish at different depths. Results from seining or trawling are
expressed as catch per unit of effort.
Passive netting techniques are commonly used to sample fish in large rivers and
lakes. Gill nets are constructed of braided or monofilament lines typically of uniform
mesh size. However, to lessen the size selectivity and to increase the number of fish
species collected in one net, Hubert (1983) recommended that a graded mesh size be
used in gill nets. Trammel nets are modified versions of gill nets, consisting of two
outer panels of large mesh netting plus an inner panel of smaller mesh. Fish pass
through the large mesh and are entangled in the fine mesh netting. Gill and
trammel nets are usually fished on the bottom and are anchored perpendicularly to
the anticipated direction offish movement as a vertical "fence"; as fish swim into the
net, their gills become entangled. Fish caught in gill and trammel nets are often
dead or injured on retrieval which may be important, depending on sampling needs
and goals. These nets are usually operated overnight or for 24-hour periods. Results
are expressed as number or biomass of fish per length of net per unit of time. An
extensive description of gill and trammel net construction, deployment and biases is
given in Hubert (1983).
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Hoop nets and fyke nets are stationary nets that collect fish by entrapment. Hoop
nets, consisting of mesh supported by a series of structural frames or hoops, are
placed on the bottom of large streams and rivers parallel with the current. Fish are
entrapped during normal, upstream movement. Most hoop nets have funne I openings
to keep fish from escaping. Fyke nets are modifications of hoop nets in that they have
wings or leaders that guide fish into the enclosure (Hubert 1983), and are generally
used in shallower waters. Data obtained with hoop or fyke nets are recorded as
number or weight offish per net-day.
Researchers should be careful to ensure uniformity of methods (mesh sizes, sampling
effort) in fish surveys. Studies offish populations or communities often involve only
relative comparisons of differences between reference and impact sites. In these
instances, absolute population estimates are not needed. However, if absolute
population size estimates are sought, gear selectivity must be evaluated. Lagler
(1978) noted that nearly all fishing gear and sampling techniques are selective for
species and sizes of fish. He described an approach to determining the sampling
selectivity of gear: marked fish of different sizes are released into the population and
later recaptured with the same gear; differences in the proportions of different length
groups recaptured by any particular gear provide a direct measure of its selectivity.
In streams (up to approximately sixth order), both upstream and downstream
approaches can be blocked with seines or nets placed across the stream to prevent fish
movement into or out of the sampling area. In these instances, repeated sampling,
either by electrofishing or seining, yields robust estimates of fish species presence
and abundance (Platts et al. 1983).
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The types of analyses performed on data from the collected fish include relative
abundance, species richness, and size structure. In a contaminant effects assessment
program in which the fish are repeatedly sampled, population size can be estimated
by using a maximum likelihood estimation technique or Zippin method after
multiple-step removal-depletion sampling described by Platts et al. (1983).
One promising method for fish community assessment is the Index of Biological
Integrity (IBI) (Karr 1981; Karr et al. 1986), which was developed to determine the
effects of decreased habitat quality on fish communities of midwestern streams. The
IBI is weighted on the basis of individual species tolerances for water quality and
habitat conditions. The index is composed of 12 individual metrics divided into the
fields of species composition and richness, trophic composition, abundance, and
condition. Scores of each metric are classified as "best," "average," or "worst" (each
class having a numerical weighting), according to information from published or
other reliable ichthyological sources for streams of a given size or geographical area
(Fausch et al. 1984). Typically, electrofishing or seining is used to determine the
species composition and relative abundance of the fish in selected habitats. After
each metric is scored, an overall score is computed ranging from 12 (poorest
conditions) to 60 (best conditions).
Representative fish samples may also be taken for residue analyses for contaminant
bioaccumulation. Sampling protocols for collecting fish for contaminant analyses
have been published, including information on target species, collection methods,
handling, preservation, shipping, chain of custody, and quality assurance (U.S. EPA
1982). Residue concentrations can serve as indicators of exposure for contaminants
that bioaccumulate. Residues obtained in fish surveys can be compared to limits for
consumption set by the Food and Drug Administration. However, residue
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information should be interpreted with caution. Many potential contaminants are
ephemeral (e.g., synthetic pyrethroids), rapidly metabolized (e.g., synthetic
pyrethroids and organophosphates), or biotransformed (e.g., polycyclic aromatic
hydrocarbons); these characteristics sometimes make identification of parent
compounds difficult (Hunn 1988). Furthermore, it is difficult to relate observed
contaminant burdens to potential biological effects. Further information on
measurement and interpretation of residue data is given in Chapter 7.
Some observations in fishes that have been used as biological indicators of
contaminant effects are percentage of tumors (Baumann 1984; Baumann et al. 1987),
vertebral anomalies (Bengtsson 1975), disease and parasites (Overstreet and Howse
1977), and fin erosion (Sherwood and Mearns 1977). Leonard and Orth (1986) urge
caution in relying on these features due to several factors: mobility of fishes,
statistical errors in inferences, differential species sensitivity, and subjectivity in
observations. However, these observations can be useful as supportive
measurements in aquatic surveys. In fact, percentage of physical anomalies in fish is
one of the 12 metrics in the IBI (Karr 1981; Karr et al. 1986). Hunn (1988) provides a
checklist for physical examinations of fish in field surveys, as well as other
information useful for field investigations of the effects of contaminants on fishes
(e.g., references and procedures for historical reconstruction of contaminant history,
prediction of contaminant bioavailability, and investigations offish kills).
8.2.4 Methods Integration
8.2.4.1 Selection of Endpoints, Methods, and Approaches
Many criteria can be used to select endpoints for assessments of adverse effects to
aquatic ecosystems (Hammons 1981; NRC 1981; Sheehan 1984). Choices of
endpoints and methods depend on the needs of the survey as well as on site-specific
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characteristics of the HWS. Chapter 3 of this document provides information on
reviewing existing information data bases, initial site assessments, formulating data
objectives, and developing an assessment strategy. Hunn (1988) also provides a
useful discussion of strategies for investigating the effects of contaminants on aquatic
resources.
If insufficient information is available on the aquatic resources at a site, a
preliminary site visit may be required to determine what aquatic resources are
potentially at risk. This visit would require a basic site evaluation consisting of a
physical habitat study (e.g., Platts et al. 1983; Hughes et al. 1986; Plafkin et al. 1988)
and a visual biological assessment. The types of aquatic fauna present, the potential
for adverse effects on biota, and the need for further biological assessment should be
indicated. For instance, no aquatic survey is needed if no aquatic habitats are
present. One should consider, however, that there is always an ultimate receiving
body for water, even though it sometimes may be some distance from the HWS. In
other situations, the HWS may be in an area that is adversely affected by other
sources of chemical contamination or physical disturbance such as sedimentation.
An aquatic survey may provide general information on the existing resources, but
little insight into the effects contributed by the HWS itself. In these situations,
toxicity tests may be more useful in determining potential risk to the aquatic
environment.
If the investigator decides to conduct a preliminary aquatic field survey, the initial
site evaluation should indicate appropriate control and impact assessment sites for a
qualitative survey of macroinvertebrates or fish. In lotic situations, the investigator
could conduct a semiquantitative, rapid bioassessment procedure on
macroinvertebrates (Hilsenhoff 1988; Plafkin et al. 1988) or fish (Plafkin et al. 1988).
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Initial screening tests in standing waters are more difficult, because potential
gradients cannot be easily identified. A qualitative survey can be used to identify
resident flora or fauna, but detection of HWS effects may be difficult. In these
situations, a fish residue survey or a bioassay approach in which water, sediments, or
caged organisms are used may be more useful (see Chapter 6).
Results of the preliminary site survey are used to determine later steps in the
assessment sequence. If an HWS problem is indicated, additional field surveys (in
conjunction with additional laboratory, on-site, or hi situ bioassays) should be
conducted to quantify the extent of adverse effects to the aquatic ecosystem. The
advantages and limitations of using macroinvertebrates, flora, and fish have been
discussed previously. It is difficult to recommend any one trophic component for
study, since needs may vary in individual assessment situations (as indicated in
Chapter 2 on ecological endpoints). However, there are certain instances when
surveys should concentrate on a specific trophic component, such as flora (periphyton
or phytoplankton), invertebrates, or fish.
Macroinvertebrates are commonly used for environmental assessments for several
practical reasons: they occur in all but the most polluted of permanent aquatic
habitats; they can be easily sampled by one person with little time, equipment, or
experience; and they can be rather quickly identified to order or family in the field by
an experienced observer.
There are several situations in which an assessment of the fish community may be
needed. Fish are good bioaccumulators of contaminants and offer sufficient biomass
for assessing contaminant bioavailability. This sort of assessment is important when
the contaminants emission level is low. In such situations, contaminants that are not
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toxic may be bioaccumulated at levels that nevertheless exceed limits for human
consumption. Thus, human health, recreational, and economic problems may result.
Direct quantification of fish population numbers may be needed when recreational
(e.g., sportfish), economic (e.g, commercial fishery), aesthetic (e.g, endangered
species), or legal issues are involved.
Neither macroinvertebrates nor fish respond to nutrients or herbicides in many
instances; an assessment of the primary producers is then recommended. This
contingency should be evident through consideration of site history and.visual
observation of aquatic conditions. The choice of techniques (natural or standardized
substrates) will depend on the time available for the assessment and the inherent
variability of site-specific conditions.
Choosing a trophic component for surveys may also depend on the spatial scale of an
HWS. When there is a defined effluent with little apparent upstream or downstream
influence of other sources of contamination or habitat degradation, periphyton,
macroinvertebrates, or fish could be used to detect the effects of an HWS. However,
when there are numerous other point-source effluents in a stream reach,
macroinvertebrates or periphyton may be more useful than fish since they are
relatively immobile and respond on a spatial scale of a few meters, whereas fish may
respond only on a spatial scale of a kilometer or more.
The time scale is important in intermittent or pulsed contaminant exposures. When
exposures are intermittent and the time between episodes exceeds the generation
time of a species, there is potential for recovery of populations or communities that
could obscure the effects of an HWS. Fish communities, by virtue of their long
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generation time, may then be more sensitive indicators than periphyton, plankton,
and macroin vertebrates.
8.2.4.2 Experimental Design
A sound experimental design is critical to aquatic field surveys that may be
conducted during the assessment of an HWS. The design requires an understanding
of the complexity of aquatic ecosystems so that confounding factors (e.g., current
velocity, depth, light penetration, substrate size, organic matter, and nutrients) are
controlled or accounted for in comparisons. If the sampling regime is thoughtfully
planned and carefully conducted, the results enable biologists to infer causality from
observed changes in numbers of individuals, species distributions, or other variables.
An appropriate experimental design must be developed before a study is started;
mistakes in study design cannot be "statistically corrected" after the sampling is
concluded. (Chapter 4 includes information on selection of reference sites, estimation
of errors, sample numbers, and appropriate data analyses.)
8.2.4.3 Taxonomic Resolution
Consideration must be given to the taxonomic resolution necessary to detect shifts or
alterations in a biological community. Identification to species clearly requires more
expertise than identifications to order, family, or genus. The degree of taxonomic
resolution required will depend on the degree of environmental contamination, the
intensity of effect, and the amount of time and money available for the
bioassessment.
Taxonomic expertise is widely available, if sufficient time is given for identifications.
Ideally, the aquatic survey is begun as early as possible to allow adequate taxonomic
determinations. If sufficient time is not available, identifications to a higher
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taxonomic level should be made, even though some sensitivity may be lost. Costs of
identification are generally nominal compared to other costs incurred in an HWS
investigation. Thus, identification of taxa to genus or species should not be seen as a
hindrance to field surveys.
8.2.5 Examples of Field Surveys
8.2.5.1 Periphyton
Crossey and LaPoint (1988) used standardized granite substrates to study the effects
of mine leachates on periphyton community structure and function in Prickly Pear
Creek, MT. Spring Creek is a tributary contaminated with high concentrations of
cadmium, copper, lead, silver, and zinc from waste piles resulting from mining,
milling, and smelting in the late 1800s. Three sites on Prickly Pear Creek were
studied: a control site, upstream from the confluence with Spring Creek; an impact
site, immediately downstream from the confluence of Spring Creek; and a recovery
site, 12 km downstream from the impact site.
Twelve granite slabs (8 X 10 cm) were placed in unshaded riffle areas of each site;
sites were selected to minimize abiotic factors (current, light, temperature, and
nutrients) that are important in determining rates of periphyton colonization. After
66 days of colonization, substrates were removed for measurement of structural
variables (chlorophyll a, AFDM, cell number, species richness, and diversity) and
functional variables (respiration, net production, and gross primary production).
Also measured were dissolved metals, pH, dissolved oxygen, dissolved nutrients
(NHa, NO2 4-NOa, and PO43-), photosynthetically active radiation, and current
velocity.
8-29
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Sites were found to be similar in all abiotic factors except for concentrations of
dissolved metals, which were known historically to exceed U.S. EPA water quality
standards. Periphyton community structure was found to be significantly different
at the three sites. Diatom species richness and diversity were lowest in the impact
zone due to the metals entering Prickly Pear Creek. Cell abundance, chlorophyll a,
and AFDM of periphyton were significantly higher in the impact and recovery sites,
due to the replacement of diatom species by the green alga Ulothrix sp. and the blue-
green alga Chroococcus sp. Functional variables, although more variable than
structural endpoints, were also altered due to the influence of metals.
8.2.5.2 Benthic Macroinvertebrates
Winner et al. (1980) provide an informative case study, using macroinvertebrate field
surveys to quantify the effects of metals in Elam's Run and Shayler Run, two
second-order streams in southwestern Ohio. Elam's Run had received fluctuating
exposures of Cu, Cr, Zn, and cyanide from the effluent of a metal plating industry
over an eight-year period, and Shayler Run had received a continuous dose of 120
pg/L of Cu for 30 months as part of an EPA experimental stream research project to
evaluate the effects of chronic metal stress on stream fauna (Winner et al. 1975;
Geckler et al. 1976). Macroinvertebrate densities in Elam's Run were determined by
using an invertebrate box sampler, which sampled 0.1 m2 of substrate.
Macroinvertebrate densities in Shayler Run were determined with a Surber sampler,
which sampled 0.09 m2 of substrate. In both streams, substrate was removed from
within the sampler frame and transferred to a tub of water where rocks were
scrubbed with a brush. The contents of the sampler net were added to the tub; tub
contents were then isolated by using a sieve for preservation and identification. Six
stations at Shayler Run (0.07 km above, and 0.2, 0.8, 1.0, 1.2, and 2.6 km below the
point of Cu dosing) and five stations in Elam's Run (0.4, 0.8, 1.0, 2.1, and 3.4 km
8-30
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downstream from the effluent) were monitored. Upstream stations were not
available in Elam's Run because the areas were dry during much of the summer. Two
samples of invertebrates were taken in riffle habitats at each station on each
sampling date. In addition, chemical water quality variables (metals, pH, hardness,
alkalinity, and conductivity) were measured.
Metal concentrations decreased downstream from point of entry in both streams.
However, differences in metal concentrations were not significant between stations
in Elam's Run because temporal and spatial variability were large.
Macroinvertebrate densities were reduced in metal-impacted areas of both streams.
Several non-insect invertebrates, including the bivalve Pisidium, the gastropod
Physa, the isopod Lirceus, the flatworm Dugesia, and the crayfish Orconectes
rusticus were absent or rare in Elam's Run and copper-stressed areas of Shayler Run,
even though they are commonly found in other small, southwestern Ohio streams. In
contrast, tubificid worms were abundant in Elam's Run.
Numbers of individuals and species richness of insects were lowest immediately
below the points of metal addition, but increased with distance downstream in both
streams. Mayflies occurred only in the least polluted sections of the two streams;
caddisflies were numerically important in the unpolluted and intermediately
polluted areas of the streams; and stoneflies were rare in all stations of both streams
(a normal observation for small streams in the area). These observations support the
generalization that species of mayflies, caddisflies, and stoneflies are generally
sensitive indicators of the effects of metals.
The most heavily contaminated areas of the two streams were dominated by
chironomids. The percentage contribution of chironomids to the invertebrate
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community was highly correlated with concentrations of Cu. Thus, as copper
concentrations decreased downstream, the percentage contribution of chironomids to
the invertebrate community decreased as well. Two species, Cricotopus bicinctusand
C. infuscatus. were also numerically dominant in stations in Elam's Run containing
the greatest exposure to copper. Surber (1959) also found C. bicinctus to be tolerant
of metal plating wastes containing chromium, copper, and cyanide.
8.2.5.3 Fish
Paller et al. (1983) and Karr et al. (1985) studied the effects of chlorine and ammonia
from wastewater treatment facilities on fish communities in three streams in Illinois.
Copper Slough, Kaskaskia Ditch, and Saline Branch received wastewater from
secondary sewage facilities, thus receiving chronic exposures of residual chlorine and
ammonia. Paller et al. (1983) monitored the streams at stations above and below
sewage outfalls monthly from November 1979 to June 1981 for water quality (metals,
chlorophyll a, residual chlorine, ammonia, phosphate, dissolved oxygen, pH,
temperature, etc.), and fish community composition. They monitored fish community
composition by electrofishing a 150-m reach of stream using a three-phase, 230-V,
3000-W generator. Fish were identified by species and enumerated, and the total
weight of each species was recorded. In September 1980, chlorination was
discontinued at the treatment plants to determine the effect of chlorine removal on
recovery offish communities; monitoring continued monthly until the study ended.
During the study, moderately diverse fish communities were found above the outfall
in all streams. Species richness ranged from 8.0 to 10.6; the fish communities were
comprised of bass (Micropterus sp.), sunfish (Lepomis sp.), crappie (Pomoxis sp.),
catfish (Ictalurus sp.), northern pike (Esox lucius). grass pickerel (Esox americanus),
native minnows (Nocomis biguttatus. Ericymba buccata. Notropus sp., Phenacobius
8-32
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mirabilis. Pimephales sp., Semotilus atromaculatus. Notemigonus crysoleucas,
Campostoma anomalum). suckers (Carpiodes sp., Catostomus commersoni. Erimyzon
oblongus. Hypentilium nigricans. Moxostoma sp.), freshwater drum (Aplodinotus
grunniens). gizzard shad (Dorosoma cepedianum). darters (Etheostoma sp.), logperch
(Percina caprodes). pirate perch (Aplodinotus grunnies), topminnows (Fundulus
notatus). and common carp (Cyprinus carpio). The percentage of samples composed of
common carp were 36 in Copper Slough, 27 in Kaskaskia Ditch, and 65 in Saline
Branch.. The IBI, calculated by Karr et al. (1985), averaged 35 to 43 in the upstream,
reference areas of the three streams. Chemical analyses showed that water quality
was sufficient to sustain diverse fish populations.
Samples taken downstream from the sewage outfalls during the chlorination phase of
the study showed that fish populations were degraded in all streams. Species
richness ranged from 3.5 in Copper Slough to 9.3 in Kaskakia Ditch. Percentages of
common carp by weight increased in all streams (to 58, 75, and 71 in Kaskaskia
Ditch, Copper Slough, and Saline Branch, respectively). Degradation of the fish
community was further reflected in calculations of the IBI, which ranged from 21 to
31 in the three streams. Decreases in the quality of the fish community were
attributed to high levels (0.5 to 1.7 mg/L) of residual chlorine in all streams; low
dissolved oxygen as well as the presence of ammonia and silver were additional
concerns in Saline Branch.
When effluent chlorination was stopped, the fish community recovered in
downstream locations of Copper Slough and Kaskaskia Ditch; fish species richness
and IBI values increased (the richness mean from 11.6 to 13.5, and the mean from 35
to 45), whereas the percentage of common carp by weight decreased to less than 18.
Although residual chlorine was eliminated in Saline Branch, the fish community did
8-33
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not recover during the chlorine-removal portion of the study; species richness
remained low (3.9) and percentage common carp by weight remained high (79)
because of low dissolved oxygen (< 2.5mg/L), and high concentrations of ammonia
(0.50 mg/L, un-ionized form) and silver (.0247 mg/L).
8.2.6 References
American Public Health Association (APHA). 1985. Standard Methods for the
Examination of Water and Wastewater. American Public Health Association,
Washington, DC. 1268pp.
American Society for Testing and Materials (ASTM). 1987a. Annual Book of ASTM
Standards: Water and Environmental Technology, Vol. 11.04. American Society for
Testing and Materials, Philadelphia, PA. 1103 pp.
American Society for Testing and Materials (ASTM). 1987b. Standard practice for
sampling phytoplankton with water-sampling bottles. Pages 53-54. In: Annual
Book of ASTM Standards: Water and Environmental Technology, Vol. 11.04.
American Society for Testing and Materials, Philadelphia, PA.
American Society for Testing' and Materials (ASTM). 1987c. Standard practice for
sampling phytoplankton with pumps. Pages 45-46. In: Annual Book of ASTM
Standards: Water and Environmental Technology, Vol. 11.04. American Society for
Testing and Materials, Philadelphia, PA.
American Society for Testing and Materials (ASTM). 1987d. Standard practice for
sampling phytoplankton with conical tow nets. Pages 42-44. In: Annual Book of
ASTM Standards: Water and Environmental Technology, Vol. 11.04. American
Society for Testing and Materials, Philadelphia, PA.
American Society for Testing and Materials (ASTM). 1987e. Standard practice
collecting benthic macroinvertebrates with Surber and related type samplers. Pages
156-158. In: Annual Book of ASTM Standards: Water and Environmental
Technology, Vol. 11.04. American Society for Testing and Materials, Philadelphia,
PA.
American Society for Testing and Materials (ASTM). 1987f. Standard practice for
selecting stream-net sampling devices for collecting benthic macroinvertebrates.
Pages 144-155. In: Annual Book of ASTM Standards: Water and Environmental
Technology, Vol. 11.04. American Society for Testing and Materials, Philadelphia,
PA.
American Society for Testing and Materials (ASTM). 1987g. Standard practice for
selecting grab sampling devices for collecting benthic macroinvertebrates. Pages 91-
106. In: Annual Book of ASTM Standards: Water and Environmental Technology,
Vol. 11.04. American Society for Testing and Materials, Philadelphia, PA.
American Society for Testing and Materials (ASTM). 1987h. Standard practice for
collecting benthic macroinvertebrates with Ekman grab sampler. Pages 79-80. In:
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Annual Book of ASTM Standards: Water and Environmental Technology, Vol. 11.04.
American Society for Testing and Materials, Philadelphia, PA.
American Society for Testing and Materials (ASTM). 1987i. Standard practice for
collecting benthic macroinvertebrates with ponar grab sampler. Pages 77-78. In:
Annual Book of ASTM Standards: Water and Environmental Technology, Vol. 11.04.
American Society for Testing and Materials, Philadelphia, PA.
Baumann, P.C. 1984. Cancer in wild freshwater fish populations with emphasis on
the Great Lakes. J. Great Lakes Res. 10:251-253.
Baumann, P.C., W.D. Smith, and W.K. Parland. 1987. Tumor frequencies and
contaminant concentrations in brown bullheads from an industrialized river and a
recreational lake. Trans. Am. Fish. Soc. 116:79-86.
Bengtsson, B.E. 1975. Vertebral damage in fish induced by pollutants. Pages 48-70.
In: Koeman, J.H., and J.J. Strik, eds., Sublethal Effects of Toxic Chemicals on
Aquatic Animals. Elsevier Scientific, Amsterdam.
Bloesch, J., ed. 1988. Mesocosm Studies. Hydrobiologia 159:221-313. W. Junk,
Publishers, Dordrecht, the Netherlands.
Courtemanch, D.L., and S.P. Davies. 1987. A coefficient of community loss to assess
detrimental change in aquatic communities. Water Res. 21:217-222.
Crossey, M.J., and T.W. LaPoint. 1988. A comparison of periphyton community
structural and functional responses to heavy metals. Hydrobiologia 162:109-121.
Cummins, K.W., and M.A. Wilzbach. 1985. Field procedures for analysis of
functional feeding groups of stream macroinvertebrates. Contribution 1611 to
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8.3 VEGETATION ASSESSMENT -- Lawrence A. Kapustka
8.3.1 Introduction
8.3.1.1 Accessibility
Access to hazardous waste sites (HWSs) generally is restricted due to
legal/proprietary and human health risk considerations. Restricted access imposes
significant constraints on ecological assessment. However, vegetation can be
analyzed in ways that overcome such access limitations.
General landscape pattern and gross structural features of vegetation can be inferred
from conventional aerial photography. More sophisticated measures can be derived
through remote radiometric sensing. Photosynthesis responds to environmental
stress in ways that affect the spectral reflectance and fluorescence radiance
emanating from a plant, and this phenomenon provides unique assessment
opportunities for remote sensing. Remote sensing of vegetation affords access to
restricted sites and can be used in limited cases on archived radiometric data. No
other ecological community is so amenable to passive, non-intrusive assessment.
Indeed, because of the dependency of other life forms on plants, quantization of plant
communities by remote sensing may be the best means of acquiring preliminary
estimates of impact for dependent groups (i.e., habitat structure may be useful in
predicting animal use rates and exposure levels).
8.3.1.2 Biological Importance
Vegetation is the dominant biological component of terrestrial ecosystems, with
nominally ten biomass units of plants, to four biomass units of microbial organisms,
to one biomass unit of animals. Depending upon the species, soil characteristics, and
environmental stresses, 40% to 85% of the plant mass resides below ground in contact
with chemicals in the soil. The impact of hazardous waste on vegetation may be
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realized in a variety of ways and with different consequences (see Table 8-4). On the
macroscale, plants are the biological source of energy as well as nutritional
components for animals. Furthermore, the structure of vegetation, in concert with
the varied abiotic landscape features, establishes habitat that animals rely on for
protection from adverse weather and predators.
Table 8-4. Generic Negative Impacts of Hazardous Materials on Plants That
Influence Vegetational Characteristics
Primary/Direct Impacts
• quantitative suppression of plant growth
• qualitative shift in community composition and/or shift in community
structure
Secondary/Indirect Impacts
• quantitative impairment of plant-microbial interactions affecting energy
flow and nutrient cycling processes (decomposition, symbiotic relationships)
• altered animal use either for food or habitat
The important features of plants for ecological assessments include the following:
• they respond to stressors found in soils through altered photosynthetic and
respiratory rates;
• they harbor microbial populations in their root systems that facilitate uptake
and metabolism of various organic and inorganic constituents including
pollutants;
• they sequester and/or metabolize toxic substances in organs and tissues both
above and below ground;
• they serve as a conduit of toxic substances into the food web; and
• they stabilize soils against wind- and water-mediated sheet erosion, thereby
reducing mass transport of hazardous materials from the site.
Plants should be considered an important component of any ecological assessment of
hazardous waste sites. To assess the full consequences of a contaminated site, it is
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crucial that analyses of the vegetation be integrated into the context of the landscape
features surrounding the site. Furthermore, the plants growing in the contamination
zone should receive careful consideration as candidates for toxicity testing and
monitoring studies since they have already demonstrated a tolerance of the
contaminants.
The vegetation growing on a site may be composed of cover crops planted specifically
to stabilize soil surfaces, naturally occurring vegetation (including native and
naturalized species), or some mixture of natural and planted species. As the degree of
"naturalness" increases, so does the ecological complexity, and thus greater levels of
analytical sophistication are required to ascertain the site's ecological condition.
This section outlines an approach to vegetation assessment relevant to contaminated
sites. The categories include remote sensing, direct vegetation measurements, and
selected functional (or process-oriented) measurements. The objectives for each level
of assessment are as follows:
Remote Sensing
• To gain current and historical information on land use and to establish
generalized perspectives of landscape interactions.
• To define generalized vegetation patterns (especially gross structural
attributes) suitable for habitat classification.
• To aid in defining the boundaries of impact (in some situations, especially
where plants exhibit stress responses to contaminants).
Direct Vegetation Sampling
• To verify patterns discerned from remote sensing.
• To provide community composition data (i.e., species identity and
dominance/density values).
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Functional Processes
• To evaluate direct impacts on vegetation.
• To identify probable secondary impacts that may affect animal populations or
other ecosystem processes.
Many excellent papers, texts, and manuals contain detailed descriptions of methods
for vegetation sampling and analysis (e.g., Greig-Smith 1983). Often, the conditions
of a hazardous waste site preclude extensive reliance on the direct techniques of
vegetation sampling. The guiding principles for suggesting the measurements
described in this section were couched in the following questions:
• Does the measurement provide information that allows one to document or
infer ecological impact?
• Can the measurement data be obtained rapidly (i.e., minimizing on site effort
and exposure time of workers) while adhering to high standards for accuracy
and precision?
• Has the utility of the measurement for ecological assessment been
demonstrated?
The following sections discuss vegetation assessment methods. Each of the methods
discussed should be considered a Class I test.
8.3.2 Remote Sensing Methods
Remote sensing may be used advantageously in a number of ways to assess
vegetation of hazardous waste sites. Primary sources of radiometric data are the
Landsat Multi Spectral Scanner (MSS), the Thematic Mapper (TM), and the French
Systeme Probatoire d'Observation de la Terre (SPOT) data banks. Resolution is the
major limitation of these satellite imaging systems. Pixel resolution limits for the
three types are: MSS, 80 m; TM, 30 m; and SPOT, 20 m. For improved resolution, the
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satellite images may be supplemented with fixed-wing aircraft flights utilizing
comparable sensing equipment. The flights may also employ infrared and
conventional photography. Coordinated work at individual sites for verification
("ground truthing") or for additional resolution can be performed from "cherry
picker" booms with field model sensors. This tiered approach provides the following
advantages:
• relatively unlimited accessibility;
• safe, non-intrusive assessment and monitoring; and
• through archived data (MSS since 1972; TM since 1982; SPOT since 1984;
global coverage each 18 days), the opportunity to assess large-scale seasonal
and annual vegetational patterns.
Radiometric data have been used effectively (Duinker and Nilsson 1988; Hardisky et
al. 1986; Mohler et al. 1986; Rock et al. 1986; Roller and Colwell 1986; Waring et al.
1986) to accomplish the following objectives:
• to map vegetational boundaries (detecting shifts in dominant canopy species
within a given forest type),
• to estimate net photosynthesis and net primary production,
• to estimate foliar nitrogen content,
• to detect drought stress,
• to detect effects from pest epidemics such as gypsy moth, and
• to assess forest decline due to air pollutants.
Conventional aerial photography should also be incorporated into the vegetation
assessment. Most of the continental United States has been photographed repeatedly
since 1938. Although the photographic record is incomplete and sporadic, and
technical limitations (such as varied camera angle and altitude) are typically great,
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the photographic records contain valuable qualitative information on vegetation and
land use patterns over a 50 year time span. Even subjective knowledge of generalized
trends over five decades can offer important interpretive perspectives to ecological
assessment.
8.3.3 Direct Observational Methods
The contamination characteristics of a site may require special precautionary steps
to protect the personnel conducting on-site vegetational measurements.
Contamination characteristics should be the primary consideration in selecting the
detail of the measurement. The specific objectives of vegetation sampling should be
defined early in the assessment process since the objectives dictate thoroughness and
methodology options.
The first phase of direct observations should be directed toward ground truthing of
the remote sensing results. This should be initiated with analysis of the off-site,
uncontaminated border regions associated with the contaminated area. Clearly it is
most desirable to validate the remotely sensed data with field data from the
contaminated site under study. However, it may not be feasible to gain the required
access to the site and the site may pose unreasonable risk to the research personnel.
Even if the only validation is from adjacent border regions, the remotely sensed data
will be valuable in assessing the vegetation on the affected site.
8.3.3.1 Ground Truth Maps/Qualitative Assessments -- Floristics
Visiting the site is required to verify the community transitions/breaks indicated in
aerial photos and to identify all prominent species. Depending on the site, multiple
visits at different seasons may be needed to capture the breadth of species richness
within the communities. Botanists familiar with the regional and local flora should
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be employed to compile the floristics checklist and to spot unusual gaps in the
assemblages of species. The utility of synthetic community measures (such as the
Species Diversity Indices, Indices of Similarity, etc.) are affected greatly by the
degree of taxonomic discrimination associated with primary data collection.
8.3.3.2 Ground Truth Maps/Qualitative Assessments--Kelevee
A semi quantitative analysis of the vegetation may be sufficient to satisfy the
objectives for many sites (e.g., highly disturbed and biologically isolated locales, sites
that pose unacceptable risk to personnel, or sites that satisfy criteria for remote
sensing analysis and only require generalized "ground-truthing"). The Relevee
method (Braun-Blanquet 1932) is in effect a structured, subjective reconnaissance
that uses flexible, loosely defined sampling areas (see Table 8-5) and generalized
ranges of cover estimates (see Table 8-6). Additional information on growth habit
(technically referred to as sociability), may be taken (see Table 8-7). Because of its
subjectivity, the method may be the most cost-effective means of detecting gross
differences in community organization or species assemblages associated with
contamination. However, because Relevee is highly subjective and only
semiquantitative, traditional parametric statistics are inappropriate to analyze the
data. It is important to remember that this technique was developed to obtain
information that could be used to classify similar vegetation types in discernable
groups. It introduces a level of discipline in the collection of data through an
otherwise subjective technique.
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Table 8-5. Estimated Minimal Area for Each Relevee Survey for
Selected Vegetation Types
Vegetation Type Surface Area (M2)
Temperate Forest 200 - 500
Trees 200 - 500
Shrubs/herbs 50-200
Grassland 50-100
Wetlands/Meadows 5 - 25
Table 8-6. Modified Braun-Blanquet Cover Class Ranges
Class Contribution to Total Cover
Cover Class
5
4
3
2
1
Range, in %
75 to 100
50 to < 75
25 to < 50
5 to < 25
1 to <5
Mean, in
87.5
62.5
37.5
15.0
3.0
%a
<1 0.5
Observed but so rare as to not contribute
measurably
Note: the algebraic mid-point of the cover class range is routinely used in
calculations, even though the values do not carry as many significant figures as
implied.
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Table 8-7. Braun-Hlanquet Plant Sociability Classes
Class Criteria
5 occurring in large, nearly pure stands
4 occurring in large aggregates (e.g., coppice or in carpets)
3 occurring in small aggregates, clusters, or cushions
2 occurring in clumps or bunches
1 occurring singly
In the initial design, the investigator selects a "representative" site within a
particular vegetation stand. A single Relevee sample is recorded. Various stands are
sampled for the purposes of classifying vegetation types. The single most important
"assurance" of the quality of the data is the ability of the investigator to select the
representative site within the stand based on "prior knowledge of what was typical"
for the given vegetation.
For assessment of vegetation at hazardous sites, a series of Relevee samples can be
collected within the affected area and from adjacent unaffected zones. These data
sets can then be examined according to the traditional Bran-Blanquet classification
strategy.
8.3.3.3 General Vegetation Sampling Strategy
Various approaches to quantitative vegetation sampling can be used for HWS
assessments. Often, the details of the sampling procedure are varied to accommodate
the structural and distributional features of vegetation type. Within each
generalized method, the investigator has several options available (e.g., position,
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plotless versus defined area plots, size, shape, number, and several other factors).
Greig-Smith (1983) provides a detailed theoretical treatment of vegetation sampling.
Other excellent treatments of vegetation sampling, typically with fewer theoretical
considerations, are Chapman (1976), Green (1979), Meyers and Shelton (1980), and
Mueller-Dombois and Ellenberg (1974). Given the special constraints and
considerations of hazardous waste sites, the following strategies are recommended.
8.3.3.3.1 Stratified Random Position. For each distinct vegetation type or unit
(e.g., grass, shrub community, forest), divide the unit into four or more zones of
approximately equal area. Distribute the sample locations (approximately equal
numbers per zone) randomly within each zone.
8.3.3.3.2 Sample Size. Within each vegetation type, use either a minimum (e.g., N
= 20) or an estimated sample size to achieve adequacy of sample. Adequacy of
sample may be estimated according to the following equation:
N = [S2 t2]/d2
where:
N = sample size
S2 = sample variance for density or cover
t = Student's t table value for the a = 0.05 level and the appropriate degrees of
freedom (sample number used to calculate variance
d = the allowable error; here for standardization purposes use 10% of the
mean density or cover.
8.3.3.3.3 Plot Size. Plot Shape, and Data Collection. There is a wealth of
literature devoted to determining size and shape of the sample plot and the type of
data one should record for each. Trees, shrubs, and herbaceous vegetation may be
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considered separately. The following definitions, methods for establishing plots, and
guidelines for data collection within plots are accepted widely among plant ecologists.
Trees are defined as erect, woody plants having a stem diameter _>_ 10 cm at 1.4 m
above ground level (Diameter at Breast Height, DBH). Juveniles of tree species with
lesser DBH are typically scored in the shrub category.
Point method: The point-quarters method is by far the most efficient way to
quantify trees. For each point, record the species, distance, and DBH of the four
designated trees.
Defined Area: Typically, a square plot 10m x 10m is established. For each tree
within the plot, record the species and DBH.
Shrubs are defined as erect or prostrate woody plants (including individuals of tree
species) <_ 10 cm DBH.
Defined Area: A plot of known area defined by a square or circular boundary (e.g.,
1 m2; or 2m x 2m) is established. The number of stems of each species within each
plot is recorded. An estimate of canopy cover may be used as an estimator of
dominance.
Herbaceous plants are all non-woody plants including bryophytes and lichens. Two
different approaches to defined area sampling of herbaceous vegetation are
commonly employed.
Cover Method: A rectangular plot (0.1 to 1.0 m2; smaller sizes used in denser
vegetation) is typically segmented to aid one in estimating cover. Cover classes
listed in Table 8-6 are often used. The cover value is recorded for each species
present in each plot.
Harvest or Clip-plot Method: This method is used to obtain aerial phytomass
values for each species within each plot. A circular plot (0.1 to 1.0 m2; smaller sizes
used in denser vegetation) is established. The vegetation is severed at ground level
and sorted according to species. The plant material is then dried in an oven at 70 to
80° C for 24 hours (or until constant weight is established). The material should be
placed in a desiccator while it cools to room temperature (especially in humid
environments) and then the weight is recorded. The raw data should be tabulated
by plot and by species within each plot.
8.3.3.3.4 Collection of Stems and Roots. In addition to collecting the typical data
for community descriptions, there may be reasons to collect stem and root sections or
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cores. Annual rings can provide direct evidence of changes in growth rates. Growth
rates may be compared to known trends for a species or against rates measured for
plants outside of the impacted area. Tissues may also be used to determine chemical
concentrations or isotope values (discussed later) for tissues spanning the temporal
ranges from pre-impact to present (or time of death of the individual).
8.3.3.3.5 Data Summary. Data summaries should be prepared for each discernable
vegetation unit, both off site and on site. For trees, this includes the calculated
estimates of density (number of individuals per hectare), basal area (the stem cross-
sectional area calculated from the measures of DBH, a surrogate value for
dominance), frequency (the percentage of plots having a particular species), and the
importance percentage (IP, the mean of the normalized density, basal-area, and
frequency values). These calculations, which are to be prepared for each species,
yield average values that should be accompanied by standard error estimates (Cox
1985).
Comparable calculations are performed for the shrub and herbaceous plants. Cover
estimates or phytomass values are used in place of basal area for shrubs and
herbaceous plants. In the herbaceous plant sample methods, one does not acquire a
measure of density.
The summary values as calculated above may be used to calculate various synthetic
indices such as species diversity or coefficient of community. Extreme caution must
accompany any interpretation of such values, since natural succession and stress
affect the diversity of a community in non-linear patterns. Also, the indices do not
provide for inclusion of variance or precision estimates. Furthermore, the effect of an
HWS may be to elevate or decrease diversity. Qualitative values of harm or benefit
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cannot be assigned to fluxes in diversity in the absence of careful ecological analysis
of the underlying features affecting a given change.
8.3.3.4 Symbiont Measurements
Stresses observed in plants may be indirect. The health of most plants is highly
dependent upon the microbial flora residing within the root system, the rhizosphere.
Associative bacteria and mycorrhizal fungi play important roles in inorganic
nutrient uptake, topological complexity of root architecture, moisture stress
tolerance, and "resistance" to pathological invasions. Assessments of the microbial
community in terms of species richness and numbers of propagules of selected guilds
offers valuable information in determining the magnitude of stress as well as the
recovery potential. At present, the techniques for enumeration of the microbial
populations rely on bioassays with target plants, laboratory culturing, and direct
microscopic counting (Doetsch and Cook 1973). Development of sensitive detection
systems for specific microbes utilizing DNA probes is underway. Within the next few
years, it will be possible to test the efficacy of such advanced technologies for
assessing the health of microbial systems. Until then, more traditional measures of
critical microbial constituents are recommended. Following are brief descriptions of
two microbial assessment techniques.
8.3.3.4.1 Vesicular Arbuscular (VA) Mycorrhizae. Select 10 species found both
on- and off-site. Score the percentage colonization for at least five individuals of each
species from each site. Roots should be harvested from the top 20 cm of soil. If it is
impractical to harvest roots with the stem attached, take precautions to verify that
the roots are from the selected plant species. The roots should be processed following
the Trypan Blue staining method of Phillips and Hayman (1970) and scored for
percentage colonization according to the grid-line intercept method (Giovarietti and
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Mosse 1980). This procedure should be performed by a specialist trained to recognize
the diagnostic features of VAM fungi (spores, arbuscules, coiled hyphae, penetration
pegs, etc.). Employ 2-way ANOVA (level 1, site; level 2, species; with replication) to
detect differences in mycorrhizal colonization values. See Chapter 4 for potential
problems in hypothesis testing.
8.3.3.4.2 Diazotroph. Examine populations of legumes on- and off-site and score the
numbers and mass of nodules. Visually check for leghemoglobin. Examine
populations of actinorhizal species and compile data on nodule numbers and nodule
mass. Not all areas will have legumes or actinorhizal plant species. Thus, the
numbers of species and the number of specimens within species to be examined
cannot be prescribed. Care should be taken to design a sampling strategy that
permits valid statistical evaluation.
8.3.4 Process Measurement Methods
8.3.4.1 Bioaccumulation of Toxic Metals
Plant samples of species found both on- and off-site should be collected and processed
to determine the concentrations of nutrients and toxic metals. Representatives of
various combinations of plants should be included in the samples (e.g., annuals and
perennials, herbaceous and woody, fibrous root and tap root). Both aerial and root
samples should be utilized. Total carbon and total nitrogen values should also be
obtained to permit direct comparisons of mass and ratios of materials in the plants.
Sampling design should be structured to permit statistical analyses by ANOVA. See
Chapter 4 for potential problems in hypothesis testing.
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8.3.4.2 Bioaccumulation of Organic Chemicals
Plant samples similar to those collected for metal analysis should be processed for
selective analysis of xenobiotic constituents. Special precautions to minimize
volatilization and metabolism of the organic chemicals must be employed. The
selection of chemicals to be assayed should be guided by what is known about the
types of hazardous chemicals expected to be present at the site.
8.3.4.3 Photosynthesis
Sophisticated methods of analyzing photosynthetic condition are available. Portable
units (e.g., LICOR 6000) can be used to measure the "instantaneous" rates of net CO-z
uptake. There are many technical considerations that require skilled personnel to
ensure reliability of the resulting data. If the proper precautions are taken, however,
excellent comparative data can be obtained to assess the impact of stress imposed by
hazardous materials on the photosynthetic process. The same instrument may be
used to measure respiratory rates of non-photosynthetic tissues or darkened
photosynthetic tissues.
There are now prototype models available of instruments that enable discrimination
of the photosynthetic process into functional segments. These instruments rely upon
the phenomena known as rapid fluorescence and delay fluorescence. Through a
series of sensitive receptors, photomultipliers, and elaborate electronics, the
instruments are able to detect the fluorescence at picosecond intervals. The rates and
magnitude of fluorescent radiance allow the precise determination of the rate-
limiting photosynthetic process. This approach, because it assesses the functional
organization of the photosynthetic apparatus, is not subject to transient fluxes
associated with the "instantaneous" measures of CO2 uptake.
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Another approach to assessing the photosynthetic process is isotope discrimination.
The biophysical and biochemical features of leaves impose resistance to the
incorporation of CO2 (Farquhar et al. 1982; Hattersley 1982; O'Leary 1981). As a
consequence of this resistance, plants discriminate among isotopes. This
discrimination is confirmed by a comparison of the natural abundance of 13C and 12C
to the abundance found in plants. Furthermore, the alternative photosynthetic
pathways among plants exhibit differing levels of discrimination. Basically, any
factor that affects the resistance of CO2 influx enhances the discrimination. Thus,
stressors that affect stomatal opening can be expected to alter the discrimination.
Peterson and Fry (1987) provide an excellent discussion of the processes of isotope
discrimination and illustrate their uses for ecosystem analyses through several case
studies.
The important feature of discrimination in the context of assessing hazardous waste
sites is that the process of discrimination is cumulative over extended periods of time.
Thus, a low level of stress, for example 1% (a depression level not likely to be detected
by any instantaneous measure), will be compounded over time. This could prove to be
a very powerful tool, especially with long-lived perennial plants. To date, however,
this technique has not been utilized to evaluate chemical stresses. The technology to
perform the basic data collection (i.e., the measurement of isotope ratios) is well
established and analyses can be performed at a cost of $30 to $100 per sample.
8.3.5 Recommended Assessment Approach
The following summary provides a sequential framework for assessing vegetation of
hazardous waste sites. At virtually every step, decisions are made to proceed with
the next level of information or to terminate the assessment. This procedure allows
site conditions and objectives to guide the detail of vegetation sampling.
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• Assemble site maps and aerial photos.
• Define the target zones to be measured.
• Acquire remotely sensed radiometric data.
• Develop "first cut" vegetation maps.
• Perform the required ground-truthing steps.
• Determine the general vegetation characteristics with the Relevee technique.
• Determine the importance of acquiring more detailed vegetation assessment.
•) If appropriate, follow up with quantitative assessments using:
higher resolution remote sensing of existing vegetation (and past
vegetation, as records permit)
quantitative, companion ground surveys
quantitative assessment of symbiotic associations
analysis of the toxic metal and xenobiotic content of plant tissues.
8.3.6 References
Braun-Blanquet, J. 1932. Plant Sociology: The Study of Plant Communities.
McGraw Hill, New York, NY.
Chapman, S.B. 1976. Methods in Plant Ecology. John Wiley and Sons, New York,
NY.
Cox, G.W. 1985. Laboratory Manual of General Ecology. W.C. Brown, Dubuque, IA.
Doetsch, R.N. and T.M. Cook. 1973. Intoduction to Bacteria and Their Ecobiology.
University Park, Press, Baltimore, MD.
Duinker, P. and S. Nilsson. 1988. Proceedings: Seminar on remote sensing of forest
decline attributed to air pollution. International Institute for Applied Systems
Analysis, Laxenburg, Austria (EPRIEA-5715, Project 2661-19).
Farquhar, G.D., M.H. O'Leary, and J.A. Berry. 1982. On the relationship between
carbon isotope discrimination and the intercellular carbon dioxide concentration in
leaves. Aust.J. Plant Physiol. 9:121-137.
Giovanetti, M. and B. Mosse. 1980. An evaluation of techniques for measuring
vesicular-arbuscular mycorrhizal infection in roots. New Phytol. 84:489-500.
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Green, R.H. 1979. Sampling design and statistical methods for environmental
biologists. Wiley Interscience.
Greig-Smith, P. 1983. Quantitative Plant Ecology. Third Edition. University of
California Press, Berkeley, CA. 359 pp.
Hardisky, M.A., M.F. Gross, and V. Klemas. 1986. Remote sensing of coastal
wetlands. Bioscience. 36:453-460.
Hattersley, P.W. 1982. Delta 13C values of 64 types in grasses. Aust. J. Plant
Physiol. 9:139-154.
Meyers, W.L. and R.L. Shelton. 1980. Survey Methods for Ecosystem Management.
John Wiley and Sons, New York, NY.
Mohler, R.R.J., G.L. Wells, D.R. Hallum and M.H. Trenchard. 1986. Monitoring
vegetation of drought environments. Bioscience. 36:478-483.
Mueller-Dombois, D. and H. Ellenberg. 1974. Aims and Methods of Vegetation
Ecology. Wiley Interscience.
O'Leary, M.H. 1981. Carbon isotope fractionation in plants. Phytochemistry.
20:553-567.
Peterson, B.J. and B. Fry. 1987. Stable isotopes in ecosystem studies. Ann. Rev.
Ecol. and Syst. 18:293-320.
Phillips, J. M. and D. S. Hayman. 1970. Improved procedures for clearing and
staining parasitic and vesicular-arbuscular mycorrhizal fungi for rapid assessment of
infection. Trans. Br. Mycol. Soc. 55:158-161.
Rock, B.N., J.E. Vogelmann, D.L. Williams, A.F. Vogelmann, and T. Hoshizaki.
1986. Remote detection of forest damage. Bioscience. 36:439-445.
Roller, N.E.G. and J.E. Colwell. 1986. Coarse-resolution satellite data for ecological
surveys. Bioscience. 36:468-475.
Waring, R.H., J.D. Aber, J.M. Melillo, and B. Moore, EQ. 1986. Precursors of change
in terrestrial ecosystems. Bioscience. 36:433-438.
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8.4 FIELD SURVEYS: TERRESTRIAL VERTEBRATES » Karen McBee
8.4.1 Introduction
The purpose of this section is to review several methods for surveying populations of
terrestrial vertebrates, including methods of capture or sampling, determination of
demographic characteristics, and measurements of ecological diversity. Ways in
which field surveys can be integrated with in situ assessments of bioaccumulation
and assays of exposure and effects (see Chapter 7) are also discussed. The techniques
and procedures presented in this section should be considered Class I methods.
8.4.2 Class I Methods
8.4.2.1 Determination of Demographic Characteristics
To determine if terrestrial vertebrate populations have been adversely affected at
hazardous waste sites, investigators must accurately census or estimate numbers of
resident species, determine sex and age ratios, and estimate natality and mortality.
Davis and Winstead (1980) review methods for estimating numbers of terrestrial
vertebrate populations. They point out that accurate estimation of animal
population size requires knowledge of the ecology and behavior of the species being
sampled. General assumptions for any population sampling study are that mortality
and recruitment during the sampling or capturing period are small and that all
members of the population have an equal chance of being sampled.
Davis and Winstead (1980) classify methods for estimating animal populations into
the following categories:
I. Count Animals
A. Count all animals present in a given area - a true census.
B. Sample counts of animals - an estimate of animals present at a given site.
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n. Count Signs
A. Count all signs in a given area - an index of a true census.
B. Sample counts of signs - an index estimate of animals present at a given
site.
A complete census of all members of a population is usually impossible, therefore
sampling methods that estimate population numbers may provide the most feasible
means of determining impacts on vertebrate populations at hazardous waste sites.
Transect and quadrat counts are the most commonly used sampling methods.
Animals can be sampled through direct observation by investigators who walk along
established transects or from point-to-point within quadrats. Population sampling
may also be conducted by setting trap lines along transects, or in quadrats, and
recording the number and trap site of animals captured. Counts should be made for
several areas within the study site or several counts of the same area should be made
over a period of time. Anderson et al. (1976) review transect and quadrat sampling
methods.
Estimates of animal population numbers can also be based on observation of animal
"signs." The sampling design and statistical treatments are essentially the same as
for direct observation or capture data. Commonly used types of sign include numbers
of dens, burrows, or nests; counts of tracks, feces, songs, and calls; and counts of
carcasses. Davis and Winstead (1980) question the validity and accuracy of
population estimates based on counts of sign, however, and offer several cautionary
comments in conducting such studies.
Many methods are available to estimate population sizes from capture studies,
including sum of daily captures, cumulative sum of captures, probability of capture,
catch effort, and change in some descriptive ratio (Davis and Winstead 1980). All
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these methods require multiple sampling periods, often over extended periods of
time.
Methods of population estimation based on capture-recapture of marked individuals
may provide the most accurate information on population sizes. Davis and Winstead
(1980) provide detailed examples of the Lincoln Index and the Schnabel Method,
(which require accumulation of capture-recapture data over an extended period of
time) and the Schumacher-Eschmeyer Procedure. They discuss the advantages and
shortcomings of each of these methods. Seber (1973) considers the Lincoln Index the
most useful for data based on capture and recapture of marked individuals.
Knowledge of demographic parameters, such as sex and age ratios, reproductive
success or natality and rearing success, and survival and mortality rates, is essential
in judging the impact of polluted habitat on resident populations. Downing (1980)
recommends that accurate data on population size and density plus several
demographic parameters be measured at several time intervals in order to assess the
status of short-lived, fluctuating species. Larger, longer-lived species may need much
less intense investigation.
Information on sex ratios will indicate whether or not populations are present in
sufficient numbers and proportions for normal reproductive activity. Age ratios will
provide information on natality and rearing success, age-specific reproductive rates,
and mortality and survival rates. Investigators should be familiar with methods to
determine the sex and the age of all individuals captured in field surveys. Larson and
Taber (1980) review methods for sex and age determination in birds and mammals.
Sex and age ratios may be subject to bias because one sex or age group may be more
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easily captured than another or because seasonal differences and migration behavior
may affect age and sex distributions at any given time and place (Downing 1980).
Estimates of natality and rearing success may be difficult to obtain because young
are usually protected in hidden dens or nest sites and are not as active as adults, thus
making them less likely to be captured. Information on natality and rearing success
can be estimated from counts of nests, by recording the proportion of lactating female
mammals captured, and by determining the proportion of birds that have brood
patches. Examination of reproductive tracts for number and size of embryos, number
of placental scars, and luteal counts in ovaries (Kirkpatrick 1980) can also provide
information on fertility, fecundity, and natality.
Downing (1980) reviews methods for determining mortality and survival based on
capture data. He emphasizes the shortcomings of single-sample death surveys in
mortality studies and recommends that as many kinds of demographic information as
possible be collected when conducting studies of the welfare of animal populations.
8.4.2.2 Measurements of Ecological Diversity
Measures of ecological diversity are potential tools for evaluating contaminant
effects on terrestrial vertebrate communities. Species diversity data (along with
information on reproduction, survivorship, and mortality of individual species) allow
evaluation of current impact and predictions of potential impacts of habitat
disruption on the structure and function of communities.
Community composition can be assessed by species frequency, species per unit area,
spatial distribution of individuals, and numerical abundance of species (Hair 1980).
Species diversity measures are among the most informative and commonly used
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measures of community structure (Peet 1974; Pielou 1975). Hair (1980) reviews the
assumptions involved in measuring species diversity in a terrestrial community and
discusses several diversity indices, including species counts, Simpson's Index,
Brillouin's Formula (H), and the Shannon-Weaver Function (H1).
Hair (1980) identifies two serious drawbacks to species counts. First, species counts
fail to account for relative abundances of species present; and second, they are
dependent on sample size. He recommends the use of "dual-concept" measures such
as Simpson's Index or the Shannon-Weaver Function because they are sensitive to
changes in both "species-richness" (number of different species present in a
community) and "evenness" components (changes in distribution of individuals
among species present). He also provides examples for calculation of several of these
indices and suggests that Simpson's Index is most appropriately used when the
relative dominance of a few key species is of interest.
When interpreting diversity indices it is important to remember that data from two
or more sites (such as a hazardous waste site and a selected reference site) could have
identical diversity index values but totally different species compositions (M'Closkey
1972). Values obtained from diversity indices are most useful when associated with
other demographic parameters (Hair 1980).
8.4.2.3 Capturing and Sampling Techniques
Terrestrial vertebrates can be captured or sampled by hand, with mechanical devices
such as traps, snares, and nets, or by use of immobilizing drugs. For some sampling
techniques discussed later in this section, a visual "capture" may be sufficient.
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Most mammals can be captured with a variety of commercially available traps. Leg-
hold steel traps with off-set and padded jaws and conebear steel traps have been
successfully used in capturing many species of carnivores and large rodents, such as
beaver and nutria (Day et al. 1980). There is risk of injury or death to the animal
with these traps, however, which may make their use unacceptable, especially when
animals from field surveys will be used in subsequent m situ assays.
Small commercial snap-traps such as Victors and Museum Specials are used in
sampling small mammal populations. Both can be successfully used to collect rats,
mice, small squirrels, and shrews. But because both types are kill traps, they may
cause damage to the cranium and internal organs making specimens unacceptable
for use in later laboratory studies.
Box-type live traps may represent the best tool for collecting mammals in ecological
assessments of hazardous waste sites. Box traps have been used successfully to
capture mammals as large as deer and as small as shrews (Day et al. 1980). Several
types are commercially available and many types can easily be constructed. The use
of box-type live traps is advantageous because animals are less likely to be injured,
they can be released for mark-recapture population studies, or they can be returned
to the laboratory for use as bioaccumulators and bioindicators.
Mammals below the size of large canids can be captured with a variety of commercial
live traps such as Havahart, Longworth, National, and Sherman. Sherman live traps
may be the most appropriate trap for use in sampling indigenous rodent and
insectivore populations at hazardous waste sites because they are inexpensive, easily
transported and set, and can be thoroughly cleaned when removed from a
contaminated site.
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Snares have been used to capture game species, canids, and ground squirrels. Their
use is reviewed by Day et al. (1980).
Conical and cylindrical pitfall traps can be used for small mammals (Nellis et al.
1974), especially burrowing insectivores such as shrews. Pitfalls may be used in
association with drift fences or they may be set inserted into the ground at the edge of
fallen logs or at the base of trees.
Choice of bait will depend on the species to be captured and the type of trap being
used. Small box traps such as Sherman traps can be baited with chicken scratch
grain or with a mixture of peanut butter and rolled oats. The peanut butter and
rolled oats mixture can also be used effectively to bait snap traps. Larger box traps
such as the Havahart may be baited with fruit such as apples to collect medium-sized
rodents, or with chicken entrails, sardines, or canned cat food to collect carnivores.
The use of injected drugs for the capture and control of mammals has changed
substantially during the past decades. Complex projectile syringes and sodium
bicarbonate pressurized blow guns have made accurate delivery of drugs to the
animal more certain. The number of different tranquilizing or anesthetizing drugs
available for use in capturing mammals has increased greatly in the last 20 years.
However, the appropriate quantity and type of drug to administer are known for very
few mammals. The use of a drug in capturing animals may confound data derived
from later in situ studies. Day et al. (1980) provide a thorough review of drugs, drug
delivery systems, and known appropriate doses for several mammalian species.
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Balgooyen (1977) reviewed capture methods for reptiles and amphibians. They
included box traps similar to those used for small mammals, pitfall traps set with
drift fences, pole nooses, snares, and large rubber bands. The most reliable means of
capturing reptiles and amphibians is walking through the study site and turning
over logs, rocks, and debris. Amphibians, water snakes, and turtles can be collected
by seining, and turtles can be collected with partially submerged cone traps.
If captured animals are going to be used in population studies involving multiple
recaptures or resightings, they must be marked in some easily identifiable manner.
It is important that the method of marking not cause irritation or injury to the
animal or hamper its normal activities. Marking methods can be permanent,
semipermanent, or temporary (Day etal. 1980). Freeze-branding, tattooing, and toe-
clipping are considered permanent marks. The attachment of ear tags or neck collars
are considered semipermanent marks, although they may stay attached for the life of
the animal. Temporary marks include dyes, fluorescent markers, and
chemoluminescent tags.
Reptiles and amphibians can be marked for use in population recapture studies by
freeze-branding and toe-clipping. Reptiles can be marked by scale painting or
clipping.
Nets are most commonly used to capture birds, but two types have been successfully
adapted for use in capturing mammals. Cannon and drop nets can be used to capture
large herds of antelope and deer (Hawkins et al. 1968; Ramsey 1968). Mist nets are
the best devices for capturing bats. They are most effective when placed across the
entry way to roost sites or over open standing water (Tuttle 1976).
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Wilbur (1967) provides several important points which must be considered when
capturing birds; the relatively greater mobility of birds compared to most other
terrestrial vertebrates is especially important in trap selection. Day et al. (1980)
describe a number of useful box and enclosure traps which are best for waterfowl and
ground foraging birds. Cannon nets can be used for capturing whole flocks of turkey,
waterfowl, and many ground foraging birds. Mist nets made of very fine black or
blonde nylon and ranging from 18 to 100 feet in length can be used for live capture of
almost any flying bird. Wind and other weather conditions can severely hamper
netting success, and capture rates will vary throughout the day. Mist netting is
especially useful for birds that are difficult to lure into baited traps (Day et al. 1980).
Special methods for marking birds are reviewed by Marion and Shamis (1977) and
Stonehouse (1977). Bird banding methods are standardized by the U.S. Fish and
Wildlife Service.
8.4.3 Methods Integration
General considerations in choosing from the variety of methods described in section
8.4.2 include: type of habitat present at the hazardous waste site; size of the site;
choice of species of interest; time and funding limitations; and possible integration
with other types of ecological assessment information.
The size and general habitat of the hazardous waste site in question may determine
the type and intensity of sampling methods and the species to be investigated.
Random quadrat sampling may be most appropriate if general populational
information is sought. If a single or a few key species are being investigated it may
be more appropriate to seek out suitable habitat within the hazardous waste site and
restrict collecting activities to those areas. Whenever possible, it is recommended
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that live-trapping be used as a capture method rather than kill-trapping because kill-
trapping may preclude the use of animals in subsequent longer-term population
assays and in in situ bioaccumulation and bioindicator tests.
Ideally, sampling should be conducted over several days and repeated seasonally.
Realistically, this may not be possible at hazardous waste sites; it is important to
remember, however, that inferences drawn from single sampling periods of a single
day or only a few days can be suspect (Davis and Winstead 1980; Downing 1980; Hair
1980).
Minimal information to be obtained from animals captured in ecological assessment
field surveys of terrestrial vertebrates should include the following:
• Taxonomic identification to species
• Sex
• Age. The accuracy of age determination may depend on whether or not the
animal is to be killed.
• Reproductive condition. Again, this may depend on whether or not animals
can be killed.
• Total body weight. If animals can be killed it will be beneficial to record the
following information: total body weight; wet weight of particular organs such
as liver, spleen and kidneys; measurement and weight of testes; presence of
embryos and placental scars; and other reproductive information (see section
8.4.2.2).
If animals are to be used for in situ analysis of bioaccumulation and exposure effects
it is imperative that they be handled in accordance with methods for each specific
assay (see Chapter 7). If possible, animals should be returned immediately to the
laboratory for processing in in situ assays. Because returning live animals to a
laboratory from a field capture site is not always feasible, certain types of tissues can
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be collected on site or at nearby "field laboratories." Most tissues for use in
bioaccumulation assays can be collected in the field, with wet organ weights
recorded, and tissues transported to the laboratory stored on dry ice or in liquid
nitrogen. All tissues should be collected immediately after death. Reproductive tract
tissues and other tissues that may be used in histological analyses can be removed in
the field and placed in 10% buffered formalin solution for transport to the laboratory.
Cytogenetic analysis of field-captured individuals requires that bone marrow be
collected and processed to the point of fixation immediately after the animal's death.
This process can be readily accomplished in a field laboratory (Baker et al. 1982) and
fixed cell suspensions can be transported to the laboratory in liquid nitrogen for final
analysis.
8.4.4 Examples
Following are examples from the scientific literature of field survey methods used to
assess the effects of environmental alterations on terrestrial vertebrate populations.
Most of these studies were not conducted at HWSs, nor do any of these studies use all
the methods described in this section. Examination of these studies, however, should
provide valuable information on the realistic expectations regarding the time-span
required and types of data available from field surveys. These examples may suggest
how field surveys of terrestrial vertebrates can be incorporated into the ecological
assessment process at HWSs and reinforce the precautions previously outlined in
Section 4 regarding statistical techniques applicable to HWSs. For each example,
treatment plots were compared to control plots, but only differences between these
nonreplicated plots could be tested statistically. Inferences beyond such comparisons
would require more information.
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In studies of small mammal populations of Mus musculus. Peromyscus maniculatus,
and Microtus ochrogaster before and after spraying with the organophosphate
insecticide, dimethoate, Barrett and Darnell (1967) found no evidence that the
insecticide caused direct mortality in any of the mammalian species examined. They
did find a shift in species composition from omnivores to herbivores. Mus musculus
numbers declined from 68 to 37% of the composition while Microtus ochrogaster
increased from 13 to 44% of the total composition. Peromyscus maniculatus numbers
were not significantly altered. The alteration in species composition may have been
related to the abrupt decline in number of insects rather than to a differential, direct
toxicological effect.
Decline in Microtus pennsylvanicus population size after application of 2,4-D
herbicide was attributed to changes in vegetation rather than to direct toxic effects
(Spencer and Barrett 1980). A year long study of three species (Peromyscus
polionotus, Sigmodon hispidus. and Mus musculus) in an enclosure treated with
sevin, a carbamate insecticide, indicated a long-term effect on population structure
changes (Pomeroy and Barrett 1975). Sigmodon reproduction was apparently
inhibited in the sprayed area compared to a control area, while Mus numbers
increased. Peromyscus did not do well in either plot. The authors suggested that the
increase in numbers of Mus was possibly due to decreased interaction with Sigmodon
(Pomeroy and Barrett 1975).
Examination of effects of endrin on unenclosed populations of Microtus
pennsylvanicus and Peromyscus maniculatus indicated significant declines in
numbers of Microtus immediately after application. Numbers rapidly recovered,
however, and no long term toxicological effect was demonstrated. The Peromyscus
population also was significantly reduced immediately after application and did not
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recover within two years, suggesting a differential population response of the two
species (Morris 1970). Enclosed populations of the same two species showed a similar
immediate response to endrin application. Young Microtus entering the population
after spraying showed a higher survival rate than counterparts in a control
population and population levels quickly grew beyond prespraying levels (Morris
1972). The herbicide Roundup had no apparent effect on survival, reproduction, or
growth of Peromyscus maniculatus in a one year study (Sullivan and Sullivan 1981).
Studies of Microtus pennsylvanicus populations inhabiting the Love Canal hazardous
waste site indicated that animals from the site had a population density of only about
one fourth of that for reference populations. Mean life expectancies were reduced by
half, and there was an apparent differential loss in old females resulting in a shift in
the sex ratio over a period of a year (Rowley et al. 1983). Orthene, an
organophosphate insecticide, had no apparent effect on population size, survival, or
recruitment over a two year period in Microtus pennsylvanicus compared to a control
population (Jett et al. 1986).
8.4.5 References
Anderson, D.R., J.L. Laake, B.R. Grain, and K.P. Burnham. 1976. Guidelines for
line transect sampling of biological populations. Utah Coop. Wildl. Res. Unit, Logan,
UT. 27 pp.
Baker, R.J., M.W. Haiduk, L.W. Robbins, A. Cadena, and B.F. Koop. 1982.
Chromosomal studies of South American bats and their systematic implications.
Spec. Publ. Pymatuning Lab. Ecol. 6:303-327.
Balgooyen, T.G. 1977. Collecting methods for amphibians and reptiles. U.S.D.I.
Bureau of Land Manage. Tech. Note T/N. 299. 12pp.
Barrett, G.W., and R.M. Darnell. 1967. Effects of dimethoate on small mammal
populations. Amer. Midi. Nat. 77:164-175.
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Davis, D.E., and R.L. Winstead. 1980. Estimating the numbers of wildlife
populations. Pages 221-245. In: S.D. Schemnitz, ed. Wildlife Management
Techniques Manual. Fourth Edition. The Wildlife Society, Washington, DC.
Day, G.I., S.D. Schemnitz, and R.D. Taber. 1980. Capturing and marking wild
animals. Pages 61-88. In: S.D. Schemnitz, ed. Wildlife Management Techniques
Manual. Fourth Edition. The Wildlife Society, Washington, DC.
Downing, R.L. 1980. Vital statistics of animal populations. Pages 247-267. In: S.D.
Schemnitz, ed., Wildlife Management Techniques Manual. Fourth Edition. The
Wildlife Society, Washington, DC.
Hair, J.D. 1980. Measurement of ecological diversity. Pages 269-275. In: S.D.
Schemnitz, ed. Wildlife Management Techniques Manual. Fourth Edition. The
Wildlife Society, Washington, DC.
Hawkins, R.D., L.D. Martoglio, and G.G. Montgomery. 1968. Cannon-netting deer.
J. Wildl. Manage. 32:191-195.
Jett, D.A., J.D. Nichols, and J.E. Hines. 1986. Effect of Orthene(R) on an unconfined
population of the meadow vole (Microtus pennsylvanicus). Can. J. Zool. 64:243-250.
Kirkpatrick, R.L. 1980. Physiological indices in wildlife management. Pages 99-
112. In: S.D. Schemnitz, ed. Wildlife Management Techniques Manual. Fourth
Edition. The Wildlife Society, Washington, DC.
Larson, J.S., and R.D. Taber. 1980. Criteria of sex and age. Pages 143-202. In: S.D.
Schemnitz, ed. Wildlife Management Techniques Manual. Fourth Edition. The
Wildlife Society, Washington, DC.
Marion, W.D., and J.D. Shamis. 1977. An annotated bibliography of bird marking
techniques. Bird-Banding. 48:42-61.
M'Closkey, R.T. 1972. Temporal changes in populations and species diversity in a
California rodent community. J. Mammal. 53:657-676.
Morris, R.D. 1970. The effects of endrin on Microtus and Peromyscus. I. Unenclosed
field populations. Can. J. Zool. 50:885-896.
Morris, R.D. 1972. The effects of endrin on Microtus and Peromyscus n. Enclosed
field populations. Can. J. Zool. 50:885-896.
Nellis, C.H., C.J. Terry, and R.D. Taber. 1974. A conical pitfall trap for small
mammals. Northwest Sci. 48:102-104.
Peet, R.K. 1974. The measurement of species diversity. Ann. Rev. Ecol. Syst.
5:285-307.
Pielou, E. 1975. Ecological diversity. John Wiley and Sons, New York, NY. 165 pp.
Pomeroy, S.E., and G.W. Barrett. 1975. Dynamics of enclosed small mammal
populations in relation to an experimental pesticide application. Amer. Midi. Nat.
93:91-106
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Ramsey, C.W. 1968. Drop-net deer trap. J.Wildl. Manage. 32:187-190.
Rowley, M.H., JJ. Christian, D.K. Basu, M.A. Pawlikowski, and C.J. Paigen. 1983.
Use of small mammals (voles) to assess a hazardous waste site at Love Canal,
Niagara Falls, New York. Arch. Environ. Contam. Toxicol. 12:383-397.
Seber, G.A.F. 1973. The estimation of animal abundance and related parameters.
Hofner Press, New York, NY. 506pp.
Spencer, S.R., and G.W. Barrett. 1980. Meadow vole (Microtus pennsylvanicus)
population response to vegetational changes resulting from 2,4-D application. Amer.
Midi. Nat. 103-32-46.
Stonehouse, B., ed. 1977. Animal Marking. Univ. Park Press, Baltimore, MD.
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Sullivan, T.P., and D.S. Sullivan. 1981. Responses of a deer mouse population to a
forest herbicide application: Reproduction, growth, and survival. Can. J. Zool.
59:1148-1154.
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Phyllostomatidae. Parti. Spec. Publ. Mus. Texas Tech Univ. 10:71-88.
Wilbur, S.R. 1967. Live-trapping North American upland game birds. U.S.D.I. Fish
and Wildlife Serv. Spec. Sci. Rep., Wildl. No. 106. 37 pp.
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8.5 TERRESTRIAL INVERTEBRATE SURVEYS -- Jerry J. Bromenshenk
8.5.1 Introduction
Approximately 95% of all species of animals are invertebrates. Invertebrates play
crucial roles in community and ecosystem functions such as decomposition, grazing,
predation, and pollination. Because invertebrates are numerous in species and
individuals per species, they are relatively easy to obtain and study, and samples
usually can be collected without depleting populations. Short life cycles and small
size permit simple sampling techniques. In fresh-water systems, invertebrate
indicator species have been utilized for many decades to assess impact to ecological
communities; more recently, structural responses of aquatic invertebrate
communities have become a principal form of water quality assessment (see sections
6.2 and 8.2).
Ecological endpoints measured by terrestrial invertebrate surveys range from
biochemical to ecosystem-level responses. From an ecotoxicological perspective, the
question is whether these measures can discriminate changes due to contaminants at
the site from those due to natural variability. Although some terrestrial invertebrate
survey methods have great potential utility in assessing adverse impacts at
hazardous waste sites and as a benchmark for determining the success of remedial
actions, none of these approaches has been universally accepted, and there are few
standard methods. Nonetheless, these methods warrant consideration since the
invertebrate systems may be some of the more sensitive and crucial for evaluating
ecological effects associated with hazardous wastes.
8.5.2 Invertebrate Survey Methods
The methods described in this section complement the acute laboratory and in situ
toxicity tests described in section 6.2 of this document and the bioaccumulation and
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biomarker tests presented in Chapter 7. Since it is often desirable to integrate field
data acquisition with laboratory testing and analysis to provide a more refined and
comprehensive ecological assessment, invertebrate samples can be used, in many
cases, to accomplish this with a minimum of extra cost. For example, if properly
preserved, specimens collected in the field provide not only information about
populations and communities, but also measures of bioaccumulation, and specimens
for histological, genetic, and biomarker studies. Furthermore, these investigations
can be carried out retrospectively, as needed.
For the most part, terrestrial invertebrate survey methods are relatively untried at
hazardous waste sites. However, data bases and established methods sometimes
exist from other regulatory programs, such as the pesticide toxicity assays required
for nontarget insects by the Federal Insecticide, Fungicide, and Rodenticide Act
(FIFRA). The Pesticide Assessment Guidelines for FIFRA contain standards for
conducting acceptable tests, guidance on evaluation and reporting of data, definition
of terms, and further guidance for hazard evaluations for nontarget insects (U.S. EPA
1982). Additional data bases are available from hazard assessments such as those
conducted as part of the management and surveillance of nuclear and chemical
wastes at Department of Energy and military facilities.
8.5.2.1 Endpoints for Class I and Class II Terrestrial Invertebrate Survey
Methods
Class I methods for surveys of invertebrate populations are discussed in subsection
8.5.2.2 below; Class II methods are discussed in 8.5.2.3. These methods emphasize
insects and other non-microscopic invertebrates of terrestrial systems. Potential
measurable ecological endpoints include, but are not limited to the following: (1)
population size and estimates of related factors such as mortality, natality, and
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dispersal; (2) species diversity; (3) alterations of histopathological and morphological
structures; (4) behavioral responses; (5) genetic alterations; (6) biomarkers such as
inhibition of acetylcholinesterase; and (7) bioaccumulation endpoints. Case history
and research examples can be provided for each of the above; but, for the most part,
measurement protocols remain unstandardized, have not been widely applied to
hazardous waste sites, or have been applied mainly in the laboratory and not in situ.
8.5.2.2 Class I Methods for Surveys of Invertebrate Populations
Population measurements of terrestrial invertebrates in the field probably are the
most useful for assessing contaminant exposures and effects. With larger animals,
populations must have small ranges (or the waste site must be very large) to avoid
obscuring effects as a result of movements onto and off of the site. However, for many
invertebrate populations, even the smallest waste site is "large" in comparison to the
size and movements of the organisms themselves.
In addition, because of their small size, it is possible (and probably desirable) to
employ bioassessment procedures that can be accomplished by bringing waste
materials into the laboratory and exposing invertebrate populations under controlled
conditions, or by examining populations of these organisms under controlled
conditions m situ (cages), or by using free living in situ organisms. For example,
Drosophila sex-linked recessive lethal and reciprocal translocations tests have long
been accepted as indicators of the potential for chemicals to cause heritable gene
mutations and chromosome aberrations in animal germ cells (Waterland 1979). A
standardized Drosophila protocol has been used by the National Institute of
Environmental Health Sciences to test over 200 hazardous chemicals. However,
application of this test to evaluations of hazardous waste sites has yet to be
demonstrated.
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The Class I methods for invertebrate species involve sampling and contaminant
testing of honey bees or harvester ants. Approaches for the use of these invertebrate
species for hazardous waste site assessment are discussed in the following sections.
8.5.2.2.1 Honey Bee Body Burdens and Bioaccutnulation of Contaminants.
Honey bees are important as pollinators and as producers of honey, pollen, and wax.
It is estimated that approximately one-third of the food consumed in the United
States is directly or indirectly dependent on pollination by bees (McGregor 1976), a
service valued at 8 to 40 billion dollars per year (Mayer 1983). In addition, they are
the most studied species of invertebrate in the world. A substantial data base exists
concerning bees and toxic chemicals since FIFRA requires pesticide testing for
toxicity to nontarget insects, namely honey bees.
Although bees may at first appear to be an unlikely and difficult-to-manage test
organism, miniature or disposable hives and the technical support readily available
from state and federal agencies, bee research laboratories, and beekeepers
(Bromenshenk and Preston 1986), make bee colonies an inexpensive (as low as $25
per unit) and practically self-sustaining test system. In addition, although bees may
seem most appropriate for rural sites, many cities such as New York, Seattle, and
San Francisco allow beekeeping within city limits and have many urban beekeepers.
The honey bee colony presents an opportunity to conduct multi-dimensional testing
(from the biochemical to the population level of organization) and to make inferences
to the community and ecosystem level through the pollination syndrome. Once a
colony is placed on site, the unit can be easily sampled and observed to monitor
exposures via bioaccumulation, as well as to determine lethal effects such as
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mortality, sublethal effects such as inhibition of acetylcholinesterase by
organophophates, and behavioral effects such as alterations in foraging and flight
activity. In addition, toxicity testing can be conducted in the laboratory. Thus, the
sample unit can yield a wide array of information.
In small and large scale investigations conducted in Europe and the United States
(Wallwork-Barber et al. 1982; Bromenshenk 1988) contaminant residues in or on
bees, pollen, honey, wax, and propolis have been used to evaluate the dispersion of
toxics. Bees are multi-media samplers, and body burdens have been shown to
correlate well with levels in environmental media (Bromenshenk et al. 1985,1988a-
c). Statistical techniques such as kriging have yielded two- and three-dimensional
maps of pollutant distribution, including isopol confidence limits (Bromenshenk et al.
1985). Honey bees have been used to follow spatial distributions of numerous heavy
metals and radionuclides on five federal reservations (Hanford, Idaho National
Engineering Laboratory, Los Alamos, Oak Ridge, and Savannah River) and of heavy
metals, particularly arsenic, cadmium, and lead, at five EPA Superfund sites in
Montana and Washington. Although contaminants can be examined in honey, wax,
pollen, or bees, the recommended sample is the bee itself, unless the primary data
requirement is the potential to transfer toxics to humans via pollen or honey. In
general, contaminant levels are highest in the forager bee, and these are the easiest
samples to obtain. The recommended procedure, including an example of application
and data presentation, is described in Bromenshenk et al. (1985).
Bees provide a means of examining a site in the context of the surrounding region,
and are best suited for examinations of relatively large sites, since their flight range
is 1.6 to 3 km. For small sites where air-borne contaminants are of concern, it is
feasible to constrain bees to flight cages.
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Colonies of bees deployed at the site may be full-size or miniature (known as nucs by
beekeepers) and can be readily obtained from local beekeepers and from suppliers of
bees located in most southern states and California. Information about bees is
readily obtained; all U.S. states have apicultural inspectors, generally associated
with state departments of agriculture or the Agricultural Soils Conservation Service.
Other sources of information and assistance are the USDA ARS bee research
laboratories, particularly the Carl Hayden Bee Research Laboratory, Tucson, AZ,
and the Beneficial Insects Laboratory, Beltsville, MD.
Since free-flying bees aggressively sample areas of more than 1.6 km in diameter,
precise location of the sampling unit (hive) is not critical. The hive(s) should be
placed near the center of the area to be sampled. Uptake of most chemical
contaminants by foraging bees takes less than 24 hours. However, hives should be
sampled before being placed on site to establish baseline values. Colonies moved
from areas of high exposure to chemical contaminants to an area of lower exposure
may take several weeks to eliminate contaminants from their colonies.
Sampling time varies from 5 to 20 minutes per hive when bees are flying. Sampling
on sunny days is recommended because flight activity is curtailed on windy, rainy, or
overcast days.
Laboratory requirements include analytical capability for determining the chemicals
of interest at ppm, ppb, and (for some organics) ppt in biological tissues. In general,
sample processing and analysis methods follow standard EPA protocols for other
biological specimens.
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Test outputs should be expressed as parts per million in dried bee tissue for data
comparability. To date, bees have been found to be effective bioaccumulators of
heavy metals, other inorganic elements such as fluoride (which they bioconcentrate),
radionuclides, organic pesticides, and PCB's (Anderson and Wojtas 1986;
Bromenshenk et al. 1985; Wallwork-Barber et al. 1982). The extent to which they
can be used to examine non-pesticide organics such as dioxin and volatile organics is
unknown, although research concerning these chemicals is ongoing.
Bees are capable of detecting extremely small concentrations of biologically available
contaminants, often equalling or surpassing the capability of more traditional
instrumentation. As few as 25 bees have been found to be representative of pollutant
concentrations in a colony, although samples of a minimum of 200 bees are
recommended. In addition, samples should be taken from a minimum of two to three
hives at any location. Sample integrity, including sample custody, is essential.
Sample holding times are not critical for heavy metals, but should be kept as short as
possible for organics (not more than six months). Laboratory quality assurance also
is essential. Although no standard reference material (SRM) is currently available
for bees or any other terrestrial invertebrate tissues, the National Bureau of
Standards (NBS) can supply several animal tissues -- oyster tissue (SRM 1566a),
bovine liver (SRM 1577a), and albacore tuna (RM 50) as well as a variety of
vegetation SRMs. In addition, a sample of cryogenically fractured bee tissue is
archived in the NBS specimen bank (contact Dr. Stephan A. Wise for information).
Toxicity testing of pesticides is required for honey bees. Test protocol guidelines are
published in U.S. EPA (1982).
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These protocols include an acute contact LD50 laboratory test, a field-based foliar
residue test, as well as recommendations for field studies. Although these
regulations focus on testing for purposes of pesticide registration and labels affecting
the use of pesticides, the test methods may be applicable to hazardous waste site
toxicity assessments, and data bases exist for several hundred chemicals.
In addition to the acute contact LD50 laboratory test for pesticide, Wildlife
International suggests a topical test similar to that of Smirle et al. (1984), who
developed a topical bioassay for evaluating sublethal effects of toxins. This test has
not been standardized or employed using materials from hazardous waste sites, but
deserves mention as a potential method for examining responses other than acute
toxicity.
There are no established protocols for field assessments of toxicity, although
guidelines are provided. Likely test methods that may be incorporated into data
acquisition objectives include in sjltu toxicity assessments of adult bee mortality by
classical methods such as Todd dead bee hive entrance traps (Atkins et al. 1970),
estimates of colony population size along pollutant exposure gradients (Bromenshenk
et al. 1988a), and brood survival (Thomas et al. 1984; Bromenshenk et al. 1985).
8.5.2.2.2 Harvester Ant Toxicity Bioassay and Body Burdens. These ants are
common in all arid and semi-arid habitats of the United States. They construct
conspicuous nests and represent an organism that lives in intimate contact with the
soil. Ongoing work near waste sites at the Idaho National Engineering Laboratory
indicates that body burdens of these ants can be used to evaluate the spatial
distribution of contaminants in soils, the potential for carrying buried wastes to the
surface, and leachates in ground water (Paul Blom, pers. comm.). In addition,
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harvester ants exposed in petri dishes containing soil amended with toxicants (Gano
et al. 1985) and irradiated with cesium-137 gamma radiation (Gano 1981) were
sensitive to certain chemicals and consistently ranked these chemicals in order of
greatest toxicity to ants. Thus, ant body burdens and laboratory-based toxicity
testing (see also section 6.3.2) are test methods that may be incorporated into
ecological assessments and may be applicable to site-specific needs.
8.5.2.3 Class II Methods for Surveys of Invertebrate Populations
Various direct and derived measures of community structure, such as species
richness and relative abundance, indicator species, and numerical indices of
taxonomic and abundance data, have long been used to study the effects of pollutants
on aquatic systems. In terrestrial systems, while interactions of air pollutants with
plants and insects are well documented (especially for insect pests affecting forests
and, to a lesser degree, agricultural crops), direct measures of invertebrate
community structure are not usually suited to short term assessment of hazardous
waste sites. Although relatively standardized insect and disease survey methods are
available (Heagle 1973; Hay 1977; Alstead et al. 1982), the approaches are best
suited for large-scale or long-term studies, since they involve examination of
temporal and spatial patterns in large data bases. Diagnostic characteristics that are
employed include: (1) pattern of insect damage relative to a known source, (2)
deviations from "normal" outbreak patterns, (3) appearance of insects in outbreak
levels that rarely reach epidemic levels, (4) documentation of change through time
relative to the source, (5) establishment of ecological or physiological basis for the
relationship, and (6) correlative statistical approaches between levels of exposure and
degree of infestation or damage. Only rarely will this type of information be
obtainable for hazardous waste site assessment.
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In addition to the air pollution-plant-insect interactions, toxic chemicals in soil or
litter frequently have been shown to have adverse effects on soil- and litter-dwelling
arthropods. The sampling methods are relatively well established, usually involving
sampling of a unit of soil or litter or by the placement of litter bags on the site,
followed by extraction of the invertebrates using Berlese/Tullgren funnels or
floatation methods (Southwood 1975; French 1970,1971). A practical problem often
arises concerning the safety of personnel attempting to sample and handle
potentially highly contaminated soils and litter at a hazardous waste site. In most
cases, laboratory assays of soil preparations using indicator species and tests such as
the Eisenia foetida (earthworm) 14-day acute toxicity bioassay (section 6.3.2) or
various microbial bioassays (section 6.4.2) reduce risks to personnel and, as such, are
used as surrogate estimators of population and community responses in place of
direct field surveys.
With respect to other community assessment endpoints employing terrestrial
invertebrates, one-time or limited field surveys of community structure and function
are unlikely to be of much use. For example, there is no terrestrial counterpart to the
100-year data base that exists for aquatic invertebrate communities. For the most
part, it is difficult, if not impossible, to distinguish patterns of community structure
and function that may reflect pollutant-induced perturbations from those of natural
variability, which generally is high. If the community has changed, it would be
revealed in terms of invertebrate species that have appeared, disappeared, or
changed in relative abundance. But this is impossible to address in the absence of
information about the community structure before contamination of the site. At best,
all that can be accomplished is a measure of the community as it exists and of
changes during and after clean up. Since comprehensive assessments of invertebrate
communities such as macro- or micro-arthropods are enormously labor intensive and
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time-consuming and require professional assistance in the design of the sampling,
taxonomic identifications of specimens, and data interpretation, this type of survey
does not appear to be cost-effective and generally is not recommended.
Surveys of community structure are recommended for specific purposes. These need
not be comprehensive and may consist of little more than a site visit by an
entomologist or invertebrate specialist and minimal sampling, using methods such as
visual observations, flushing, and collecting with a sweep net or similar device. The
primary purpose is to determine the appropriateness of proceeding with on-site
measurements of invertebrate population assemblages. For example, the site may be
conspicuously lacking in terms of species diversity and abundance or lacking species
common to the region. In addition, the site may be a potential habitat for endangered
or threatened species, e.g., several species of butterflies, a moth, some beetles, or a
tarantula (50 CFR Chapter I: 17.1, Subpart B and 23.23, Subpart C). Occasionally,
the site may pose a threat to commercially valuable insects, such as honey bees, that
may be located on or near the site. If more extensive or intensive sampling is
warranted, guidelines are available (Southwood 1975; French 1970, 1971).
Professional assistance should be obtained for the design, conduct, and interpretation
of surveys of terrestrial invertebrate communities. Data acquisition requirements
are site specific, and specific methods cannot be recommended within the scope of this
document.
8.5.3 Methods Integration
The recommended invertebrate surveys emphasize a tiered approach and combined
measures of exposure and effects. A necessary first step in a site assessment is an
overview of the site itself and identification of the invertebrate population
assemblages present and likely to be affected. This phase must also consider the
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ecological context of the site, the extent of the impacted area, and other ecological
features that warrant more detailed analysis. In some cases, an invertebrate
community analysis may be appropriate, but in most cases a more incisive approach
is to sample or to test named species. This has the advantage of allowing the
formulation and statement of clear objectives that are translatable into a practical
monitoring program. The emphasis on a specific test organism may seem to be a
questionable strategy, but one population generally has significance to others and, in
a practical sense, we are often most concerned about a limited number of species that
are ecologically or economically important, valued for aesthetic reasons, or
endangered or threatened. Thus, the use of in situ or laboratory tests of acute toxicity
of an organism such as an earthworm, which has an easily recognized and defined
role in ecosystems, may be an appropriate choice for a site where the soils are known
or thought to be highly contaminated. In addition, this type of test may prove to be
an extremely valuable benchmark by which to assess the effectiveness of remedial
actions.
However, a change in a measured ecological endpoint, even a statistically significant
change, does not necessarily provide direct information about pollution effects.
Often, survey methods provide, at best, base-line or benchmark information and
some estimate of temporal and spatial variation.
A better approach is to get correlative data for the chosen measure of biological
performance that correspond to changes in measured concentrations of contaminants,
not only in environmental media, but in the target organisms themselves. Toxic
chemicals in air, soil, or water are not necessarily hazardous unless biologically
available. Questions of this nature are best addressed by organisms such as the
honey bee that can be employed for assessments of exposure through bioaccumulation
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and for assessments of effects through tests such as acute mortality and sublethal
effects. Note also that the use of an organism that can readily be utilized in the
laboratory and in situ has advantages in terms of versatility and for "calibration" of
field/laboratory endpoints. In addition, the ability to examine one or more endpoints
at differing levels of biological organization using the same organism has cost and
data interpretation benefits.
8.5.4 Case Studies of Invertebrate Surveys
Selected examples have been drawn from the literature to illustrate the application
of invertebrate surveys in field evaluations of hazardous waste sites. None of the
approaches is suitable for all hazardous waste sites, but some may have potential
benefits for site-specific characterizations; nor are these examples to be taken as
indicative of the only invertebrate surveys that may be employed. Other potentially
useful techniques are available.
8.5.4.1 Commencement Bay (Bromenshenk et al. 1985)
To show that honey bees are effective biological monitors of environmental
contaminants over large areas, beekeepers of Puget Sound, WA, collected pollen and
bees for chemical analysis. From these data, kriging maps of arsenic, cadmium, and
fluoride were generated. Results, based on actual concentrations of contaminants in
bee tissues, show that the greatest concentrations of contaminants occur close to
Commencement Bay and that honey bees are effective as large-scale monitors.
In a companion study (Bromenshenk et al. 1988a), 50 mini-colonies of bees were
placed along an arsenic and cadmium exposure gradient at five sites on Vashon
Island in Commencement Bay. After 40 days of exposure, the mini-colonies displayed
statistically significant site differences for numbers of bees and mean biomass
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(Pj<_.01) and arsenic and cadmium content (P_<^.001). Bee populations were
approximately 40% lower at the highest exposure site than at the sites of lowest
exposure. Population size displayed a statistically significant (Pf^.005) negative
correlation with arsenic content of bees.
8.5.4.2. Rocky Mountain Arsenal (Thomas et al. 1984)
An overall goal of the 1982 studies at the U.S. Army arsenal in Commerce City, CO
(RMA) was to demonstrate that field tests using honey bees could be useful in
detecting likely areas of chemical pollution. Honey bees at two waste areas, Derby
Lake and Basin F, exhibited statistically higher (P<^.01) brood mortality compared to
hives at a control site during July and early August of 1983 (72% and 85% compared
to 21%). Based on no evidence of food shortages or brood diseases, increased levels of
brood mortality appeared to have resulted from contaminants brought by foraging
bees to the hives.
The authors concluded that bee colonies placed near other contaminant sources would
result in detection of increased brood mortality in comparison with colonies located
remote from the such areas. However, personnel experienced in apiculture should
conduct the tests since the occurrence of disease or natural changes in brood
production patterns could be incorrectly interpreted as a response to toxic materials.
These variables could be evaluated by analysis of covariance techniques.
8.5.5 References
Alstead, D.N., G.F. Edmonds, Jr., and L.H. Weinstein. 1982. Effects of air pollutants
on insect populations. Annual Review of Entomology. 27:369-384.
Anderson, J.F. and M.A. Wojtas. 1986. Honey bees (Hymenoptera: Apidae)
contaminated with pesticides and polychlorinated biphenyls. J. Econ. Entomol.
79:1200-1205.
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Atkins, E.L., Jr., L.D. Anderson, and F.E. Todd. 1970. Honey bee field research
aided by Todd dead bee hive entrance trap. Calif. Agric. 24:12-13.
Bromenshenk, J.J. 1988. Regional monitoring of pollutants with honey bees. Pages
156-170. In: Wise, Zeisler, Goldstein, eds. Progress in Environmental Specimen
Banking. U.S. Department of Commerce, National Bureau of Standards Special
Publication 740.
Bromenshenk, J.J., and E.M. Preston. 1986. Public participation in environmental
monitoring: A means of attaining network capability. Pages 35-47. In:
Environmental Monitoring and Assessment, Vol. 6.
Bromenshenk, J.J., S.R. Carlson, J.C. Simpson, J.M. Thomas. 1985. Pollution
monitoring in puget sound with honey bees. Science. 227:632-634.
Bromenshenk, J.J, J.L. Gudatis, S.R. Carlson, and J.M. Thomas. 1988a. Sampling
honey bee mini-hives for field evaluations of pollutant hazards. (Submitted to
Apidologia, in review).
Bromenshenk, J.J., J.L. Gudatis, and R.C. Cronn. 1988b. Post-closure assessment of
a hazardous waste site region with honey bees. (In Review).
Bromenshenk, J.J., J.L. Gudatis, and R.C. Cronn. 1988c. Heavy metal kinetics in
honey bees. (In Review).
French, N.R. 1970. Field Data Collection Procedures for the Comprehensive
Network 1970 Season. International Biological Program (IBP) Grassland Biome
Technical Report No. 35. 37pp.
French, N.R. 1971. Basic Field Data Collection Procedures for the Brassland Biome
1971 Season. International Biological Program (IBP) Grassland Biome Technical
Report No. 85. 87pp.
Gano, K.A., D.W. Carlile, and L.E. Rogers. 1985. A Harvester Ant Bioassay for
Assessing Hazardous Chemical Waste Sites. PNL-5434, UN-11. Pacific Northwest
Laboratory, Richland, WA.
Gano, K.A. 1981. Mortality of the harvester ant (Pogonomyrmex owyheei) after
exposure to Csl37 gamma radiation. Environ. Entomol. 10:39 44.
Heagle, A.S. 1973. Interactions between air pollutants and plant parasites. Annual
Review of Phytopathology. 11:365-388.
Hay, C.J. 1977. Bibliography on Arthropoda and Air Pollution. General Technical
Report NE-34, U.S. Department of Agriculture, Forest Service.
Mayer, D.F. 1983. Man's best friend: The honeybee. In: Proceedings of the Western
Apicultural Society, Sixth Annual Convention.
McGregor, S.E. 1976. Insect pollination of cultivated crop plants. Agriculture
Handbook No. 46, U.S. Department of Agriculture, Agriculture Research Service.
411pp.
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Southwood, T.R.E. 1975. Ecological Methods with Particular Reference to the Study
of Insect Populations. 1975 edition. Methuen and Co. LTD, London. 391pp.
Smirle, M.J., M.L. Winston, and K.L. Woodward. 1984. Development of a sensitive
bioassay for evaluating sublethal pesticide effects on the honey bee (Hymenoptera:
Apidae). J. Econ. Entomol. 77:63-67.
Thomas, J.M., J.R. Skalski, L.L. Eberhardt, and M.A. Simmons. 1984. Field
sampling for monitoring, migration, and defining the areal extent of chemical
contamination. In: Management of Uncontrolled Hazardous Waste Site, Hazardous
Material Control Research Institute, Silver Spring, MD.
U.S. Environmental Protection Agency. 1982. Pesticide assessment guidelines,
subdivision L, hazard evaluation: Non-target insects. EPA/540/9-82/019. Office of
Pesticides and Toxic Substances, U.S. Environmental Protection Agency,
Washington, DC.
Waterland, R.L. 1979. Terrestrial ecology protocols for environmental assessment
programs, workshop proceedings. EPA/600/2-79/122. Corvallis Environmental
Research Laboratory, U.S. Environmental Protection Agency, Corvallis, OR.
Wallwork-Barber, M.K., R.W. Ferenbaugh, and E.S. Gladney. 1982. The use of
honey bees as monitors of environmental pollution. Am. Bee J. 122:770-772.
8-88
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CHAPTER 9
DATA INTERPRETATION
By
Donald L. Stevens, Jr., Eastern Oregon State College, La Grande, OR.
Greg Linder, NSI Technology Services Corporation,
Corvallis Environmental Research Laboratory, Corvallis, OR.
William Warren-Hicks, Kilkelly Environmental Associates, Raleigh, NC.
9.1 CAUSALITY
The causal link between an adverse ecological effect and a hazardous waste site
(HWS) can be established by demonstrating a pattern of effects between ecological,
toxicological, and chemical data. For example, the toxicity of a soil sample collected
from the site can be compared to ecological survey data for terrestrial plants,
invertebrates, and/or vertebrates and also compared to chemical concentrations in
the soil samples. A correlation between the survey data and the toxicity and
chemistry data is an indication that the ecological effects are caused by something
related to the hazardous wastes. If a source of contamination can be localized, plots of
toxicity and ecological data versus distance can be examined for patterns.
Alternatively, isopleths of toxicity and ecological data can be prepared and
evaluated. For example, a pattern of toxicity that corresponds to physical or
hydrological conditions is strong indication of causality. The strength of the
correspondence can be evaluated with several statistical techniques, such as
regression, correlation, or nonparametric methods. If aquatic effects in flowing water
are expected, toxicity at sites upstream from the HWS can be compared to toxicity at
the site and at varying distances downstream. The key to establishing causality is to
relate the observed differences and patterns to a reasonable physical model, and to
show that the pattern is consistent across a number of endpoints. Ultimately, a
9-1
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preponderance of evidence is obtained demonstrating a causal link (or conversely,
lack of one) between ecological, toxicological and chemical data and the HWS.
Both parametric (Snedecor and Cochran 1967) and nonparametric (Hollander and
Wolfe 1973) statistical techniques can be used to assess causality. Candidate
techniques include correlation, multiple regression, analysis of variance, their
nonparametric equivalents, and comparisons of cumulative density functions. A
competent statistician should always be consulted before an attempt is made to
implement any of these methods.
To illustrate the importance of competent statistical input to the HWS assessment
process, consider a hypothetical site where soil was sampled for laboratory toxicity
testing, and where measures of important chemical species, measures of vegetation
abundance, and other observations of biological activity could be recorded. It is
reasonable to regress the LC50 values generated from the laboratory toxicity testing
on several chemical species concentrations, particularly if one or more of the chemical
species is known to have originated at the HWS. The presence of a significant
regression of LC50 on chemical concentration would not directly indicate that the
chemical species was responsible for the resultant toxicity. However, it is a direct
indication that the source of the toxicity is linked to the measured chemical, and an
indirect indication that the toxicity was originating from the HWS.
If the origin of toxicity can be localized, the relationship between ecological and
toxicological variables and distance from the origin can be determined. This is
particularly useful if there is water flowing through the site. For example, a plot of
toxicity and ecological effects data against downstream distance is presented in
Figure 9-1. These data show a significant relationship between toxicity and
9-2
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ecological effects. Similarly, recent work (Birge, etal 1989) has illustrated the role of
integrated lexicological and ecological studies in assessments of complex effluents in
aquatic systems,
100 r-
80 -
60 -
40 -
20 -
e>
Toxicity data •
Community datao
345
Stream Stations
Figure 9-1. A comparison of percent toxicity and percent reduction of the
taxa. (Norberg-King and Mount 1986)
9.2 UNCERTAINTY
Presentation of information generated from an ecological assessment of a hazardous
waste site should always include an assessment of the uncertainty inherent in the
data. Uncertainty is a state or condition of incomplete or unreliable knowledge. It is
ubiquitous in environmental assessments and is present in most scientific endeavors.
9-3
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Uncertainty also exists in all scientific projections of future conditions such as an
environmental risk analysis.
Uncertainty in environmental assessment is due in part to natural variability,
sampling error, measurement error, and estimation error. Sampling error
uncertainty results merely from the fact that samples cannot be collected over all
geographical space throughout all time. Measurement uncertainty may result from
sample processing or analysis in the field or laboratory. These uncertainties may
propagate themselves in the estimation of summary statistics, such as the mean or
variance, or the estimation of parameters such as a coefficient in a regression
equation. Uncertainty, therefore, presents a problem and a challenge for the
interpretation of data generated at an HWS.
Uncertainty relates to reliability or precision, and all three terms may be used to
describe the value of information. Uncertain information, uncertain statistics, and
uncertain predictions are less valuable for decision making than are these same
quantities when measured with less error. Therefore, estimates of uncertainty allow
the decision maker to properly weigh information for which uncertainty has been
assessed.
Estimating uncertainty in an ecological assessment can be a complex task. Methods
for quantifying uncertainty are somewhat specific to the type of assessment, but
include estimates of sample variance, confidence intervals, prediction intervals,
cumulative density functions, descriptive statistics such as the inter-quartile range,
and many types of graphical display techniques such as box-and-whisker plots.
Whenever possible, ecological assessment data should be presented along with the
appropriate estimates of uncertainty. Hypothesis testing can be significantly
9-4
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confounded under many types of uncertainty (see Chapter 4); therefore, exploratory
techniques and graphical presentation techniques may be preferred for inferring the
nature of the relationships inherent in the data.
9.3 ANALYSIS AND DISPLAY OF SPATIAL DATA
Much of the information collected during a field survey of an HWS will be associated
with a particular spatial location, and the spatial relationship of the points will be
important in interpreting the data. Maps have been used extensively to study and
display spatial patterns. Many cartographic techniques are available for displaying
spatially varying quantitative data. For example, if the variable being displayed is
spatially continuous, it can be conceptualized as a surface in three dimensions. The
surface can be displayed as contour lines, isopleths, or as perspective plots.
Alternatively, if the variable is spatially discontinuous, the magnitude of an
observation at a point can be represented by symbol size or color.
9.3.1 Point Methods
Point displays are useful for discrete spatial variables. They also give an accurate
representation of the location and magnitude of observations, thus providing
information not available in surface displays.
9.3.1.1 Scatter Plots
Graphic techniques are an invaluable method of exploring data for relationships
among several variables. Simple x-y scatter plots are one of the most effective means
to detect and display relationships between two variables (Tufte 1983). Plots have an
advantage over numerical techniques such as correlation or regression in that non-
linear relationships and outlier data points with high leverage can become obvious.
Cleveland and McGill (1984) discuss a number of techniques that can be used to
9-5
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enhance the information content of scatter plots. For example, a frequent problem is
overplotting data, so that density of data points may be visually misjudged.
Cleveland and McGill (1984) solve the overlap problem by dividing the plotting
region into square subregions, counting the number of points in each subregion, and
portraying the count with a "sunflower". The number of points in the subregion
corresponds to the number of leaves of the sunflower: a single dot is a count of 1, a dot
with a vertical line segment is count of 2, and additional line segments are added for
each additional point thereafter (see Figure 9-2). Carr et al. (1986) use a similar
technique, except the size of hexagonal bins is used to indicate count (see Figure 9-3).
o -
A A A.
• ( * i • • (
• ( A « « * * I
. I . A * # * * t
JL | . | * + Jk **
4. * J JL + » I * A •
.A. . A
o * « e •
x
Figure 9-2. Sunflower technique for displaying clusters of data points.
Scatter plots can be used to examine multivariate relationships through the use of
scatter plot matrices (Chambers et al. 1983; Cleveland McGill 1984; Carr and
Nicholsen 1984). In these displays, a series of bivariate scatter plots are arranged in
9-6
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• *
c
V
•*->
u
o
•0
0 1 2
Logten Sodium
Figure 9-3. Hexagonal binning technique for displaying clusters of data points.
(Garret al. 1986)
a matrix, with all plots in the same row having the same y axis, and all plots in the
same column having the same x-axis (see Figure 9-4). Often, a smooth curve is drawn
through the data to aid in interpretation. The curve can be drawn by eye, or robust
regression can be used to obtain a smooth curve (Cleveland 1979).
9.3.1.2 Glyph Plots
In the most general sense, a "glyph plot" is used to convey information by changing
the appearance of a pictograph. Glyphs can be used in a coordinate-free manner to
provide visual representations of multivariate data. For example, Chernoff (1973)
used stylized human faces to depict associations between multivariate observations,
and to identify groups with similar multivariate relationships. A "glyph plot" is
much like a standard x-y scatter plot, except that information is conveyed not only by
the x-y coordinates, but also by the appearance of the symbol. In a simple case, for
example, the x-y axes might be map coordinates, and the size of the plotting symbol
9-7
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o
o
* L-!.
*?£*•..
ig
* N
»8
in O
O
cc
£.
o
rw
e.
en
I 2
* r>
0 SC 100 0 100 200 300 60 60
OZONE SOLAR RADIATION
S 10 IS 20
WIND SPEED
Figure 9-4. Ozone and Meteorology data. The arrangement of the scatterplots
of the four variables is called a scatterplot matrix. Each panel has a middle
smoothing of y given x and of x given y, using lowess with f=|. The
smoothings highlight the nonlinearity of the relationships among variables.
could indicate magnitude of the observation (see Figure 9-5). Anscombe (1973) called
this representation a "triple scatterplot." Additional information can be displayed by
changing size or orientation of the symbol. Fienberg (1979) and Carr et al. (1986)
provide overviews and discussions.
9.3.2 Surface Methods
In many cases, it is appropriate to think of the observations as values on a smoothly
varying continuous surface, e.g., the spatial distribution of a chemical contaminant
about the source of the contaminant. The surface can be represented as a three*
9-8
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SAMPLE LAKE AREA
. 4 - 10 ha (10 - 25 acres)
© 10-40 ha (25 - 100 acres)
® 40 - 400 ha (100 - 1000 acres)
>400 ha (1000 acres)
Figure 9-5. Example glyph plot. (Adapted from Linthurstetal. 1986)
9-9
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dimensional perspective plot or as a series of contour lines. In either case, a smooth
representation requires interpolating or fitting the surface between data points.
Many software packages that produce contours from irregularly spaced data points
begin by interpolating the points to a regularly spaced grid. Thus, interpolation
during data analysis can be avoided if systematic spacing of sampling points is
achieved initially.
9.3.2.1 Spatial Interpolation
Techniques in the literature that have been proposed for spatial interpolation include
Thiessen polygons, polynomial interpolation, distance weighted least squares, and
spatial stochastic processes. All of the commonly used methods produce an
interpolated point as a weighted linear combination of observed data. The differences
between the methods are in the manner in which the weights are selected. Varying
assumptions are made about the underlying process that generated the data. These
assumptions should be carefully checked before selecting an interpolation method.
9.3.2.2 Thiessen Polygons
This method, originally published by Thiessen (1911), associates a polygon with each
data point in a region, with the polygon consisting of the part of the region closer to
that data point than to any other. An interpolated value at any point of interest can
be obtained by assigning that point the value associated with the nearest polygon.
The resulting surface is quite discontinuous, but can be the basis for a very effective
display of spatial pattern. The polygons can be plotted, and the data values assigned
shading intensity corresponding to magnitude (see Figure 9-6).
9-10
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Figure 9-6. Example data depiction using Thiessen polygons.
(Adapted from Linthurst et al. 1986)
9-11
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9.3.2.3 Spatial Splines
The division of the plane region into Thiessen polygons (also called a Dirichlet
tesselation) provides a starting point for some spatial spline methods. A one-
dimensional spline is a series of polynomials defined over successive intervals whose
endpoints are usually data points. The polynomials are "tied" together at the data
points (also called "knots") by requiring the equality of adjacent polynomials when
evaluated at the knots. The smoothness of the splines can be increased by also
requiring the equality of the first n derivatives, where usually n < 3. A spatial spline
requires equality of functions and derivatives along a line joining two data points.
The Theissen polygons are used to construct a triangulation of the region, called a
Delauney triangulation, by connecting points for which the associated polygons have
a common edge. A two dimensional analog of linear interpolation fits a plane to each
triangle. This produces a continuous surface, with sharp edges along the edges of the
triangles. The value of the plane at a point within the triangle is a weighted
combination of the values at the vertices of the triangle, where the weights are the
distances from the point to the respective vertex. Several methods of using distance
weighted least squares (DWLS) (McLain 1976; Akima 1978; Sibson 1980) have been
proposed that interpolate over the triangles and give continuously differentiable
surfaces. More generally, DWLS does not have to be restricted to interpolation over
triangles, but can be used over arbitrary regions.
A related approach is to fit a bivariate polynomial to the data (Brodlie 1980). This
approach leads to some smoothing if the number of monomial terms is less than the
number of data points (least squares approach), or it leads to exact interpolation if the
number of monomials is equal to the number of data points (LaGrange approach). A
bivariate quintic polynomial is the basis of the contouring subroutine in the
9-12
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geographic information system ARC/INFO, marketed by ESRI (Environmental
Systems Research Institute 1987a, b).
9.3.2.4 Kriging
Kriging has recently become a popular technique for spatial interpolation. In this
technique, the observations are considered as a realization of a spatial stochastic
process with both a trend function and a noise component. The interpolated
estimates are derived by minimizing the variance of the interpolation error. The
estimates produced by Kriging are also weighted linear combinations of observed
data. The specification of a spatial covariance structure is required in order to apply
the technique, and in most applications, the covariance is assumed to be both
homogeneous and isotropic. The smoothness of the resulting surface is controlled by
the choice of the covariance function: the more slowly the function decreases the
smoother the surface. Many Kriging applications use the variogram (a
transformation of the covariance function) instead of the covariance function, but the
results are equivalent. Complete discussions of Kriging can be found in Clark (1979),
Journel and Huijbregts (1978) and David (1977). David (1977) also provides a
thorough discussion of the basis for Kriging and discusses the practical aspects of
estimating the variogram and developing a Kriging code. Davis and Culhane (1984)
discuss the use of Kriging in contour applications and illustrate how to avoid a
preliminary step of interpolating to a grid. Experience with Kriging as a contouring
instrument has not been uniformly favorable. The contours produced sometimes
cross, and behavior in regions of sparse data can be very erratic.
One advantage of Kriging over other interpolation methods is that it provides an
easily available estimate of precision. The estimate can also be used to check the
effects of increased sampling density. This can provide some assurance that enough
9-13
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data points have been taken to achieve the desired precision of the contour lines.
However, the variance estimate is highly dependent on the assumed covariance
function, which is one of the most difficult quantities to estimate. Large data sets are
needed to provide reliable estimates, and the assumption of a homogeneous and
isotropic covariance function can seldom be checked. The variance estimates should
be used with caution.
Variance estimates can be obtained for any interpolation method by jackknifing,
cross-validation, or bootstrapping (Efron 1981; Efron and Gong 1983). These
techniques are variations on the idea of setting some data aside, and using the
remaining data to predict the withheld data. Rochelle et al. (1988) provide an
example of using cross-validation to estimate uncertainty in runoff contours.
9.4 DATA ANALYSIS AND INTERPRETATION CASE STUDIES
There are relatively few case studies that illustrate evaluations of adverse ecological
effects at hazardous waste sites. The following representative examples emphasize
the potential benefits gained from integrated laboratory and field assessments and
reinforce the significance of gathering data on chemistry, toxicity, and ecological
effects during the ecological assessment process. The realized contribution of
integrated studies will vary on a site-specific basis. Ultimately, the data should be
integrated for correct interpretation of the potential adverse ecological effects which
may be present at an HWS.
9.4.1 Rocky Mountain Arsenal (Thomas et al. 1986)
In this study, laboratory toxicity test results were used in a three-phase research
project with the following objectives: (1) to assess the comparative sensitivity of test
organisms to known classes of chemicals; (2) to determine if the chemical components
9-14
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in field soil and water samples of unknown chemical composition could be inferred
from laboratory studies using pure chemicals; and (3) to investigate Kriging of
toxicity data as methods to define the areal extent of chemical contamination.
Toxicity test results revealed that the algal assay was generally the most sensitive
test for samples of pure chemicals, soil elutriates, and water from eight sites with
known chemical contamination. Toxicity tests on nine samples of unknown chemical
composition from the Rocky Mountain Arsenal site showed that lettuce seed
germination phytoassay was the most sensitive. Preliminary evidence suggests that
toxicity tests are a useful tool in identifying classes of toxic components of
contaminated soil. Nearly pure formulations of insecticides and herbicides were less
toxic than were their counterpart commercial formulations. This finding indicates
that chemical analysis alone may fail to correctly rate the severity of possible
environmental toxicity.
The case history of the Rocky Mountain Arsenal exemplifies an integrated study that
incorporated laboratory-generated toxicity data into field assessments (see section
6.3). The Thomas, et al. (1986) work used toxicity test results to develop an
assessment of the spatial distribution of toxicity at the site. Kriging analysis was
applied to laboratory-derived toxicity test results to generate a map of the spatial
distribution of toxicity (Figure 9-7). Incorporating the toxicity test results into the
site assessment provided a realistic assessment of the ecological effects associated
with the HWS and aided the decision making process.
9.4.2 Comparative Toxicity Assessment (Miller et al. 1985)
Comparative toxicological studies on algae (Selenastrum capricornutum); daphnia
(Daphnia magna); earthworms (Eisenia foetida); microbes (Photobacterium fisherii),
mixed sewage microorganisms and plants; wheat, "Stephans," (Triticum aestivum);
9-15
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16 90
DISTANCE (m| FROM NORTHEAST CORNER
Figure 9-7. Estimated lettuce seed mortality (Based on Kriging)fortheO-15
cm soil fraction from the Rocky Mountain Arsenal. (Thomas et al.
1986)
lettuce, "butter crunch" (Lactuca sativa L.); radish, "Cherry Belle," (Raphanus
sativa); red clover, "Kenland," (Trifolium partense L.); and cucumber, "Spartan
Valor," (Cucumis sativa L.) were conducted on selected heavy metals, herbicides and
insecticides. Algae and daphnia were found to be most sensitive to heavy metals and
insecticides, followed in order of decreasing sensitivity by Microtox (Photobacterium
flsherii), DO depletion rate, seed germination test, and earthworms. Higher plants
were the most sensitive to 2,4-D (2,4-Dichlorophenoxy acetic acid), followed by algae,
Microtox, daphnia and earthworms. Differences in toxicity of 2,4-D chemical
9-16
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formulations and commercial sources of insecticides were observed with algae and
daphnia tests.
As part of the work, a toxicity assessment was completed for the Western Processing
site in Kent, WA. Toxicity tests selected for use in this site evaluation included the
earthworm test on soil as well as the algal, root elongation, and daphnid short-term
tests, which were completed on surface waters and soil eluates (see Table 9-1). The
battery of single-species, multi-media toxicity tests contributed significantly to the
evaluation of the Western Processing site. On-site contaminant loads occurred as
complex chemical mixtures rather than as single-compounds. The toxicity tests
indicated that toxicity was indeed present at various locations, despite the chemical
analyses of water samples that suggested that toxicity was not evident.
9-17
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Table 9-1. EC50 Response in Soils (Earthworm), Soil Elutriate, and Surface Water
to Chemical Contaminants in Western Processing Samples
Test East ditch
organism control
Pond
water
Sample
005
Sample Sample
017 020
Algae
Daphnia
Microtox 5 min
15 min
30 min
Lettuce RE
Earthworms 3
0.450
0.900
NE
NE
NE
NE
NE
0.008
0.185
0.827
0.213
NE
NE
—
0.004
0.033
0.412
0.056
0.056
0.614
>0.50<1.00
0.249
NE1
0.554
0.501
0.434
0.49/1.002
>1.00
NE
NE
NE
NE
NE
NE
NE
1 NE = No significant toxicity was observed.
2 49/100 = 0.49 inhibition in 1.0 soil elutriate.
3 LC50 values = concentration at which 50% mortality occurs.
9.4.3 Small Mammal Assessment (Rowley et al. 1983)
In this study, voles (Microtus pennsylvanicus) were trapped in the immediate area of
Love Canal near Niagra Falls, New York (I), in an area very close to Love Canal (II),
and in a reference area (HI) about 1 km from Love Canal. The population densities
were low in I, intermediate in n, and high in HI. Using ages estimated on the basis of
dry lens weights, mean life expectancy from weaning was 23.6 days in I, 29.2 days in
II, and 48.8 days in HI. Survivorship curves had significantly steeper slopes near the
canal than in the reference area. Thus, voles near the canal experienced a higher
mortality rate than those in the reference area. Liver and adrenal weights in females
and seminal vesicle weights in males were significantly reduced in I compared to IH.
A fat pool from voles in I and II contained hexachlorocyclohexane and other
chlorinated hydrocarbons that were not found in voles from the reference area. These
results suggest that the relatively sedentary small native mammals were useful in
assessing the presence of hazardous contamination.
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As in situ biomonitors, the small mammals trapped at various locations on or near
the Love Canal site suggested exposure had occurred. Biological responses (e.g.,
altered age structure and mortality curves) suggested population level changes had
occurred, and while acute toxicity was not considered in the reported work, longer-
term effects related to reproductive endpoints were demonstrated in the field work
completed on site or at a reference site located nearby. Supporting laboratory
analyses of biological tissues (e.g., comparison of liver and adrenal weights from
individuals captured on site and off site) further suggested that exposure had
occurred, and reinforced the potential role of integrated laboratory and field studies
as complementary features of site evaluation.
9.4.4 Mutagenesis Assessment (McBee et al. 1987)
In this study, examination of standard metaphase chromosome preparations was
employed to evaluate the use of resident small mammals as indicators of
environmental mutagenesis. Small mammals of two species, Peromyscus leucopus
and Sigmodon hispidus, were trapped over a two-year period at a locality polluted
with a complex mixture of petrochemical waste products, heavy metals, and PCBs
(polychlorinated biphenyls) and at two uncontaminated localities. Significant
differences in levels of chromosomal aberrations between animals collected at the
contaminated site and the uncontaminated sites were clearly indicated. Increases in
lesions per cell and aberrant cells per individual were shown for both species at the
contaminated site compared to the control sites. Levels of chromosomal aberrations
were not different between the two control sites, however. This study suggests that
cytogenetic analysis of resident small mammals is a feasible test model for
assessment of environmental mutagenesis.
9-19
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As shown in Table 9-2 and Figures 9-8 and 9-9, trapped populations of small
mammals presented cellular and molecular level responses (e.g., chromosomal
aberrations) that were correlated with exposure to chemical constituents of complex
mixtures characteristic of hazardous waste sites; acute toxicity was not addressed,
nor was it apparent, in these studies. The potential longer-term biological effects
suggested by the cytogenetic analyses, however, clearly indicated responses relevant
to site assessments evaluating adverse ecological effects, and reinforced the
importance of reference sites when correlative analyses are considered in the
assessment of biological effects in the field.
Table 9-2. Chromosome Aberrations in Peromyscus leucopus from One Field Site
(FS) and Two Control Sites (CSl and CS2) as Assessed by Standard
Metaphase Chromosome Preparations
Number of
Locality individuals
CSl
CS2
FSla
FS2a
12
14
12
20
Number of
cells
600
700
600
1000
Mean Number
aberrant cells/
individual
1.42(0-4)
1.79(0-4)
5.92*t(2-10)
6.15*t(2-9)
Mean Number
lesions/cell
0.04(0-8)
0.04(0-5)
0.16*t(0-15)
0.15*t(0-17)
% Cells with
chromosome
aberrations
2.83
3.57
11.83*
10.06*
* Indicates significant increases in field site values compared to the baseline value
of control sites.
t Indicates significant differences by Student's t tests (p<0.05). Numbers in
parentheses are ranges.
9-20
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a
Ml /f* 4* ** **
6f» tft
AA XA
X X
II a 11
10 IA K
1(1 W AA O •* «• A
II HA (A IK Ai AA «•
AH ^» Aft ••
XY
Figure 9-8. Normal geimsa stained standard karyotypes of a. Peromyscus
leucopus, female, 2n = 48; b. Sigmodon hispidus. male, 2n = 52
(fromMcBee et al., 1987).
9-21
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B
H
Figure 9-9. Representative chromosomal aberrations detected in standard
IJS^-J5 hrjmos°maj preparations of Peromvscus leucopus
?fi?.<}
-------�
9.5 REFERENCES
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Anscombe, F.J. Graphics in Statistical Analysis. American Statistician. 27:17-21.
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Brodlie, K.W., ed. 1980. Mathematical Methods in Computer Graphics and Design.
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Environmental Systems Research Institute. 1987a. ARC/INFO Users Manual,
Version 3.2. Environmental Systems Research Institute, Inc., Redlands, CA.
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9-24
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9-25
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APPENDIX A
ECOLOGICAL ASSESSMENTS of HAZARDOUS WASTE SITES
WORKSHOP PARTICIPANTS
Elmer Akin
U.S. Environmental Protection Agency
Region 4
345 Courtland Avenue
Atlanta, GA 30365
Joan Baker
Kilkelly Environmental Associates
P.O. Box 31265
Raleigh, NC 27622
Federal Express: Highway 70 West
The Water Garden
Raleigh, NC 27612
John Barich
U.S. Environmental Protection Agency
Hazardous Waste Division
1200 Sixth Street
Seattle, WA 98101
Lee Barkley
U.S. Fish and Wildlife
Division of Environmental Contaminants
1000 N. Glebe Road, Room 601
Arlington, VA 22201
John Bascietto
U.S. Environmental Protection Agency
WH-527
401M Street
Washington, DC 20460
Wes Birge
School of Biological Sciences
University of Kentucky
Lexington, KY 40506
Gabriel Bitton
Department of Environmental Engineering
University of Florida
Gainesville, FL 32611
904/392-0838
(will not attend the Seattle Workshop)
A-l
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APPENDIX A
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APPENDIX 1 (cont.)
Jerry Bromenshenk
University of Montana
Department of Zoology
Missoula, MT 59812
406/243-5648
Dave Charters
U.S. Environmental Protection Agency
Environmental Response Branch
MS-101
Woodbridge Avenue
Edison, NJ 08837
Patricia Cirone
U.S. Environmental Protection Agency
Environmental Studies Division
1200 Sixth A venue
Seattle, WA 98101
Ken Dickson
Institute of Applied Sciences
P.O. Box 13078
North Texas State University
NT Station
Denton, TX 76203
Federal Express: Corner of Avenue B and Mulberry
General Academic Building
Room 471
Denton, TX 76203
Rich DiGiulio
School of Forestry & Environmental Studies
Duke University
Durham, NC 27706
919/684-6090
Michael Dover
375 Concord Drive
The Cadmus Group
Bellmont, MA 02178
Barney Dutka
Environment Canada
Canada Center for Inland Waters
867 Lakeshore Road
Burlington, Ontario L7R 4A6
416/336-4923
A-2
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APPENDIX 1 (cont.)
John Emlen
National Fisheries Research Center
U.S. Fish & Wildlife
Building 204
Naval Support Facility
Seattle, WA 98115
James Fairchild
National Fisheries Research Center
Route #1
Columbia, MI 65201
314/875-5399
John Fletcher
University of Oklahoma
Department of Botany & Microbiology
770 Van Vleet Street
Norman, OK 73019
JefTGiddings
Springborn Life Sciences
Environmental Toxicology and Chemistry Division
790 Main Street
Wareham, MA 02571
JefTHatfield
Patuxent Wildlife Research Center
U.S. Fish & Wildlife
Laurel, MA 20708
Charles Hendricks
U.S. Environmental Protection Agency
200 S.W. 35th Street
Corvallis.OR 97333
503/757-4582
Kathryn Higley
Battelle
Pacific Northwest Laboratories
P.O. Box 999
Richland, WA 99352
Harvey Holm
College Station Road
U.S. EPA
Athens, GA 30613
A-3
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APPENDIX 1 (cont.)
Bob Hughes
U.S. Environmental Protection Agency
CERL/NSI
200 SW 35th Street
Corvallis, OR 97330
Elaine Ingham
Department of Botany & Plant Pathology
Oregon State University
Corvallis, OR 97331
Larry Kapustka
U.S. Environmental Protection Agency
200 S.W. 35th Street
Corvallis, OR 97333
503/757-4606
Hal Kibby
U.S. Environmental Protection Agency
200 SW 35th Street
Corvallis, OR 97333
Tom LaPoint
National Fisheries Research Center
Route #1
Columbia, MI 65201
314/875-5399
(will not attend the Seattle Workshop)
Will Laveille
U.S. Environmental Protection Agency
OEPER (RD 682)
401 M Street, SW
Washington, DC 20460
Greg Linder
CERL/NSI
200 S.W. 35th Street
Corvallis, OR 97333
503/757-4639
Karen McBee
Department of Zoology
LSW 430
Oklahoma State University
Stillwater, OK 74078
405/624-5555
A-4
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APPENDIX 1 (cent.)
Pat Mundy
U.S. Environmental Protection Agency
WH548A
401 M Street, SW
Washington, DC 20460
Ossi Meyn
U.S. Environmental Protection Agency
WH562B
401 M Street, SW
Washington, DC 20460
Susan Norton
U.S. Environmental Protection Agency
Office of Health and Environmental Assessment
RD-682
401 M Street, SW
Washington, DC 20460
Benjamin Parkhurst
Western Aquatics, Inc.
P.O. Box 546
Laramie.WY 82070
Federal Express: 203 Grand Avenue
Laramie.WY 82070
307/742-7624
Ron Preston
Environmental Services Division
U.S. Environmental Protection Agency
303 Methodist
Wheeling, WV 26003
Ron Stanley
U.S. Environmental Protection Agency
PM223
401 M Street
Washington, DC 20460
Don Stevens
Eastern Oregon State College
LeGrande, OR 97850
503/963-2171
A-5
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APPENDIX 1 (cont.)
Glenn Suter
Oak Ridge National Laboratory
P.O. Box 2008
Building 1505
Mail Stop 038
Oak Ridge, TN 37831-6038
Federal Express: Bethel Valley Road
Oak Ridge, TN 37831-6038
615/574-7306
John Thomas
Battelle Pacific Northwest Laboratories
P.O. Box 999
Richland,WA 99352
William Warren-Hicks
Kilkelly Environmental Associates
P.O. Box 31265
Raleigh, NC 27622
Federal Express: Highway 70 West
The Water Garden
Raleigh, NC 27612
Ron Wilhelm
U.S. EPA
WH-527
401M Street S.W.
Washington, B.C. 20460
Bill Williams
U.S. EPA
200 SW 35th Street
Corvallis, OR 97330
Craig Zamuda
U.S. Environmental Protection Agency
Hazardous Waste Branch
PM220
401 M Street, SW
Washington, DC 20460
A-6
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