PRELIMINARY ASSESSMENT
OF THE ENVIRONMENTAL PROBLEMS
ASSOCIATED WITH
VINYL CHLORIDE AND
POLYVINYL CHLORIDE
Report on the Activities and
Findings of the Vinyl Chloride Task Force
ENVIRONMENTAL PROTECTION AGENCY
WASHINGTON. D.C.
SEPTEMBER 1974

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PRELIMINARY ASSESSMENT OF THE ENVIRONMENTAL PROBLEMS
ASSOCIATED WITH
VINYL CHLORIDE AND POLYVINYL CHLORIDE
A Report on the Activities & Findings of the
Vinyl Chloride Task Force
Compiled by the Office of Toxic Substances
Environmental Protection Agency
Washington, DC
September 1974
With Contributions from the Following Task Force Members
OFFICE OF WATER AND HAZARDOUS MATERIALS
Mr.	Glenn E. Schweitzer, Office of Toxic Substances (Chairman)
Dr.	Nancy Beach, Office of Toxic Substances (Coordinator)
Mr.	John B. Ritch, Office of Pesticide Programs
Mr.	David Becker, Office of Water Quality Planning & Standards
Mr.	John Nardella, Office of Water Quality Planning & Standards
Dr.	Richard Rhoden, Office of Water Quality Planning & Standards
Mr.	William T. Musser, Office of Water Program Operations
Mr.	Benjamin H. Pringle, Office of Water Program Operations
OFFICE OF AIR AND WASTE MANAGEMENT
Mr. Mike H. Jones, Office of Air Quality Planning & Standards
Mr. Alessi D. Otte, Office of Solid Waste Management
OFFICE OF ENFORCEMENT AND GENERAL COUNSEL
Dr. William M. Reid, Office of Technical Analysis
OFFICE OF PLANNING AND MANAGEMENT
Dr. Joel Jacknow, Office of Planning and Evaluation
OFFICE OF RESEARCH AND DEVELOPMENT
Dr.	Lawrence A. Plumlee, Office of Program Integration
Dr.	Henry F. Enos, Office of Monitoring Systems
Dr.	Robert McGaughey, Office of Environmental Sciences
Dr.	Andrew J. McErlean, Office of Environmental Sciences
Mr.	Paul E. des Rosiers, Office of Environmental Engineering
Dr.	Dale A. Denny, NERC-Research Triangle Park
Mr.	Frank P. Scaringelli, NERC-Research Triangle Park
STAFF OFFICES
Mr. George Marienthal, Office of Regional Liaison
Ms. Leslye Arsht, Office of Public Affairs
Mr. Pope A. Lawrence, Office of Federal Activities
Mr. Bryan F. LaPlante, Office of Legislation
REGIONAL OFFICES
Mr. George J. Moein, Region IV, Atlanta, Georgia
Dr. Oscar Ramirez, Jr., Region V, Dallas, Texas

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PREFACE
This Report summarizes the activities and findings of the Task Force
established by the Administrator on February 14, 1974, to assess the
character and extent of the problems associated with the production, dis-
tribution, use, and disposal of vinyl chloride and polyvinyl chloride. The
discussion and conclusions presented in the Report should be considered
preliminary since the Task Force has only scratched the surface of a
complicated subject and analyses within the Agency are continuing. The
Report is not a statement of Agency policy even though many of the
recommendations are already being implemented.
During the lifetime of the Task Force the Agency took several regula-
tory steps concerning vinyl chloride. These were directed to banning
pesticidal sprays containing vinyl chloride as a propellant and requesting
information from industry pursuant to Section 114 of the Clean Air Act
concerning vinyl chloride air emissions and related control technologies.
Since these activities have been or are being documented m detail m
other reports, they are mentioned only briefly in this Report.
Similarly, m recent months the Occupational Safety and Health Ad-
ministration, the Food and Drug Administration, and the Consumer Product
Safety Commission took a series of regulatory actions directed to vinyl
chloride. While recognizing many of the problems facing other Government
agencies and the implications for EPA of their regulatory steps, the Report
dwells primarily on those activities of direct responsibility to EPA, and
problems such as worker exposure to chemicals, use of polyvinyl chloride
in food packaging, and consumer products containing vinyl chloride have
not been a major concern.
The Report is organized into an Executive Summary, three Sections,
and Appendices. The first Section discusses the nature and magnitude
of the problems associated with vinyl chloride and polyvinyl chloride
activities. The second Section discusses previous and planned activities
within the Federal Government of particular significance and the role of
industry. The Report concludes with a Section setting forth the specific
recommendations of the Task Force. The Appendices present a consider-
able body of original data developed by the Task Force with the assistance
of a large number of EPA specialists.

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TABLE OF CONTENTS
Page
PREFACE
1
EXECUTIVE SUMMARY
1
Background
1
EPA Concerns
2
Further Steps
3
CHARACTER AND SCOPE OF PROBLEMS BEYOND THE
WORKPLACE
4
Emergence of the VC Problem
Exposure to VC of Special Importance to EPA
4
5
Pesticidal Sprays
Discharges from VC/PVC Plants: Materials Balance
and Monitoring Data
Transportation Accidents
Unreacted Monomer Entrapped in PVC Products
Health Effects of Vinyl Chloride	8
Persistence of VC	10
Ecological Effects of VC	10
Other Chemicals of Concern in PVC Activities	11
Size and Character of the PVC Industry	12
Lessons Learned from VC/PVC Experiences Relevant to Other
Chemical Problems	13
INTERESTS AND ACTIVITIES OF GOVERNMENT AGENCIES
AND INDUSTRY	16
EPA Regulatory Authorities	16
Pesticide Registration
Air Pollution
Water Pollution
Solid Waste Disposal
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Page
Ocean Dumping
Drinking Water
Proposed Toxic Substances Control Act
Supporting Research Activities
Regulatory Interests of Other Agencies	19
Aerosol Sprays
Worker Protection
Unreacted VC Monomer in PVC Products
Transportation Handling
Related Research Activities
Role of Industry	22
Reducing Discharges of VC and Other Toxic Chemicals
Medical Surveillance
Fenceline Monitoring for Chemical Discharges
Toxicological Testing of VC
Testing for Persistence and Environmental Fate and Effects
of VC and PVC
Testing for Levels of Unreacted Monomer in PVC Resins
and PVC Products
RECOMMENDATIONS	26
Regulatory and Directly Supportive Actions by EPA	26
Steps by Industry	29
APPENDICES
APPENDIX I - SELECTED ECONOMIC CONSIDERATIONS
APPENDIX II - PRODUCERS OF VC AND PVC
APPENDIX III - THE MATERIALS BALANCE AT VC AND PVC
FACILITIES
APPENDIX IV - INTERIM METHOD FOR SAMPLING AND ANALYSIS
OF VC IN WASTE WATER EFFLUENTS AND AIR
EMISSIONS
APPENDIX V - SUMMARY OF REGIONAL ACTIVITIES
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APPENDIX VI- PERSISTENCE OF VINYL CHLORIDE
APPENDIX VII- HEALTH EFFECTS OF VINYL CHLORIDE
APPENDIX VIII- DISPOSAL OF PRODUCTS CONTAINING POLYVINYL
CHLORIDE
APPENDIX IX - ACTIVITIES OF TASK FORCE
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EXECUTIVE SUMMARY
EPA's recent concern over vinyl chloride (VC) and polyvinyl chloride
(PVC) was triggered by reports in January 1974 of (a) deaths of four PVC
workers believed to be attributable to exposure to VC, and (b) an estimated
material loss ofVCand PVC of six percent during the PVC polymerization
process. The investigations of the Task Force confirm that in the United
States substantial amounts of VC--probably exceeding 200 million pounds
annually -- and large quantities of PVC -- probably exceeding 50 million
pounds -- are being discharged into the environment during the PVC pro-
duction process. Meanwhile, additional epidemiological and toxicological
evidence supports the linkage between worker deaths and VC exposure.
The VC/PVC industry has experienced rapid growth at home and
abroad in recent years with PVC products currently permeating our entire
economy. This multi-billion dollar industry involves not only several
dozen large manufacturers of VC and PVC resin but also thousands of
fabricators producing a variety of products based on PVC and probably
employing more than 300,000 workers. There are readily available sub-
stitutes for PVC in some of these products; more expensive substitutes
for others; and no substitutes for still others. A principal constraint
on near-term production increases has been availability of ethylene, a
petroleum derivative. A new constraint is the uncertainty over Govern-
mental regulatory actions affecting VC/PVC activities,
VC has induced angiosarcoma of the liver in rats and mice exposed to
concentrations of 50 ppm at intervals simulating occupational exposure,
and this same rare and fatal tumor has been identified in at least 15
former workers in U. S. PVC facilities. Cancers at other sites,
non-malignant liver disease, and a unique occupational disease --
acroosteolysis -- have also been attributed to VC exposure. There
is no direct evidence that VC contributes to adverse health effects at
the lower levels of exposure encountered outside the workplace; how-
ever, two recently reported cases of angiosarcoma of the liver in
non-workers who had lived near PVC fabrication plants suggest the
possibility of such a correlation. At the same time there has been
little effort to search for adverse effects at these lower levels. Since
carcinogens are generally considered not to have a "no effects" threshold
level, there should be concern with possible risks to health at even
the lowest levels of exposure to VC which are encountered in the ambient
air, and possibly in water.
Preliminary monitoring results at seven industrial complexes involv-
ing 10 PVC resin and 2 VC plants indicate that the levels of VC in the
ambient air near the plants fluctuate sharply, apparently due to the periodic
opening of reactor kettles in the PVC plants, accidental plant discharges,
variations in the production process, and meteorological conditions.
While almost all of the samples collected contamed detectable levels
of VC, more than 90 percent of the instantaneous observations and 97
percent of the 24-hour samples showed amounts less than 1 ppm. At
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several of the chemical complexes, a number of individual air samples
showed more than 1 ppm. At one PVC plant a high of 33 ppm was
obtained at one site; however, repeated sampling indicated that
this level was an unusually high excursion with the average at this site
less than 1 ppm. Most of the air sampling was done within one-half
mile of the property lines of the plants. In one case a level of 3.4
ppm was recorded at a distance of three miles from the plant, but the
average of several readings at this site was approximately 0.5 ppm.
Water effluents were also monitored, and levels varied considerably
depending on the in-plant handling of wastes and treatment of wastewater.
The highest level for wastewater leaving the plant site was 20 ppm. More
typically, levels of 2 to 3 ppm were found. Not unexpectedly, the levels of
VC entrapped in sludge and other solid wastes from the reactor kettles
ranged from 100 ppm to, in one case, 3,000 ppm.
EPA Concerns
The principal near-term issues facing the Agency include (a) an
assessment of the risks associated with exposure to VC, with such
an assessment hampered by inadequate data concernmg health effects
at the levels likely to be encountered in the environment and only very
preliminary monitoring results, (b) the costs to industry to reduce the
levels of VC entering the environment, keeping in mind that much
of the cost will be passed on to society as a whole, and (c) regulatory
and related steps which will contribute to reducing the risks at an
appropriate cost. Two closely related areas of interest are (a) the
amount of Agency resources to be directed to VC/PVC in the months
and years ahead, and (b) lessons that have been learned in addressing
VC/PVC that can save time and resources in addressing other chemicals.
VC air emissions from PVC polymerization plants -- and to a lesser
extent from VC plants and possibly PVC fabrication plants -- are the
most immediate concern to the Agency. The earlier problems related
to the use of VC as a propellant in pesticidal sprays have been largely
resolved with the banning of such sprays. Other current concerns
related to VC include the Agency's capability to provide sound advice
in the event of transportation accidents involving the release of VC;
the fate and effects, if any, of VC trapped in water effluents, and
particularly VC that might thereby appear in drinking water; and the
migration of unreacted VC from PVC products into drinking water or into
the ambient air.
There are of course a host of other chemicals involved in VC/PVC
activities that should be of concern. Impurities m the VC, PVC as
inhaled or ingested particulate, additives introduced to alter the proper-
ties of PVC, copolymers used in conjunction with PVC, and chlorinated
hydrocarbon wastes from VC production all need further investigation.
The by-products associated with PVC incineration and the leaching of
additives, and particularly plasticizers and toxic metals, from PVC
products which come into contact with the aquatic environment need
additional study.
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Further Steps
Development of an air emission standard for VC is currently under-
way, with additional monitoring activities being planned in the immediate
future to improve the basis for the standard. While additional epidemio-
logical and toxicological data are slowly becoming available, it is unlikely
that there will be a good technical basis within the next few months or
perhaps even within several years for establishing an appropriate ambient
level to protect public health. Therefore, a performance standard may
be far easier to develop and implement than a standard based upon
achieving a specific air quality level. Initial estimates indicate that
available control technology when installed can reduce VC emissions
by about 75 percent from PVC resin plants and 90 percent from VC
plants with a concomitant increase in the cost of PVC of about four
percent. Currently available information indicates that such reductions
should result in ambient air levels .which present no established risk
to health or welfare. Meanwhile, close liaison with the Department of
Labor is important to insure that the regulatory approach to protect the
worker is compatible with EPA regulatory activities.
The Agency should monitor for VC in drinking water supplies.
Monitoring is also needed in the ambient air -- indoors and outdoors --
distant from chemical complexes to determine whether concentrations
of PVC products release quantities of unreacted VC that should be
of concern. Further refinement of monitoring methodologies is needed
in support of these efforts. The limited toxicological and epidemiological
studies that are planned should be fully supported.
The Agency should continue its leadership role in bringing together
other Agencies to exchange views on regulatory actions, supporting acti-
vities, and research projects related to VC and PVC. Industry should be
strongly encouraged to accelerate its efforts to reduce VC discharges
and its very limited research, testing, and monitoring activities to
clarify further the problems associated with VC and PVC.
Finally, we have been alerted in a rather dramatic fashion to the
need for greater attention to an important segment of our industrial base
which will surely continue to expand in the years ahead. Many of the
considerations and uncertainties that have punctuated the VC/PVC
deliberations undoubtedly characterize a far broader swath of concerns
over high volume industrial chemicals m general, and plastics in
particular. Hopefully, we can extrapolate from current experiences with
VC and PVC in identifying problems with other potentially important
commercial chemicals early m their embryonic stage and thus minimize
health and environmental hazards and also the economic dislocations
attendant to corrective actions. In this regard the Agency should continue
its efforts to seek early enactment of the Toxic Substances Control Act
which can provide a much needed broader basis for addressing these types
of problems.
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CHARACTER AND SCOPE OF PROBLEMS BEYOND THE WORKPLACE
Emergence of the VC Problem
On January 22, 1974, the B. F. Goodrich Company, the largest U. S.
producer of PVC resin, notified the National Institute of Occupational
Safety and Health (NIOSH) that four workers from its PVC polymerization
plant in Louisville, Kentucky, apparently had died from a rare cancer,
angiosarcoma of the liver. All four workers had been closely associated
for many years with the production of PVC resins. The rarity of the
tumor and the clustering of deaths at a single plant raised suspicions that
an occupational disease related to VC* exposure had been found. Since
that time, 10 additional cases of this tumor, which developed in U. S.
PVC polymerization workers since 1961, have been confirmed. This tumor
has also been reported m seven workers at European polymerization
plants, one worker at a U.S. PVC fabrication plant, two workers at Euro-
pean fabrication plants, one worker at a European VC plant, and two resi-
dents in the general population near U. S. fabrication plants.
Concurrently, toxicological data from animal studies became available
which further strengthened the suspicion of VC as the etiological agent
in the formation of the liver cancer. A broad spectrum of cancers was
reported by Professor Cesare Maltoni of Italy m different animal species
at various exposure levels. His inhalation studies of rats exposed to
50 ppm at repeated intervals approximating occupational exposures have
produced angiosarcomas of the liver and abdomen as well as tumors of
the kidney and skin. In mice exposed to VC the same tumors have been
observed, with the addition of lung tumors. Animal studies sponsored by
U. S. industry have confirmed Maltoni's observations at 50 ppm. Recent
epidemiological studies also suggest the possibility of multiple cancers
attributable to VC exposure.
Meanwhile, statements by industry and Government officials indicated
that the material loss to the environment during the PVC polymerization
process may be about six percent, with more than 75 percent of the losses
being VC air emissions. Also, it soon came to light that VC was being
used as a propellant in pesticidal sprays, and the EPA Regional Offices
were becoming more aware of railroad accidents involving VC tank cars.
Until this series of events the Agency had not been particularly con-
cerned with VC as an urgent problem. PVC plants had been on the list
of industries to be examined as candidates for new source perform-
ance standards to limit air emissions. Also, limited studies of PVC
disposal were underway, and VC and PVC resin manufacturing activities
have been addressed in the Effluent Guidelines promulgated under the
Federal Water Pollution Control Act. However, only since January
have VC/PVC activities been elevated to the level of priority Agency
attention.
* Vinyl chloride (CH2CHCI) is a colorless3 faintly sweet smelling gas at room
temperature. As a gas it is readily flammable and explosive but is usually
handled industrially as a liquid under pressure. Polyvinyl chloride resin
is a fine powder which is produced by polymerizing vinyl chloride. The re-
sin is the base ingredient for a wide variety of plastics.
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Exposure to VC of Special Importance to EPA
Pesticidal Sprays
Spurred by the active interest of a consumer protection organiza-
tion, the Health Research Group, one of the earliest EPA concerns this
year was the use of VC as a propellant in a large number of pesticidal
sprays. After the searching of EPA pesticide registration files more
than 50 different sprays containing VC -- including a large number used
indoors -- were identified. It has been estimated that in addition to the
cans in the possession of consumers, up to 100,000 cans were in the
channels of trade.
Preliminary tests at EPA research facilities showed that a 30 second
release of an aerosol containing VC could result in a concentration as high
as 400 ppm in the air. Related tests showed that in closed rooms VC
will persist for many hours, and even when diluted by ventilation, will
probably result m some VC exposure within the household for at least
several hours. (See Appendix VI).
Discharges from VC/PVC Plants: Materials Balance and Monitoring
Data
Industrial reports and analytical studies (see Appendix III) confirm
that generally the material loss during the PVC polymerization process
ranges from 4.5 to 7.5 percent. During recent months industry has taken
a variety of steps to reduce the losses, and these losses may be now
declining. The losses will vary with the type of process, the age of the
plant, the level of technology that is employed, and manufacturing
practices. However there is no doubt that in the United States substantial
amounts of VC -- probably exceeding 200 million pounds annually -- and
large quantities of PVC -- probably exceeding 50 million pounds -- are
being discharged into the environment during the PVC polymerization
process. Most of the VC escapes directly into the atmosphere, with
lesser amounts dissolved in water effluent streams and entrapped in sludge
and solid wastes. PVC losses occur as particulate in air emissions, sus-
pended solids in water effluents, and components of solid wastes.
A principal area of VC leakage is associated with the operation of
the polymerization kettles, including losses when they are opened or when
they are recharged or sampled. Other losses occur during the transfer of
VC from tank cars to storage, during the PVC drying process, and from
leaks at a variety of valves, flanges, and pump seals throughout the
process. Polymer losses are similarly distributed among a variety of
activities including dust collector losses, disposal of oversize particles,
and sampling losses. In this regard two aspects are particularly signifi-
cant: there are a variety of PVC processes with differing problems and
control possibilities, and in every case the number of potential leakage
points is very large.
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Losses at VC plants occur during the loading process, as the result
of venting of gases, from leaks in pumps, and at other points. These losses
are considerably less than one percent but still may be environmentally
significant. As in the case of PVC polymerization activities, current
industrial efforts should reduce these losses. No mass balance data are
available concerning losses at PVC compounding and fabrication plants.
However, the only source of VC at these facilities is the unreacted monomer
in the PVC resin which suggests that environmental discharges are less
than at the VC and PVC polymerization plants.
To obtain more direct evidence on VC discharges from VC/PVC acti-
vities, ambient air, waste water effluents, and solid wastes from seven
chemical complexes were monitored during May. The 2 VC and 10 PVC
production facilities located at these seven complexes are listed in the table
below:
Vinyl Chloride and Polyvinyl Chloride Manufacturing Complexes
Monitored by EPA Regional Offices
Louisville, Ky.
Leominster, Mass.
Plaquemine, La.
Long Beach, Calif.
Painesville, Ohio
Delaware City, Del.
Flemington, N. J.
PVC Plant
PVC Plant
PVC Plant
VC Plant
PVC Plant
PVC Plant
VC Plant
PVC Plant
PVC Plant
PVC Plant
PVC Plant
PVC Plant
The B. F. Goodrich Co.
B. F. Goodrich Chemical Co.
Borden, Inc.
Borden Chemical Division
The Goodyear Tire & Rubber Co.
Chemical Division
Dow Chemical, U.S.A.
The B. F. Goodrich Co.
B. F. Goodrich Chemical Co.
American Chemical Corporation
American Chemical Corporation
Uniroyal, Inc.
Uniroyal Chemical Division
Robintech, Inc.
Stauffer Chemical Co.
Plastics Division
Diamond Shamrock Corporation
Diamond Shamrock Chem. Co.
Tenneco, Inc.
Tenneco Chemicals, Inc.
The preliminary monitoring results indicate that the levels of VC in the
ambient air near plants fluctuate sharply, apparently due to the periodic
opening of polyvinyl chloride reactor kettles, accidental plant discharges,
variations in the production process, and meteorological conditions. A
summary of the monitoring results at each complex can be found in Appendix
V. The monitoring method developed for this activity, and subsequently
refined, is presented in Appendix IV. Since the samples were limited in
number, time, and duration, additional monitoring is in order to obtain a
more definitive assessment of VC discharges.
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Most of the air sampling was done up to three miles beyond the prop-
erty lines of the plants although in two regions the EPA sampling teams
were able to conduct part of the study within the plant property. Almost
all air samples contained detectable levels of VC. However, more than
90 percent of the instantaneous samples and 97 percent of the 24-hour
samples showed less than 1 ppm. In one case a level of 3.4 ppm was
recorded at a distance of three miles from the plant. The average of
several readings at this site was about 0.5 ppm. A high value of 33 ppm
was observed around one complex at a distance of 0. 3 miles from the fence -
line although the average at this site was less than 1 ppm.
The levels of VC in water effluents varied considerably depending on
the in-plant handling.of wastes and treatment of wastewater. The highest
level for wastewater leaving the plant site was 20 ppm. More typically,
levels of 2 to 3 ppm were found. Not unexpectedly, the levels of VC
entrapped in sludge and other solid wastes from the reactor kettles ranged
from 100 ppm to 3, 000 ppm.
Transportation Accidents
It is estimated that more than two-thirds of the produced VC is
transported from the production site to another location, frequently
located hundreds of miles away. More than 95 percent of the ship-
ments travel by rail tank car, with a small amount being shipped by
water. During the past three years there have been 16 reported rail
accidents involving VC tank cars. The immediate concern has been pre-
vention of fire and explosion and only recently has attention been directed
to the long-term effects, if any, that might be associated with a one-time
massive exposure to VC. 1/
Unreacted Monomer Entrapped in PVC Products
Industry has reported to EPA that PVC resin contains in very unusual
cases .as high as 8,000 ppm of unreacted VC monomer although the levels
are usually between 50 and 1,000 ppm. Presumably these levels are
substantially reduced as the resin is processed further, with much lower
levels (e.g. 5 to 20 ppm) present in finished products containing PVC.
Nevertheless, the eventual fate of the unreacted monomer in PVC
products is of concern. Conceivably, it could be contributing to a
general environmental background level of VC, and detectable levels
of VC may be present where there is a heavy concentration of products
containing PVC, and particularly new products.
In view of EPA's responsibilities concerning drinking water, a prob-
lem of special significance is the possible migration of unreacted
monomer into the water from PVC pipe or liners used in drinking water
systems. At present little is known about such migration.
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Health Effects of Vinyl Chloride
There is no direct evidence about the health effects on man of VC
at the levels of exposure that have been or are likely to be encoun-
tered outside the workplace; however, the two recently reported non-
occupational cases of angiosarcoma of the liver in neighborhoods near
PVC fabrication plants suggest the possibility that there may be a
correlation between the incidence of angiosarcoma and low levels of
exposure. There are also recent reports of angiosarcoma among workers
at fabrication and VC plants who presumably were exposed to relatively
low levels of VC. At the same time epidemiological and toxicological
studies have clearly linked VC to angiosarcoma of the liver and other
adverse effects at the higher levels of exposure that have been encoun-
tered in the workplace. Given the previous lack of effort to search for
effects at low doses, it seems prudent to assume that there probably
is not a no-effects threshold for VC, and there should be concern about
the possible health effects at any level of exposure.
Extrapolation of effects from animals to man, from intermittent to
sustained or peak exposures, and from high to low dose levels is fraught
with uncertainty. Nevertheless, such extrapolations can be useful in
helping set the basis for the necessarily subjective judgements that
must be made as to health risks. With regard to the toxicological data,
studies are currently underway at the National Cancer Institute and with-
in EPA using statistical methods to extrapolate from the effects at 50 ppm
to likely effects at 1 ppm and lower. Such statistical techniques must be
viewed with caution but can be helpful in providing a sense of perspective
in assessing risk. The relative sensitivites of rats, mice, and men to VC
are not known, nor is there good information on the relative sensitivities
within a human population. Another difficulty is interjected in attempting
to deal with the extrapolation from worker exposure (i. e. 40 hours per
week) to neighborhood exposure (i.e. up to 168 hours per week), even
assuming that time weighted averages are the determinant in ambient air
rather than peak levels.
The risks, if any, associated with ingestion of VC, via drinking water,
food, or other routes are totally unknown. It is prudent to assume that
ingestion is no less worrisome than inhalation although the likelihood of
sustained ingestion at even low levels seems remote.
Summarized below are some of the most important known health
effects of VC. A more detailed presentation of health data is set forth
in Appendix VII, recognizing that additional information is continuously
becoming available. Ongoing Agency studies are taking this information
into account.
Anesthetic Effects of Acute Exposures: These effects have occurred in
PVC workers exposed to high concentrations of VC as the result of acci-
dents or inadequately ventilated reactor vessels. A dizziness, nausea.
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and loss of consciousness occur which are reversible upon exposure to
fresh air. Human volunteers have reacted in a similar way to high levels
of VC inhaled for brief periods. These subjects reported feeling dizzy
or inebriated, experienced loss of certain reflexes, and encountered
feelings of impending unconsciousness. The effects were proportional to
concentrations and duration of exposure.
Acroosteolysis: A small proportion (from 1 to 3 percent) of workers
involved in manual cleaning of PVC reactor vessels have experienced a
combination of symptoms known as acroosteolysis. This is character-
ized by a soreness and thickening of the skin at the fingertips, a gradual
dissolution of bone calcium at fingertips and toes, skin sores, and fre-
quently heightened sensitivity of the hands to cold (blanching of the skin
and pain). These symptoms were first described in 1967, and apparently
occur only after several years of high levels of exposure.
Liver Function Abnormalities: Changes in blood chemistry attributed to
alterations in liver function have been observed in PVC workers whose
8-hour exposures to VC averaged 300 ppm. At levels below 300 ppm,
the noted functional changes were minimal, suggesting a dose-response
relationship with respect to liver function. There has been no overt
liver disease noted. From Europe, there are reports that liver damage
was found in Russian workers, and disease of the liver, skin, and other
organs has been discovered in workers in Rumania and France. Other
chemicals are invariably present in the occupational setting, and may have
interfered with the effect often attributed to VC alone.
Liver Angiosarcoma: A fourth effect related to occupational exposure
is angiosarcoma of the liver, a rare form of liver cancer which is a pro-
gressive and invariably fatal disease. It has recently been reported in 15
workers in PVC facilities in the United States. The exposure time of these
workers in the factory setting has ranged from 11 to 30 years. Many of these
workers were engaged in cleaning polymerization reactor vessels in an area
where exposure levels were the highest.
The etiological role of VC in the induction of liver angiosarcoma is not
certain because of possible confounding factors. The occupational expo-
sure of the workers to other chemicals precludes identifying this substance
as the sole cause for cancer. However, taking into account the effect of VC
on animals in the absence of other chemicals, the implication of VC as the
possible etiological agent is very strong, and unless another carcino-
genic agent is identified, VC must clearly remain the prime suspect.
The reported cases of angiosarcoma of the liver have in the past been
extraordinarily rare. For example, in the Third National Cancer Survey
(1969-1971), a population of 21 million persons residing in nine geographic
areas was sampled for incidence and type of cancer. In this period, only
eight cases of liver angiosarcoma had been newly diagnosed among that ten
percent of the U.S. population.
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Controlled Exposures of Animals to VC: On laboratory mammals VC con-
centrations of 5 to 20 percent have narcotic effects which are not unlike
the human anesthetic effects noted above. The acroosteolysis syndrome
has never been produced in animals, although disturbances in peripheral
blood circulation, abnormal cartilage formation in the toes, and abnormal
skin lesions have occurred in rats. Liver enlargement in rats has been
seen with inhalation exposure as low as 100 ppm for 6 months, but little is
known about frank liver disease caused by VC exposure.
Among the several animal inhalation experiments employing repeated
exposures of over six months duration, two have disclosed liver angio-
sarcoma at 50 ppm and higher in mice and rats. It remains to be deter-
mined whether the liver angiosarcoma observed in animals are precisely
the same as those reported for occupationally exposed workers and for non-
workers. Nevertheless, the similarities observed between the animals and
man strongly suggest that the animal carcinogenic reaction is like that
reported for PVC workers.
Persistence of VC
As discussed in Appendix VI, very preliminary investigations at EPA
laboratories suggest that in the ambient air near the emission source VC
can be considered as a stable pollutant whereas VC rather quickly escapes
from agitated or aerated water.
The available results indicate a rate of reaction of about 8 to 10 per-
cent per hour for VC in air. The direct and indirect reaction products
identified include ozone, nitrogen dioxide, carbon monoxide, formaldehyde,
formic acid, and formyl chloride. High eye irritation levels found with
human exposure levels are consistent with these products. Although VC
would disappear significantly over longer travel distances, the conversions
anticipated within a few miles downwind of VC emission sources indicate
that VC can be considered a stable pollutant near emission sources. The
usual meterological dispersion equations for gases could be applied to
approximate concentrations. Because of strong inversions at night during
the fall and winter period, buildup of VC near emission sources might
be of particular concern during such periods.
Ecological Effects of VC
As indicated above, preliminary studies concerning the volatility of VC
from aqueous solutions as well as analyses of hydrolysis and photolysis
suggest that the impact of VC in the aquatic environment may not be
significant. However, if there is a continued mput of VC into water,
it is possible that a steady state concentration of VC could be reached.
Bioaccumulation and/or biotransformation might then become of con-
siderable concern.
Potential terrestrial ecosystem effects, as well as transport pathways
from source to plant or animal receptors, of VC are unknown. How-
ever, the suspected volatility of VC may result m a large dilution factor
which might reduce the toxicological or bioac cumulation hazard to an
insignificant level.
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Given the lack of past attention to the ecological effects of VC,
some inferences drawn from the behavior of other low molecular weight
chlorinated hydrocarbons may be helpful in anticipating the fate and
effects of VC. In particular, 1, 1, 2 trichloroethane and 1, 2 dichloro-
ethane comprise a portion of the waste products -- often referred to as
tars --from the production of VC and are of concern in themselves as
well as possibly suggesting VC behavioral patterns. Other potentially
hazardous compounds, such as hexachlorobenzene and hexachlorobutadiene,
are also found in these tars. Therefore, tars are discussed below.
Other Chemicals of Concern in PVC Activities
Immediately following the January report of worker deaths related to
VC exposure, questions arose as to whether other chemicals, such as
vinylidene chloride, might also contribute to angiosarcoma either indepen-
dently or in conjunction with VC. Little work has been done to date to
clarify this concern. Also, the toxicity of PVC particulate has become a
significant interest. There have been some inhalation toxicology studies
conducted on PVC. However, there are no readily available data to indi-
cate whether any substantial risk is involved at the levels of exposure that
might be encountered via inhalation or ingestion of PVC outside the work -
place. 2/
As pointed out in Appendix VIII, a large number of chemicals are used
in PVC products as antioxidants, antistatics, colorants, fillers, plasti-
cizers, and stabilizers, and many of them can reach man through a variety
of routes. The health effects of some of these chemicals are reasonably
well known; the effects of others have yet to be explored. Several of them
are particularly good candidates for further investigation, e.g. cadmium,
barium. However, the Task Force has not attempted to assess in any
detail the known health risks nor sort out the priorities for further investi-
gation.
A special concern of the Task Force has been disposal of products con-
taining PVC and disposal of the by-products of PVC/VC plants. As
discussed in Appendix VIII incineration of PVC produces HC1 and possibly
metallic vapors. As the volume of PVC and other plastic products enter-
ing municipal waste systems continues to grow, the possibility of problems
resulting from incineration and land disposal -- particularly leachates --
will increase. In addition, toxic leachates from PVC used in the
lining of fish tanks are known to have caused damage to aquatic
organisms. 3/
The adverse effect of the tars from VC plants on aquatic organisms
has been of special concern since they are known to affect at least some
marine species at concentrations of 2. 5 ppm. Worms and barnacles are
also affected at levels below 5 ppm. Bioaccumulation of the tars appears
possible through the food chain, and these materials also adhere to
particles in water. However, relatively short biological half lives and
rapid excretion rates may prevent serious accumulation of the tars. 4/
11

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Size and Character of the PVC Industry
During 1973 VC production in the United States was at the 5.35 bil-
lion pound level with PVC and its copolymers at the 4.56 billion pound
level. The industry has been operating for about forty years, and over
the past five years has shown an annually compounded growth rate of 14
percent -- a rate of growth that is expected to taper off only moderately
in the next few years. A few of the most significant characteristics of the
industry are summarized below with additional details presented in Appen-
dices I and II. 5/
PVC has become a very important polymer as evidenced by the broad
dependence of nearly every branch of industrial and commercial activity
upon products and components fabricated from this plastic. Markets include
the apparel, building, construction, electrical, home packaging, recreation,
and transportation industries. The wholesale value of the annual output of
fabricated products is at least several billion dollars.
The synthesis of VC is conducted in fifteen U. S. plants, and thirty-
seven plants are engaged in polymerization with almost all of these plants
currently operating at or near capacity. Five new PVC resin plants are
under construction and together with expansions at five others will yield an
additional annual capacity of 1.378 billion pounds. Additional plants are in-
volved in manufacturing copolymers using VC. Approximately 7500 plants
are engaged in fabricating products from PVC. It is estimated that 1000
to 1500 workers are employed in monomer synthesis, an additional 5000 are
engaged in PVC polymerization operations, and approximately 350, 000 are
associated with the 7500 PVC fabrication plants.
More than 97% of the monomer is used for the manufacture of homopoly-
mer and copolymer resins, with the remainder utilized primarily for (a) the
production of methyl chloroform, (b) additives in specialty coatings, and
(c) until recently, aerosol propellants. Over 90% of the VC produced in the
United States is manufactured by ethylene-based processes; the remaining
10% is synthesized by the acetylene-based process. In both processes VC
is made by a continuous rather than a batch process.
PVC resins are manufactured by four polymerization processes: suspen-
sion - 79% Of total; emulsion - 13%; bulk - 6%; and solution - 2%. These
are all batch processes.
The number of PVC fabrication plants is at least several thousand
but no complete compilation by company, location, and capacity is known
to exist. For example, the B. F. Goodrich Company alone supplies finished
resins and compounds to about 2200 U. S. customer plants. Some of the
more important products are set forth in Appendix II.
12

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Appendix I discusses the opportunities for PVC substitutes at com-
parable and at higher price. In many cases there are substitutes; in ^
some cases there are no substitutes. At the present time worldwide
shortages of ethylene and the uncertainty of regulatory actions concerning
VC are creating more intensive searches for alternatives to PVC resins
in a variety of applications.
Lessons Learned from VC/PVC Experiences Relevant to Other Chemical
Problems'
Except for continuing concern over spills and accidents, Government
and industry have been rather complacent with regard to the potential
environmental threat from the high volume industrial chemicals (e.g. the
top fifty in terms of production levels). This complacency is in large
measure attributable to the relative absence of visible and uncontrolled
dangers from exposure to the chemicals during their long histories. In
addition, since each of these chemicals is manufactured by a number of
companies, firms may lack incentive to invest individual company
resources to clarify the safety aspects of their usage. Clearly, the
experience with VC -- the twenty-second leading chemical in terms of
production -- underscores the problems that can result from such com-
placency. Despite the continuing commercial importance of these high
volume chemicals, it cannot be assumed that adequate research, testing,
and related safety measures will be taken by industry, and vigorous
governmental leadership in this area seems essential.
The Agency's experience in addressing VC discharges from PVC plants
has highlighted the need for three key types of information for decision-
making and the difficulty of such decisions in the absence of adequate
information:
-- The levels of exposure to populations beyond the fenceline, with
monitoring data being the key ingredient in estimating such levels.
-- The health and environmental effects of the levels of exposure
that are encountered, drawing on available epidemiological, toxi-
cological, and ecological data from all sources.
-- The feasibility --in terms of technology, cost, and time - - oT
introducing controls to reduce discharges.
In all of these areas, concerted short-range efforts enhanced signi-
cantly the existing data base and provided critical inputs into the deci-
sion-making process.
Reliable techniques for sampling and analysis of VC were not available
and had to be developed in a short period of time. Similarly, monitoring
personnel gained their experience during the actual operations. While
each chemical problem that arises will undoubtedly have unique charac-
teristics, EPA should be able to improve its anticipatory monitoring
capability by such steps as limited stockpiling of equipment (e.g. Tedlar
bags), clarification of organizational and funding responsibilities, and
development of immediately available contractor support services.
13

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In the pesticides area, the use of VC in aerosol propellants has
emphasized the need for greater attention to the many inert ingredients
in pesticides. With regard to water pollution and to drinking water con-
tamination, EPA must extend its emphasis beyond the traditional con-
cerns with gross pollution effects and with toxic metals and pesticide
contaminants to include a wide range of other organic chemicals. Simi-
larly, in the area of air pollution, VC has awakened the entire environmental
community to the broad problem of uncontrolled and unmonitored chemical
discharges reaching neighborhoods adjacent to chemical complexes.
Also, the potential problems associated with the incineration and burial
of PVC products may be common to a variety of plastics.
Even at this late date all the commercial products using VC have pro-
bably not been identified by EPA and other Government agencies, pointing
out the need for a better means of acquiring information concerning the
uses of toxic chemicals. Finally, the problem of unreacted monomer in
PVC products has opened a broad vista of possible new concerns associ-
ated with contaminants in polymers in general.
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REFERENCES
The material presented in this Section is based largely on original
investigations and analyses conducted within the Agency. Most of
these activities are elaborated in the Appendices which also cite many
of the relevant scientific publications. However, the Appendices do
not cover the entire range of the activities of the Task Force, and
a few additional references concerning this Section are set forth below.
1.	Estimates based inter alia on informal communications with the
Department of Transportation and Manufacturing Chemists Associ-
ation.
2.	A small sampling of the available literature on the effects of PVC
inhalation follows:
Cylwik, B., "Histological and Histochemical Changes of the Liver
in Experimental Polyvinyl Chloride Pneumonoconiosis," Rocz.
Akad. Med. im. J. Marchlewskiego w Bialymstoku 17: 93-111,
1972. (Translation).
Popow, J., "influence of Polyvinyl Chloride (PVC) Dust on the
Respiratory System in the Rat,' Roczniki Akademii Med. im.
Juliana Marchlewskiego w Bialymstoku 24: 5-48, 1969 (Trans-
lation).
Szende B. et al, "Pneumoconiosis Developing after Inhalation of
Polyvinyl Chloride," Orv. Hetil. 112: 85-6, January 10, 1971.
Wooley, W. D., "Toxic Products from Plastics Materials in
Fires." Plastics & Polymers 41 (No. 156), 280-286, December
1973.
3.	Bernhard, M. and A. Zattera, "The Importance of Avoiding
Chemical Contamination for Successful Cultivation of Marine
Organisms," 1970. Helgolander Wiss. Meeresunters. 20:655-
675. Also, informal communications with Bureau of Sport Fish
and Wildlife, Department of Interior.
4.	Jernelov, A., R. Rosenberg, and S. Jensen, "Biological Effects
and Physical Properties in the Marine Environment of Aliphatic
Chlorinated By-products from Vinyl Chloride Production, " Water
Research 6: 1181-1191.
5.	See also:
Frey, H. E., "Polyvinyl Chloride Resins," Chemical Economics
Handbook, Stanford Research Institute, September 197J!
Modern Plastics, May 1974, pp. 44-46.
15

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INTERESTS AND ACTIVITIES OF GOVERNMENT AGENCIES AND INDUSTRY
EPA Regulatory Authorities
Pesticide Registration
On April 26, 1974, the Agency determined that the potential risk
associated with continued use of VC in pesticidal sprays was unjustified,
given the acceptable substitutes which were available. Therefore, on that
date Notice was given of the emergency suspension, and intent to cancel
the registrations, of all spray products containing VC for use in the
home, food handling establishments, hospitals, or other enclosed areas.
At the same time EPA requested that all existent stocks of such products
be recalled by the manufacturers (39 FR 14753). * In addition, EPA
will no longer register pesticides containing VC for indoor or outdoor
uses, and all existing registrations have now been withdrawn or amended
to substitute another propellant.
At present a few implementing details of this determination remain.
Perhaps the most important action is to insure prompt removal of the
cans containing VC from commercial channels and environmentally sound
disposal of these products, i.e. proper land disposal. EPA Regional
Offices have been actively pursuing this problem and should complete their
efforts within several months.
Air Pollution
The results of the initial monitoring efforts clearly document the fact
that neighborhoods adjacent to PVC resin manufacturing complexes are
being exposed to some level of VC air emissions. At present there is
no scientific evidence to indicate that these emissions pose an imminent
hazard to people living near these plants. However, because of the severe
health effects associated with occupational exposure to VC and the lack of
data regarding the levels at which effects begin to occur, prudence
dictates that steps should be promptly taken to reduce the emissions to
the lowest practical level. Indeed, EPA, together with state and local air
pollution authorities, has an immediate responsibility to insure that these
levels are reduced.
The key questions revolve around (a) the levels of VC concentration
that should be achieved outside the plant area, and (b) the regulatory
approach that is most appropriate, e.g. ambient air standard, per-
formance standard for new sources, or emission standard for hazardous
air pollutants. Several factors bear on such determinations in addition to
the uncertainties inherent in the health risks involved, namely: the effect
of regulations which are to be promulgated in early October by the
Department of Labor on VC levels in the workplace; the technical feasi-
bility, costs, and timing of control technologies and other approaches to
reducing emissions; and compliance schedules for the industry as a whole
and for individual plants.
*The FR citations identify the Volume and Page of the appropriate FederaI
Register announcement.
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Depending on the air emission level and/or the level of technology to
be achieved, the costs of compliance could have several effects: The
price of PVC could increase, thus opening the way for substitutes in
•some products. Some of the older plants might find it more attractive
economically to close or to replace the old technology with new. New
plants presumably would emphasize even more than at present larger
reactors with fewer requirements for entry and other innovations to re-
ducing leakage rates.
On May 31, EPA requested the manufacturers of VC and PVC resin to
provide detailed technical and economic information concerning steps
that have been and could be taken to reduce VC emissions. The in-
formation was sought under Section 114 of the Clean Air Act.
The Task Force believes that a standard based upon achieving a
specific air quality level will be very difficult to develop using currently
available data. On the other hand a performance or emission
standard, which is designed to drive down the emissions as low as
practical, and in the longer run drive technology toward more envi-
ronmentally acceptable approaches, would seem consistent with the
desirability of reducing risks from carcinogens to the minimum possible
level.
Present preliminary estimates are that emissions can be reduced by
75 percent in PVC plants and 90 percent in VC plants. Such reductions
can be achieved by employing best available control technology which
mcludes a variety of control measures that could be in place from with-
in several months to two years after promulgation of regulations. Each
plant would likely use different combinations of such measures to achieve
the necessary reductions. Currently available information indicates that
such reductions should result in ambient air levels which present no
established risk to health or welfare. The cumulative costs of the
control technology are estimated to increase the cost of PVC resin by
about four percent.
An expanded monitoring program to gain additional data at selected
plants to assist in setting an air standard is needed. Twenty-four hour
integrated samples taken during a period of several days or longer at
a number of sites around representative complexes are desirable. To
the extent possible in-plant activities should be correlated with external
readings. Since no previous monitoring was done at fabrication or co-
polymer plants, they should also be included.
Water Pollution
In view of its low solubility and volatility from water, VC is not
currently a candidate for the hazardous substances list under Section 311
(spills) of the Federal Water Pollution Control Act. Similarly, VC in
water has not been shown to present a threat to aquatic life, and there-
fore there is no basis at present to develop water quality criteria under
Section 304(a) or to consider designating VC as a toxic effluent. At the
same time, in view of the monitoring data indicating discharges up to a
level of 20 ppm of VC from at least two PVC resin plants, further
investigations of its effect, if any, on the aquatic environment seem in
order.
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The Effluent Guidelines for the Plastics Industry promulgated by EPA
cover only PVC polymerization activities and not compounding or fabrica-
tion activities. However, some of the potentially most troublesome
water effluent problems relate to the toxic materials used in the com-
pounding process.
Also, as previously mentioned, the possibility of toxic additives
in PVC products leaching into the aquatic environment is of concern.
Further clarification of these problems is needed prior to considering
regulatory action.
Solid Waste Disposed
<
Problems associated with disposal of PVC products through incinera-
tion and burial are discussed in detail in Appendix VIII. The emission
of HC1 is the only clearly identified incineration problem at present
although there are many uncertainties concerning the fate of PVC addi-
tives during the incineration process. There are well accepted environ-
mentally sound landfill techniques that should adequately contain PVC
products. At the same time there are sufficient uncertainties -- par-
ticularly with regard to additives -- m both of these areas to warrant
more detailed investigations in the months ahead. There is no evidence
at present that PVC will revert to VC during incineration or as the
result of biological or chemical activity during environmental exposure.
Disposal of the solid and semi-solid wastes from VC/PVC plants
poses many problems encountered with hazardous wastes in general. One
particular concern is the disposal of tars - -a concern that was height-
ened last year when a large number of cattle were contaminated due
to poor handling and disposal practices involving hexachlorobenzene
wastes. 1J Another problem is the possible exposure of personnel at
landfills to sludges containing up to 3000 ppm of entrapped VC which
might be escaping. Given the widespread concern at the local level
over VC/PVC activities, EPA guidance on handling such hazardous
wastes would be welcomed. In the longer term the steps called for in the
proposed Hazardous Waste Management Act might be particularly
appropriate.
Ocean Dumping
The October 1973 criteria for evaluating ocean dumping permit ap-
plications prohibit dumping of organohalogen compounds, except for
narrowly defined trace amounts, and compounds which may combine with
other substances to form organohalogens in the marine environment.
These criteria cover the principal earlier concerns over ocean disposal
of the by-products of VC/PVC manufacturing activities which were
triggered by reports of fish kills in the North Sea from disposal of
tars and of the buildup of organohalogen compounds near Puerto Rico.
Unfortunately, earlier ocean disposal practices for tars in the Car-
ibbean also have had adverse effects on marine life. 2/
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Drinking Water
Currently there are no data on VC concentrations in community water
supplies, primarily because no one has ever looked for VC. Conceivably,
it could be present in drinking water. Possible sources are PVC poly-
merization plants just upstream from water intakes and from PVC prod-
ucts used in the distribution system such as PVC pipe and storage tank
liners.
Monitoring a few selected water supplies should provide a basis for
assessing VC concentrations that may be found in water supplies from
both industrial pollution and product contamination. Adequate sampling
and analytical procedures will of course be required to insure the
soundness of the results. The results should be used to determine the
need for additional sampling and possible research requirements.
Proposed Toxic Substances Control Act
An important authority which is currently missing is the Toxic Sub-
stances Control Act. The requirements for reportmg of industrial pro-
duction data evisaged in the Act would enhance knowledge of the types
and extent of different uses of VC. The testing provision would be the
basis to obtain much needed data -- and particularly data on toxicity and
persistence --for assessing the risks associated with low concentration
levels of VC, including those levels that are likely to persist beyond
the workplace. The proposed regulatory provisions would provide a
mechanism for addressing those products using VC not now subject to
regulation under other laws. Also, if considered appropriate, steps
might be taken to limit the amount of unreacted VC in certain PVC
products which could eventually migrate out of these products to pose an
unnecessary risk.
Supporting Research Activities
As a component of the national effort to clarify the health risks
associated with VC, the Agency plans to support a toxicological effort
at the University of Cincinnati. These studies are designed to determine
the effects of VC on the developmg fetus, to determine changes of VC
toxicity caused by nutritional imbalance and interactions with other
common chemicals, and to develop cell culture techniques for rapid
screening of the oncogenic potential of VC and related compounds.
Also, epidemiological studies of neighborhoods near PVC activities
are scheduled to complement related efforts of other Government agen-
cies.
Regulatory Interests of Other Agencies
Aerosol Sprays
Early this year evidence indicated that some supplies of hair sprays
containing VC were still on the market, and the Food and Drug Adminis-
tration (FDA) requested that all known manufacturers recall these
19

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supplies. In early April, three manufacturers initiated recalls for hair
spray and other drug and cosmetic aerosol products. On April 22, FDA
published a notice of proposed amendments to the Federal Food, Drug
and Cosmetic Act concerning the use of VC as an ingredient, including
propellant, of (a) aerosol drug products, and (b) cosmetic aerosol prod-
ucts (39 FR 14215). At the same time, but in a separate notice, FDA
requested a list of all marketed drug products containing VC as an ingre-
dient or packaged in containers of or lined with PVC (39 FR 14238). On
August 26, FDA published regulations which (a) banned the use of VC in
cosmetic aerosol products, and (b) required a new drug application as
a condition for marketing drug aerosol products when VC is used as an
ingredient (39 FR 30830).
The Consumer Product Safety Commission has undertaken two steps.
An information gathering process was initiated in May to determine the
specific aerosol products containing VC which are being or have been used
(39 FR 16511). The Commission has identified more than 25 aerosol
products containing VC and is currently continuing its analyses. On
August 21, the Commission promulgated a regulation, effective from
October 7, banning as hazardous substances "self-pressurized products
intended or suitable for household use that contain VCM as an ingredient
or in the propellant" (39 FR 30114).
Worker Protection
The Occupational Safety and Health Administration (OSHA) of the De-
partment of Labor, responsible for worker safety, determined that VC
levels exceeding 50 ppm in the workplace present a hazard and on April 5
set an emergency temporary standard at that level (39 FR 12342). To
initiate the process for setting a permanent standard, on May 10, OSHA
proposed lowering the standard to the level of detection, defined at 1 ppm
plus or minus 0.5 ppm (39 FR 16896). Public hearings to gather infor-
mation for a permanent standard and to assist OSHA in making a final
judgement as to the adverse effects of VC and the appropriate levels of
exposure to workers were held in June and July. The final standard is to
be set by October 5, 1974.
Much of the information being developed by OSHA is of direct rele-
vance to EPA concerns, and particularly concerns over an air standard.
Even more importantly the regulatory action taken by OSHA within the next
several months can have a profound effect on the need for and character of
action by EPA. If OSHA uses health data as the basis for its standard,
it is important that the interpretation of the data not be inconsistent
among agencies. Also, OSHA should be encouraged to recommend control
techniques which will not simply vent VC to the environment external to
the workplace.
Unreacted VC Monomer in PVC Products
Early last year reports were received of possible migration of VC to
distilled spirits and wines packaged in PVC bottles under an experimental
program authorized by the Department of Treasury. Subsequent inves-
tigations by FDA confirmed that residual VC had migrated from the PVC
20

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into various distilled spirits and wines. Since there were no available
toxicological studies supporting a safe level of VC in food, FDA published
a proposal which in essence would preclude the use of PVC resin in con-
tact with alcoholic food (39 FR 12931). At the same time, the Department
of Treasury withdrew the approval of the experimental use of PVC bottles
to contain distilled spirits. Since there was no indication, at that time,
that VC migration occurred from PVC in contact with non-alcoholic foods,
FDA proposed a regulation which identified criteria for safe use under
the prior sanction (38 FR 12931). Recently, however, FDA has received
data confirming VC migration from PVC packaging into a variety of foods
and currently is considering limitations on the use of PVC in food packag-
ing.
The Consumer Product Safety Commission has not taken a position on
unreacted monomer in consumer products.
Transportation Handling
The problems associated with VC have heightened the concern of the
Department of Transportation (DOT) as to whether any changes in its
regulations are warranted since some commercially important chemicals
have been identified as carcinogens. A major question is whether a single
exposure to these chemicals can cause cancer. At present, DOT is con-
sidering the desirability of changes in labeling requirements and/or
packagmg requirements for carcinogens but has not yet reached a con-
clusion.
In July 1974, DOT published (a) proposals to amend the bulk dan-
gerous cargoes regulations for the carriage of VC (39 FR 26752), and (b)
a requirement for protective head shields on uninsulated tank cars carry-
ing liquefied flammable compressed gases such as VC (39 FR 27572). In
a related action in August, DOT proposed amending the requirements for
handling freight cars carrying hazardous materials to include those pla-
cards as "Dangerous" (39 FR 29197).
Related Research Activities
The Center for Disease Control (CDC) and the National Institute of
Occupational Safety and Health (NIOSH) are maintaining a nationwide
surveillance network of all cases of angiosarcoma of the liver which have
been reported since 1965. For each case identified, the health history
of the individual will be reviewed and analyzed to determine if there was
any connection with VC or PVC plants. CDC/NIOSH are also conducting
studies to determine if other cancers and other mortality causes are
associated with exposure to VC. In these studies, pathological informa-
tion will be obtained from hospitals. A CDC survey among meat wrappers
in Houston, Texas, should determine if chemicals produced upon combus-
tion of PVC film may be implicated in "meat wrappers asthma. "
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CDC/NIOSH are conducting a comprehensive epidemiological survey
of workers from 11 polymerization and fabricating plants. Employee
medical records are being subjected to intense screening to determine
the scope and magnitude of VC effects. Hospital data obtained in this
study are being sent to the angiosarcoma network. NIOSH is also
planning studies to determine the levels of exposure at fabricating
plants and to determine if cosmeticians exposed to VC from aerosol
hair sprays have had any cases of liver angiosarcoma.
The Consumer Product Safety Commission plans to support rodent
experiments to determine the effects over a lifetime of single dose and/or
intermittent exposures of VC at several dose levels. Reproductive,
mutagenic, and teratogenic effects may be considered.
The National Institute of Environmental Health Sciences (NIEHS) has
taken an active role in bringing together interested Government agencies,
industry, and the academic community to begin to assess the public health
implications of a broad range of chemicals used in the plastics industry.
An initial meeting in Pinehurst, North Carolina, from July 29 to 31 was
designed to set the stage for a continuing effort to sort out research pri-
orities within Government and industry, as well as to highlight the types
of considerations that should surround regulatory actions in this field.
The National Cancer Institute is providing pathology services (human
and experimental animal) and in collaboration with the Armed Forces
Institute of Pathology is establishing a case registry for VC associated
diseases.
The National Bureau of Standards (NBS) is conducting research on the
development of calibration methods for EPA. This includes preparation
of standard VC air mixtures in the ppm range and of charcoal sampling
tubes with known VC loadings. NBS is also domg research to develop
more sensitive techniques for the detection of VC in the atmosphere.
Role of Industry
During the past several months industry has cooperated extensively
with the Task Force and with individual Agency offices in the assessment
of problems associated with VC/PVC activities. Summarized below are
some of the areas of greatest concern involving major industrial commit-
ments.
Reducing Disharges of VC and Other Toxic Chemicals
There is no doubt that industry has taken and can continue to take a
variety of immediate steps at relatively little cost to reduce the VC
losses at VC and PVC polymerization facilities. During the past few
months many plants have already started to tighten maintenance and
operating procedures; other plants are installing improved pumps, seals,
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and disconnect devices; while still other plants are introducing more
significant process changes. One company is reportedly spending $3
million to tighten the processes at a single PVC facility; another company
reports that it has 100 engineers working to introduce modifications that
will dramatically cut VC losses at several plants.
In the longer run significantly different approaches to the polymeri-
zation process may be in order. Clearly, the opening of the reactor
kettles is a major source of discharges, and a continuous rather than
batch process should be considered as an example of a design change to
reduce VC losses. In the batch process the trend toward larger ket-
tles will probably accelerate. At the same time some companies may
elect to mark time with regard to major modifications or significant new
departures until the initial OSHA and EPA regulatory approaches become
clearer.
A number of other toxic chemicals are also associated with VC/PVC
activities. As previously mentioned the disposal of tars and the dis-
charges of toxic metals at PVC compounding plants are of particular
concern. A number of the troublesome chemicals may be better known to
industry than Government, and industry should not delay in taking correc-
tive actions even though these chemicals have not yet been designated for
control by the Government.
Medical Surveillance
Clearly, VC concerns have triggered extensive medical surveillance
programs of VC and PVC workers throughout the industry. These pro-
grams should become routine to cover a far broader swath of chemicals
at VC/PVC and other chemical complexes. Published analyses of the
results of such programs would be very valuable to EPA and other
agencies.
In addition, industry has a responsibility to support medical surveil-
lance programs for residents in neighborhoods adjacent to VC/PVC
complexes and other types of plants releasing chemicals into these neigh-
borhoods. The character of such surveillance will obviously depend on
the type of chemicals involved and the arrangements that can be worked
out by industry with local health authorities.
Fenceline Monitoring for Chemical Discharges
Traditionally, the chemical industry has conducted very little fence-
line monitoring not required by Federal, state, or local agencies to de-
termine the chemical discharges leavmg plant property. During the past
several months, however, monitoring for VC has become a concern, and
hopefully this concern will rapidly spread to other chemicals. Clearly,
a plant manager should know the chemical mix of the air emissions
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drifting over the plant fence into nearby neighborhoods. Similarly, he
should be fully aware of the chemical cross section of his liquid and solid
waste streams. Thus, a far more intensive physical monitoring effort on
the part of industry is needed -- monitoring not only for gross pollution
(e.g., biological oxygen demand, chemical oxygen demand, total suspend-
ed solids) but for individual chemicals as well, including VC and related
chlorinated hydrocarbons.
Toxicological Testing of VC
Until the recent revelations concerning the relationship of VC to
angiosarcoma of the liver, the efforts of U. S. industry to clarify the
chronic toxicity of VC were nearly negligible, despite the commercial
importance of VC. The industrial studies of the early sixties and the
recent Manufacturing Chemists Association ( MCA) toxicological study on
behalf of a number of companies have not been adequate, in terms of
direction, scope, or quality. Even the additional toxicological studies
which have been proposed by MCA calling for animal exposures down to
1 ppm of VC may not be sufficient if the objective is to understand in
some detail the biological effects from the types of dose levels likely
to be found in the workplace and beyond. This proposed effort, while
important, is but a small step toward a very complicated problem. Also,
a number of experts have expressed concern over the design and statis-
tical significance of the studies as currently planned.
Testing for Persistence and Environmental Fate and Effects of VC
and PVC
A related area is industry's responsibility to clarify the environmental
fate and effects of the chemicals it manufactures, and in this case the
behavior of VC in water and air (including degradation products) and the
fate and effects of products containing PVC m soil and water. This is
a new area which has not attracted sufficient attention from industry but
which is of crucial importance in assessing environmental impacts of
chemical activities. Governmental leadership will probably be essen-
tial in helping to point the way as to the types of tests and analyses that
are the most appropriate.
Testing for Levels of Unreacted Monomer in PVC Resins and PVC
Products
In view of the likelihood that FDA will limit the levels of unreacted VC
allowed in PVC food packaging, industry has recently accelerated efforts
to analyze the levels of VC that are present in PVC resin used for food
packaging and in the packaging itself. This relatively inexpensive pro-
cedure should be extended to other types of products as well. It is par-
ticularly important that the manufacturers of resin, who in general are
well equipped to carry out the necessary sampling and analysis, advise
their customers (i.e., the fabricators) of the quality of the resin in
terms of unreacted monomer in addition to the usual quality criteria. The
fabricators in turn have a responsibility to be aware of the levels of
unreacted monomer that persist in the products that eventually reach
the marketplace.
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REFERENCES
The technical information presented in this Section is based princi-
pally on informal communications with the concerned EPA offices,
other Federal agencies, and industrial representatives. Two relevant
publications not cited in the Appendices are identified below:
1.	Environmental Contamination from Hexachlorobenzene, Office of
Toxic Substances, Environmental Protection Agency, July 20, 1973.
2.	Aubert, M., "Effect on the Marine Environment of the Combustion
at Sea of Some Industrial Waste", Center of Biological Studies and
Research and of Oceanographic Medicine (C. E. R. B. O. M.), Nice,
France, January 1974.
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RECOMMENDATIONS
This Section sets forth the recommendations of the Task Force
concerning steps that should be taken by the Agency and steps that
the Agency should encourage industry to take in the near term to (a)
help clarify and reduce the risks associated with VC/PVC activities, and
(b) take full advantage of our experiences with these chemicals in ad-
dressing other chemicals.
Regulatory and Directly Supportive Actions by EPA
Recommendation #1:
An air standard for VC should be established as soon as practical
under the Clean Air Act for VC and PVC polymerization plants
and, if warranted by further investigations, for PVC fabrication
plants. The Agency should determine the ambient levels that are
likely to be achieved and, to the extent possible, the health risks
associated with such levels
Recommendation #2:
Additional ambient air monitoring should be carried out to support
regulatory action under the Clean Air Act. These efforts should
include sampling at a number of carefully selected sites around a
few VC, PVC polymerization, and PVC fabrication plants. The moni-
toring measurements made at these facilities should be correlated
with specific m-plant activities such as reactor venting.
Recommendation #3:
More detailed material balance studies should be conducted, in
cooperation with industry, at a few VC and PVC polymerization
plants. Specific VC leakage points should be more clearly identified,
and attempts should be made to correlate the magnitude and timing
of the estimated losses with the levels of VC detected in a monitoring
program.
Recommendation #4:
A program should be initiated to determine whether and to what
extent background levels of VC are present in the ambient air --
indoors, and outdoors--due to the presence of PVC products.
Recommendation #5:
A limited VC monitoring program should be undertaken of drinking
water supplies which might be contaminated from VC discharges
from nearby PVC plants. Prior to undertaking the program sampling
and analysis procedures should be carefully reviewed and refined as
necessary.
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Recommendation #6:
A study should be conducted to determine the amount of VC migra-
ting out of PVC products used in water distribution systems--such
as PVC pipe or storage tank liners. Prior to undertaking the pro-
gram sampling and analysis procedures should be carefully reviewed
and refined as necessary.
Recommendation #7:
To insure comparability of results between laboratories EPA should
further develop its interim method into a standardized method for
monitoring levels of VC. Concurrently, the Agency should also
investigate the feasibility of developing continuous air monitoring
devices.
Recommendation #8:
Monitoring and bench-scale studies should be conducted around
industrial storage and disposal sites and municipal disposal sites
to determine the types and quantities of toxic substances leached
or discharged out of (a) semi-solid and solid wastes generated by
VC/PVC facilities, or (b) PVC products discarded by consumers.
If these studies indicate that there could be a health or environ-
mental hazard, guidelines should be developed to control the storage
and disposal of these wastes.
Recommendation #9:
The responsible Office should continue to support currently planned
VC toxicological studies.
Recommendation #10:
The responsible Office should continue to support currently planned
VC epidemiological studies.
Recommendation #11:
More intensive studies should be conducted on the behavior of VC in
the atmosphere and in the aquatic environment, and particularly on its
degradation products and related chemical reactions. These studies
should be supported by both industry and Government.
Recommendation #12:
The industries covered by the Effluent Guidelines for the Plastics
Industry promulgated under the Federal Water Pollution Control
Act should be expanded beyond the production of resins to include
the compounding and directly associated activities that result in
discharges into the water of toxic metals and other chemicals of par-
ticular concern.
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Recommendation #13:
Enforcement efforts, including spot checks of manufacturers,
distributors, and retail outlets, should continue to be pursued
vigorously to insure that pesticidal sprays containing VC as a
propellant are removed from the channels of trade as rapidly
as possible.
Recommendation #14:
Regional, State, and local authorities should be kept fully
informed of Agency efforts under the Clean Air Act and other
authorities. As the Federal approach becomes clearer, they
should be encouraged to undertake supportive actions as appro-
priate.
Recommendation #15:
The Agency should build on the experience gained in respond-
ing to the problems associated with VC in strengthening its
organizational, manpower, and contractor resources to anticipate
and respond to similar situations involving other chemicals.
Readily available information on the handling of VC should be
made available to the Regional Offices to assist them in respond-
ing to rail or barge accidents resulting in the release of VC.
Recommendation #16:
Laboratory procedures for safe handling of VC should be developed
and distributed to all EPA laboratories. Consideration should be
promptly given to how such procedures can most effectively be
developed for a number of carcinogens that are likely to be of con-
cern to the Agency.
Recommendation #17:
Should the Toxic Substances Control Act be enacted, prompt
consideration should be given to the need for and feasibility of
(a) requirements for industrial testing of the toxicity of VC at
low ambient levels and the persistence of VC in different media,
and (b) limitations on the levels of unreacted VC monomer in
selected PVC products.
Recommendation #18:
The Agency should continue its leadership role in bringing together
the interested Federal agencies to exchange views on regulatory
actions, supporting activities, and research projects directed to
problems associated with VC and PVC. In addition, an appropriate
interagency mechanism should be developed to address a broader
spectrum of potential problems associated with the plastics
industry.
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Recommendation #19:
EPA should exercise leadership in stimulating Governmental and
industrial efforts to analyze in depth the other high volume
chemicals (e.g., top 50 in terms of pounds of production) to
identify those which deserve additional testing or controls to
clarify or reduce potential environmental problems.
Steps by Industry
Recommendation #20:
All possible steps to tighten up operating and maintenance pro-
cedures to reduce VC and PVC losses at VC, PVC polymeri-
zation, and PVC fabrication facilities should be taken promptly
without waiting for further Governmental regulatory actions.
R&D efforts should be expanded to develop new approaches to
reduce losses during polymerization, such as continuous flow
systems.
Recommendation #21:
Each VC and PVC resin facility, and indeed chemical complexes
in general, should have up-to-date information on the character
and extent of the chemical pollutants that are leaving the plant
property as air, water, or solid waste discharges or degradation
products. A systematic monitoring program operated by industry
at the fence line and beyond will in many cases be essential to
ascertain the nature of the pollutants reaching nearby neighbor-
hoods.
Recommendation #22:
The levels of unreacted VC monomer in all grades of PVC resin
should be routinely ascertained and purchasers of the resin should
be advised accordingly. Also, analyses of the rates of release
of VC monomer from PVC products should be expanded.
Recommendation #23:
The Manufacturing Chemists Association should, in consultation
with interested Government agencies, carefully reevaluate its
planned VC toxicological experiments at low doses to insure
that the design is (a) statistically reliable, and (b) relevant to the
ambient air concerns of EPA.
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