ECAO-CIN-0007
United States August, 1988
» ,v-.-,'.. Environmental Protection Revised April, 1991
•<*£-•. ' ^3ftU- A«enc*
Research and
Development
i .
t DRINKING WATER CRITERIA DOCUMENT FOR
HEXACHLOROCYCLOPENTADIENE
O
Prepared for
OFFICE OF WATER
Prepared by
Environmental Criteria and Assessment Office
Office of Health and Environmental Assessment
U.S. Environmental Protection Agency
Cincinnati, OH 45268
HEADQUARTERS LIBRARY
ENVIRONMENTAL PROTECTION AGENCY
WASHINGTON, D.C. 20460
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DISCLAIMER
This document has been reviewed In accordance wHh the U.S. Environ-
mental Protection Agency's peer and administrative review policies and
approved for publication. Mention of trade names or commercial products
does not constitute endorsement or recommendation for use.
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FOREWORD
Section 1412 (b)(3)(A) of the Safe Drinking Water Act, as amended 1n
1986, requires the Administrator of the Environmental Protection Agency to
publish maximum contaminant level goals (MCLGs) and promulgate National
Primary Drinking Water Regulations for each contaminant, which, 1n the
judgment of the Administrator, may have an adverse effect on public health
and which 1s known or anticipated to occur 1n public water systems. The
MCLG 1s nonenforceable and 1s set at a level at which no known or antici-
pated adverse health effects 1n humans occur and which allows for an
adequate margin of safety. Factors considered 1n setting the MCLG Include
health effects data and sources of exposure other than drinking water.
This document provides the health effects basis to be considered 1n
establishing the MCLG. To achieve this objective, data on pharmacoklnetlcs,
human exposure, acute and chronic toxlclty to animals and .humans, epidemi-
ology and mechanisms of toxldty are evaluated. Specific emphasis 1s placed
on literature data providing dose-response Information. Thus, while the
literature search and evaluation performed 1n support of this document has
been comprehensive, only the reports considered most pertinent In the deri-
vation of the MCLG are cited In the document. The comprehensive literature
data base 1n support of this document Includes Information published up to
1985; however, more recent data may have been added during the review
process. Editorial changes were also made 1n 1991 when this document was
finalized.
When adequate health effects data exist, Health Advisory values for less
than lifetime exposures (1-day, 10-day and longer-term, -10% of an
Individual's lifetime) are Included 1n this document. These-values are not
used 1n setting the MCLG, but serve as Informal guidance to municipalities
and other organizations when emergency spills or contamination situations
occur.
Tudor Davles, Director
Office of Science and
Technology
James Elder, Director
Office of Ground Water
and Drinking Water
111
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DOCUMENT DEVELOPMENT
Linda R. Papa, Document Manager
Environmental Criteria and Assessment Office, Cincinnati
U.S. Environmental Protection Agency
Scientific Contributors
David J. Relsman
Environmental Criteria and
Assessment Office, Cincinnati
U.S. Environmental Protection Agency
James WHhey, Author of Chapter III and Reviewer
Environmental Health Directorate
Bureau of Chemical Hazards
Tunney's Pasture
Ottawa, Ontario K1A-OL?
Scientific Reviewers
W. Bruce Pelrano
Environmental Criteria and
Assessment Office, Cincinnati
U.S. Environmental Protection Agency
Annette M. Gatchett
Environmental Criteria and
Assessment Office, Cincinnati
U.S. Environmental Protection Agency
C. Ralph Buncher
Department of Environmental Health
University of Cincinnati
Cincinnati, OH
Fumlo Matsumura
Director, Pesticide Research Center
Michigan Stale University
East Lansing, MI
Charles 0. Abernathy
Yogendra Patel
Health Effects Branch
Office of Drinking Hater
U.S. Environmental Protection Agency
Washington, DC
Larry Valcovlc
Reproductive Effects Assessment Group
Office of Health and Environmental
Assessment
U.S. Environmental Protection Agency
Washington, DC
Paul White
Exposure Assessment Group
Office of Health and Environmental
Assessment
U.S. Environmental Protection Agency
Washington, DC
Arthur Ch1u
Carcinogen Assessment Group
Office of Health and Environmental
Assessment
U.S. Environmental Protection Agency
Washington, DC
Editorial Reviewer
Judith Olsen
Environmental Criteria and
Assessment Office, Cincinnati
U.S. Environmental Protection Agency
1v
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TABLE OF CONTENTS
Page
I. SUMMARY J-l
II. PHYSICAL AND CHEMICAL PROPERTIES II-l
ANALYSIS 11-10
SUMMARY 11-16
III. TOXICOKINET1CS 111-1
INTRODUCTION III-l
INTRAVENOUS ROUTE ... III-l
ORAL ROUTE '. III-3
INHALATION ROUTE. ' II1-8
PERCUTANEOUS ROUTE 111-13
COMPARATIVE STUDIES -.. *'-... 111-13
SUMMARY .......... 111-14
- IV. HUMAN EXPOSURE IV-1
(To be provided by the Office of Drinking Water)
V. HEALTH EFFECTS IN ANIMALS V-1
OVERVIEW V-1
ACUTE TOXICITY ; : V-1
SUBCHRON1C AND CHRONIC TOXICITY V-7
MUTAGENICITY. V-15
CARCINOGEN1CITY V-16
TERATOGENICITY V-17
SUMMARY V-18
VI. HEALTH EFFECTS IN HUMANS. VI-1
ACUTE EXPOSURE STUDIES Vl-1
EPIDEMIOLOGIC STUDIES VI-8
SUMMARY VI-10
VII. MECHANISMS OF TOXICITY VI1-1
SUMMARY Vll-2
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TABLE OF CONTENTS (cent.)
Page
VIII. QUANTIFICATION OF TOX1COLOGIC EFFECTS V11I-1
INTRODUCTION VI11-1
NONCARCINOGENIC EFFECTS VIII-6
QUANTIFICATION OF NONCARCINOGENIC EFFECTS VI1I-11
Derivation of 1-Day HA VIII-11
Derivation of 10-Day HA VIII-12
Derivation of Longer-Term HA ... VII1-13
Assessment of Lifetime Exposure and Derivation of DUEL . VIII-14
CARCINOGENIC EFFECTS V11I-15
EXISTING GUIDELINES, RECOMMENDATIONS AND STANDARDS VII1-15
Occupational Standards -."... VI11-15
Transportation Regulations .... VI1I-17
Solid Waste Regulations V1II-17
Food Tolerances V1I1-17
Water Regulations : VI11-17
Air Regulations VII1-18
Other Regulations V1II-18
SPECIAL GROUPS AT RISK V1II-19
SUMMARY VI11-19
IX. REFERENCES IX-1
v1
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LIST OF TABLES
No. TUIe Page
II-l Identity of Hexachlorocyclopentadlene .... 11-2
II-2 Physical Properties of Hexachlorocyclopentadlene 11-3
11-3 Characteristics of the Porapak* T Collection System . . . 11-12
11-4 Optimized GC Analytical Procedure for HEX 11-13
II1-1 ExtractabllUy of [J«C] HEX and Radioactivity Derived
from Saline and Various Biological Preparations . . .-. . . 111-12
»
III-2 Disposition of Radioactivity Expressed as Percentage
of Administered Dose from 14C-HEX 1n Rats Dosed by
Various Routes . . . . 111-15
111-3 Fate of Radiocarbon Following Oral, Inhalation and
Intravenous Exposure to 14C-HEX In Rats Expressed
as Percentage of Administered Dose 111-16
I1I-4 Distribution of HEX Equivalents 1n Tissues and Excreta
of Rats 72 Hours After Oral, Inhalation and Intravenous
Exposure to 1«C-HEX . 111-17
V-l Acute ToxUHy of HEX V-2
V-2 Subchronlc Toxlclty of HEX V-8
V-3 Toxlcologlcal Parameters for Mice and Rats Administered
Technical Grade HEX In Corn 011 for 91 Days : V-10
Vl-1 Symptoms of 145 Wastewater Treatment Plant Employees
Exposed to HEX (Louisville, KY, March 1977) ... .^. ... VI-4
Vl-2 Abnormalities for 18 of 97 Cleanup Workers at
the Morris Forman Treatment Plant t Vl-5
VI-3 Overview of Individual Exposure - Symptomatology
1 Correlations at the Morris Forman Treatment 'Plant Vl-6
\
VI-4 Hepatic Profile Comparison of Hardeman County:
Exposed Group (November 1978) and Control Group ...... VI-9
VIII-1 Summary of HAs and DHEL for NoncardnogenU Effects ..... VI1I-16
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LIST OF ABBREVIATIONS
CDC
DMSO
OWEL
ECO
GC/MS
GI
KA
HEX
J«C-HEX
HPLC
l.d.
1.v.
LAQL
LOAEL
LOEL
Mg
NAS
NIOSH
NOAEL
NOEL
NTP
OCCP
Radlolabeled carbon dioxide
Centers for Disease Control
Dlmethylsulfoxlde
Drinking water equivalent level
Electron capture detection
Gas chromatography/mass spectrometry
Gastrointestinal
Health advisory
Hexachlorocyclopentadlene
Radlolabeled carbon-14 hexachlorocyclopentadlene
High performance liquid chromatography
Internal diameter
Intravenous
Lowest analytically quantifiable level
Lethal dose to. 5054 of recipients
Lowest-observed-adverse-effect level
Lowest-observed-effect level
Hegagrams equivalent to 1 metric ton
National Academy of Sciences
National Institute for Occupational Safety and Health
No-observed-adverse-effect level
No-observed-effecl level
National Toxicology Program
Octachlorocyclopentad1ene
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RfO
S.D.
SMR
sp. gr,
SRI
LIST OF ABBREVIATIONS (cont.)
Reference dose
Standard deviation
Standard mortality ratio
Specific gravity
Southern Research Institute
1x
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I. SUMMARY
Hexachlorocyclopentadlene (HEX) Is an unsaturated, highly reactive,
chlorinated cyclic hydrocarbon of low water solubility. HEX 1s a chemical
Intermediate used 1n the manufacture of chlorinated pesticides and flame
retardants with no end uses of Us own. The major source of environmental
contamination by HEX 1s the aqueous discharge from .production facilities,
with small concentrations present as contaminants 1n commercial products
made from It. However, HEX 1s not frequently found 1n the environment and,
even when present, It 1s rapidly degraded. The degradation products of HEX
have not been Identified. Because of recent controls on environmental
emissions, current environmental exposure to HEX 1s extremely low. From
time to time. Isolated Instances, such as the sewer system disposal of HEX
wastes 1n 1977 In Louisville, KY, and the cleanup of a large waste disposal
site 1n Michigan 1n 1983, have brought this chemical to the forefront of
environmental news.
HEX Is not readily absorbed by epithelial tissues because H Is highly
reactive, especially with the contents of the GI tract. HEX Is moderately
toxic when given orally, but has been estimated to be 100 times more toxic
when Inhaled. The data base for the long-term toxlclty of HEX Is very
limited. A chronic Inhalation bloassay Is being conducted by the NIP and
may provide data regarding any carcinogenic potential! of HEX.
Several literature reviews on the health and environmental effects of
HEX are available. Although each of these reports varies 1n scope and
03610
08/24/88
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emphasis, a large amount of the scientific knowledge about HEX 1s reviewed
1n these documents. To avoid unnecessary duplication, the previously
reviewed material will not be considered at great length, except where 1t
Impinges directly upon present critical considerations.
.HEX Is currently produced by only one company 1n the United States,
Velslcol Chemical Corporation. Production data are considered proprietary;
however, estimates show that 8-15 million pounds/year are produced. HEX can
enter the environment as an Impurity/contaminant 1n some of the products
using HEX as an Intermediate or can be released during ttie-manufacture of
products requiring HEX. The total estimated environmental release of HEX 1s
11.9 Mg (13.1 tons). Because of Its physical and chemical characteristics,
only a small amount of this total can be expected to persist. In water, HEX
may undergo photolysis, hydrolysis and blodegradatlon. In shallow, standing
water, HEX has a photolytlc half-life of <1 hour, while 1n deeper waters
where photolysis Is precluded, HEX may persist for several days. HEX 1s
known to be quite volatile; however, the rate of volatilization from natural
waters can be Influenced by turbulence and adsorption onto sediments.
In animal studies, the absorption of unchanged HEX 1s reduced because of
Us reactivity with membranes and tissues, and especially with the contents
of the Gl tract. Radioactivity from **C-HEX 1s retained by the kidneys
and livers of animals for at least 12 hours after oral or Inhalation
dosing. Absorbed HEX 1s metabolized and rapidly excreted, predominantly In
the urine and feces with <1X of the HEX found 1n expired air. The
metabolites of HEX have not been Identified.
03610 1-2 08/30/88
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Subchronlc oral dosing studies have been conducted on rats and mice for
91 days. At 38 and 75 mg/kg/day levels In rats and mice, respectively,
adverse effects were noted, which Included Inflammation and hyperplasla of
the forestomach and nephrosls. In vitro test results from three species
have not shown HEX to be a mutagen. HEX was also Inactive In the mouse
dominant lethal assay.
Limited data are available on the health effects In humans from exposure
to HEX. Isolated Instances have occurred that show Inhalation exposure to
HEX causes severe Irritation of the eyes, nose, throat and lungs. Human
exposures from other routes have elicited effects that Include short-term
Irritations, with recovery after cessation of exposure. The long-term
health effects of continuous low-level and/or Intermittent acute exposure In
humans are not known.
The data base 1s neither extensive nor adequate for assessing the car-
clnogenlcHy of HEX. The NTP has recently completed:a subchronlc Inhalation
animal study and will begin a lifetime animal Inhalation bloassay using both
rats and mice. Several epIdemlologU studies were dted In the literature;
however, no Increased Incidences of neoplasms at any site were reported that
could be related to HEX. Accordingly, VelsUol Chemical Corporation has
on-going programs and follow-up studies 1n order to study the long-term
effects of HEX exposure. A judgment of carcinogenic potential will be
deferred until the results of the NTP long-term bloassay are available.
Using the International Agency for Research on Cancer (IARC) criteria, the
available evidence would place HEX 1n the Group 3 category. According to
the U.S. EPA Guidelines for Carcinogen Risk Assessment, based upon present
03610
1-3
08/24/88
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data, this chemical 1s classified 1n the Group D category. A U.S. EPA
carclnogenldty Group 0 classification was verified by the CRAVE Work Group
on 10/05/89. This classification Indicates that the available data base Is
Inadequate to assess the carcinogenic potential of this substance.
Using a gavage study on rats, the 1-day health advisory (HA) for
children has been calculated to be 15 mg/i. The 10-day HA was derived
using a repeated-dose toxldty study on both rats and mice, and for children
the level 1s recommended to be 2 mg/l.
The longer-term HAs were developed from the SRI 13-week study also used
for the derivation of the Drinking Water Equivalent Level (DWEL). The
recommended longer-term HA for adults 1s 3 mg/l and for children the
longer-term HA Is 0.7 mg/l. The DWEL Is 0.3 mg/s,, which 1s calculated
using an RfD of 0.007 mg/kg bw/day (verification date 10/09/85} based on a
NOAEL of 10 mg/kg for absence of adverse effects In rats.
03610 1-4 06/11/91
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II. PHYSICAL AND CHEMICAL PROPERTIES
Hexachlorocyclopentadlene (HEX, HCCPD, C-56) Is a nonflammable liquid
with a characteristically pungent, musty odor. The pure compound 1s a pale
yellow but Impurities may produce a greenish tinge (Stevens, 1979). HEX 1s
a dense liquid with a specific gravity of 1.7019 iat 25°C and low water
solubility (0.805-2.1 mg/l) (U.S. EPA, 1978). Studies by Nalshteln and
Llsovskaya (1965) have Indicated an odor threshold for HEX of 0.002 mg/i
and a "taste" threshold of 0.007 mg/l. HEX 1s a liquid with a high
boiling point (239°C) and a vapor pressure of 0.08 mm Hg at 25'C. Table
II-l presents Information on the Identity of the chemical while Table 11-2
t
lists Us physical properties.
HEX 1s stable under moisture-free and Iron-free conditions (Stevens,
1979). Chemically, HEX 1s a highly reactive dlene that readily undergoes
addition and substitution reactions and^ also participates In Diels-Alder
reactions (Ungnade and McBee, 1958). The products of the Diels-Alder
reaction of HEX are generally 1:1 adducts containing a hexachlorobicyclo-
(2,2,1)heptene structure; the monoene derived part of the adduct is nearly
always In the endo-posltion. rather than the exo-posltlon (Stevens, 1979).
Look (1974) also reviewed the formation of HEX adducts of aromatic compounds
and the by-products of the Diels-Alder reaction. Two early reviews of the
chemistry of HEX were published by Roberts (1958) and Ungnade and McBee
(1958).
HEX has an absorption band In the ultraviolet range at 322 and 3?3 nm
(log e = 3.17) 1n ethanol (U.S. EPA, 1978). Th1s: absorption band reaches
03620
H_-| - 04/12/91
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TABLE II-l
Identity of Hexachlorocyclopentadlene*
Identifying Characteristic
Name/Number/Structure
IUPAC Name:
Trade Names:
Synonyms:
CAS Number
CIS Accession Number:
Molecular Formula:
Molecular Structure:
l,2,3,4,5,5'-Hexachloro-lt3-cyclopentad1ene
C56; HRS 16S5; Graphlox
Hexachlorocyclopentadlene
Perchlorocyclopentadlene
HEX
HCPD
HCCP
HCCPD
C-56
HRS 1655
Graphlox
77-47-4
7800117
C1,
Cl
Cl
*Source: U.S. EPA, 1984
03620
II-2
10/16/85
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TABLE 11-2
Physical Properties of Hexachlorocyclopentadlene
Property
Value/Description
Reference
Molecular weight
Physical form (25°C)
Odor
Odor threshold: air
water
Electronic absorption
maximum [(In 50%
acetonHr lie-water)]
Solubility 1n water
(mg/i)
Organic solvents
Vapor density (air
Vapor pressure
(mm Hg, °C)
Specific gravity
Melting point (°C)'
1)
Boiling point (°C)
Conversion Factor
272.79
Pale yellow liquid
Pungent
0.03 ppm (v/v)
0.0077 ppm (w/v)
313 nm
3.4 (20°C)
2.1 (25°C)
1.8 (28°C)
Mlsclble {hexane)
9.4
0.08 (25°C)
0.975 (62°C)
1.717 (15°C)
1.710 (20°C)
1.7019 (25°C)
9.6-11.34
-9
-10
239
234
Stevens, 1979
Hawley, 1977; Irish, 1963
Hawley, 1977; Irish, 1963
Amopre and Hautala, 1983
Wolfe et al., 1982
Horvath, 1982
Dal Monte and Yu, 1977
Wolfe et al., 1982
U.S. EPA, 1978
Verschueren, 1977
Irish, 1963
Stevens, 1979
Hawley, 1977
Stevens, 1979
Weast and Astle, 1980
U.S. EPA, 1978; Hawley,
1977; Stevens, 1979
Weast and Astle, 1980
Aldrlch Chemical
Company, 1988
Hawley, 1977; Stevens, 1979
Irish, 1963
1 ppm = 11.17 mg/cu.m Irish, 1963
03620
11-3
04/12/91
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TABLE II-2.(cont.)
Property
Value/Description
Reference
Octanol/Haier partition
coefficient (log P)
(measured) 5.04+0.04
(estimated) 5.51
Row l.lxlO5
Latent heat of vapori-
zation 176.6 3/g
Henry's Law constant 2.7xlO~2
(atm-mVmole)
Wolfe et al., 1982
Wolfe et al., 1982
Wolfe et al., 1982
Stevens, 1979
Atallah et al., 1980;
Wolfe et all, 1982
*A wide range of melting points have been reported for this chemical; this
variation may be due to chemical Impurities and/or IsomeMc structure.
03620
II-4
06/19/90
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Into the visible spectrum, as evidenced by the yellow color of HEX. Facile
carbon-chlorine bond scission might be expected 1n sunlight or under
fluorescent light. The 1R spectrum of the dlene has two absorption bands at
6.2 and 6.3 ym 1n the double bond region and three bands at 12.4, 14.1 and
14.7 vm 1n the C-C region. The mass spectrum of HEX shows a weak
molecular 1on (M) at H/e 270, but also a very Intense (M-35) Ion making this
latter 1on suitable for sensitive, specific Ion monitoring.
HEX Is produced for commercial use only by Velslcol Chemical Corporation
(SRI, 1987; USITC, 1986). Current production data are not available. U.S.
EPA (1984) estimated that between 8 and 15 million pounds/year (4000-7500
tons) are produced. In a report prepared for the U.S. EPA, Hunt and Brooks
(1984) estimated that 8300 Mg (9130 tons) of HEX were produced 1n the United
States In 1983.
Commercial HEX contains various Impurities depending upon the method of
synthesis. The three primary processes commonly used for the production of
HEX are chlorlnatlon of cyclopentadlene, dechlorlnatlon of octachloro-
cyclopentene and the dehydrochlorlnatlon of hexachlorocyclopentane. In the
first process, cyclopentadlene Is mixed with alkaline. hypochloMte at 40°C.
HEX 1s recovered by fractional distillation, and contains appreciable
quantities of lower chlorinated cyclopentadlenes. In the dechlorlnatlon
process, HEX Is produced by thermal dechlorlnatlon of octachlorocyclopentene
at 470-480'C (Stevens, 1979). Technical grade HEX usually . contains
contaminants such as hexachlorobenzene, octachlorocyclopentene, PCBs and
mlrex. The nature and levels of contaminants will vary with the method of
production. Commercial HEX produced by Velslcol Chemical Corporation at the
03620 11-5 08/25/88
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Memphis, TN plant, which Is used Internally and sold to other users, has a
97% minimum purity (Velslcol Chemical Corporation, 1984).
Although HEX has essentially no end use of Its own, 1t has been used as
a chemical Intermediate In the production of several Insecticides/pesticides
Including aldrln, dleldrln, endrln, chlordane, heptachlor, endosulfan,
pentac, mlrex and others and In the manufacture of flame retardants such as
wet add chlorendlc add, and Dechlorane plus* (Stevens, 1979). HHh the
exception of endosulfan and pentac, the use of HEX-based pesticides has been
banned, suspended or severely restricted (U.S. EPA, 1980}-. Figure 11-1
Illustrates synthetic pathways for the various chlorinated pesticides. HEX
Is also used to a lesser extent In the manufacture of resins and dyes (U.S.
EPA, 1980}, and has been used previously as a* general blodde (Cole, 1954}.
When studying HEX 1n water, there are numerous physical properties that
Influence Us ultimate fate. In the event of release Into shallow or flow-
ing bodies of water, degenerative processes such as photolysis, hydrolysis
and blodegradatlon, as well as transport processes Involving volatilization,
evaporation and other physical loss mechanisms, are expected to be prominent
1n HEX dissipation. In deeper, nonflowing bodies of water, hydrolysis and
blodegradatlon may become the predominant fate processes (U.S. EPA, 1984).
Zepp et al. (1979, 1984) and Wolfe et al. (1982) reported the results of
U.S. EPA studies on the rate of HEX phototransformatlon In water. Under a
variety of natural sunlight conditions, 1n both distilled and natural waters
of 1-4- cm depth, phototransformatlon half-life was <10 minutes. Rate
constants were also computed for various times of the day at 40°N latitude.
03620 11-6 . 08/25/88
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03620
11-7
08/11/88
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The rate constant for near-surface photolysis of HEX was estimated as 3.9
hour"1. This corresponds to a half-life of -11 minutes. Addition of
natural sediments to distilled water containing HEX had Utt'le effect on the
phototransformatlon rate. These findings Indicated that the predominant
mechanism of HEX phototransformatlon (decomposition) was direct absorption
of light by the chemical, rather than photosensltlzatlon reactions Involving
other dissolved or suspended materials. Although no product was Identified,
Zepp et al. (1984) and Wolfe et al. (1982) speculated that the primary
phototransformatlon product was hydrated tetrachlorocyclopentadlenone, which
dlmerlzes or reacts to form higher molecular weight products. The dlmerlza-
tlon of hexachlorocyclopentadlene to form higher molecular weight products
represents a minor pathway according to Butz et al. (1982) and Yu and
Atallah (1977b). According to Chu et al. (1987), the photolysis half-life
of HEX In water was <4 minutes when exposed to "sunlight. These authors
positively or tentatively Identified at least eight photoproducts:
2,3,4,4,5-pentachloro-2-cyclopentenone; hexachloro-2-cyclopentenone; hexa-
chloro-3-cyclopentenone (primary products); pentachloro-ds-2,4-pentad1eno1c
add; 2- and E-pentachlorobutad1ene, tetrachlorobutyne (secondary products)
and hexachlorolndenone (minor product).
Studies of the hydrolysis of HEX Indicate that at 25-30°C and 1n the
environmental pH, range of 5-9, a hydrolytlc half-life of -3-11 days 1s
observed (Wolfe et al., 1982; Yu and Atallah, 1977a). ' In comparison,
hydrolysis 1s much slower than photolysis, but may be a significant load-
reducing process In waters where photolysis and physical transport "processes
are not Important (I.e., 1n deep, nonflowlng waters). Wolfe et al. (1982)
found hydrolysis of HEX to be Independent of pH over an environmental range
03620 11-8 08/25/88
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of 3-10. Also, the addition of natural sediments, sufficient to adsorb <92%
of the compound, caused the rate constant to vary by less than a factor of
2. It was therefore concluded that sorptlon to sediments would not
significantly affect the rate of hydrolysis (Wolfe et al., 1982). In both
studies (Wolfe et al., 1982; Yu and Atallah, 1977a) the authors concluded
that the hydrolysis rate was higher as temperatures Increased and although
the hydrolysis products were not Identified, high molecular weight
polyhydroxyl compounds appear to be major products.
The rate constants for the oxidation of hexachloropentadlene with
singlet oxygen (10?) and penoxy radicals 1n water were estimated at
<103 and 12 H'1 hour'*, respectively (Habey et al., 1982). If the
concentrations of 10- and RCL radicals 1n water are assumed to be
t
TO'12 and 10~» M, respectively (Mill and Mabey, 1985), H Is likely that
under ordinary environmental conditions, oxidation of HEX will not be
significant.
The Intermedia transport of HEX from water may occur through
volatilization Into air, adsorption onto suspended partlculate matters and
subsequent sedimentation and uptake by plants and animals 1n water. The
significance of HEX sorptlon 1n water was predicted by Wolfe et al. (1982)
using a computer simulated Exposure Analysis Modeling System (EXAMS). The
->r>
distribution of HEX In the sediments of a river, pond, eutrophlc and
oUgotrophlc lake was estimated to be 98.8, 86, 87 and 97.1%, respectively,
of the total HEX 1n the system. Johnson and Young (1983) observed that
adsorption plays an Important role In reducing the -concentration of HEX In
aqueous solutions. The predicted strong sorptlon of HEX 1n sediments Is
also supported by experimental sorptlon data In soils.
03620 11-9 08/25/88
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However, the main removal of HEX from water bodies comes from
volatility. Weber -(1979) measured the volatility of 14C-HEX from
distilled water following the Incubation of the glass-stoppered and
unstoppered test bottles shaken at room temperature for 24 hours. From the
full glass-stoppered bottles containing 0.41 mg/i HEX. only 4-5% of HEX
was lost, while 1n the half-full stoppered bottles, 15-16% of the chemical
was missing. The volatilization of HEX from the half-full, unstoppered
bottles was 45-47% over the 24-hour period. Other researchers (KHzer et
a!., 1979; Atallah et a!., 1980} have determined very high rates of
volatilization for HEX. Kllzer et al. (1979) reported that the volatility
of HEX ranged from 4.7-8.8%/hour from a static aqueous solution containing
50 ugA HEA. Atallah et al. (1980) observed >80% volatilization In 24
hours from unlnoculated media containing 45 rag/8. HEX.
Blodegradatlon may also be a significant process In certain waters
(Tabak et al., 1981), although the evidence 1s limited. Tabak et al. (1981)
observed complete degradation of HEX at concentrations of 5 and 10 mg/i
within 7 days In a settled domestic wastewater culture system.
Blodegradatlon of <2.5% 14C-HEX by acclimated mixed microorganisms was
observed In 2-3 weeks by Atallah et al. (1980), while Wolfe et al. (1982)
observed no difference 1n degradation rate when, sterile and nonslerlle
natural sediments were added to HEX solutions.
Analysis
Gas chromatography 1s the preferred method for analyzing HEX In air
using either flame 1on1zat1on collection or GC-63N1 electron capture
03620 11-10 04/12/91
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detection (ECD) (Chopra et al., 1978; Neumelster and Kurlmo, 1978; WhHmore
et al., 1977; NIOSH, 1979). GC/MS 1s necessary for confirmation (Elchler,
1978).
Several sorbent .materials were evaluated for collection of HEX vapor:
Amber!He® XAD-2 (20/50 mesh), Porapak® R (50/80 mesh). Amber sorb®
XE-340 (20/50 mesh), Chromosorb* 104 (60/80 mesh), Tenax-GC» (35/60
mesh), Porapak* T (80/100 mesh) and Porapak* "I (50/80 mesh). According
to the NIOSH criterion for acceptable methods, a sorbent material must have
a demonstrated sorptlon capacity for the analyte that Is adequate for
sampling a reasonable volume of workplace air at an established rate. Table
II-3 enumerates additional factors related to the Porapak® T collection
system.
\
Gas chromatography with ECD was determined to.be the most sensitive
analytical technique (Boyd et al., 1981). For HEX the chromatographlc
response was stated to be a linear and reproducible function of HEX
concentration 1n the range of -5-142 ng/ml (25-710 pg Injected), with a
correlation coefficient of 0.9993 for peak height measurement. The
optimized operating conditions for this method are shown 1n Table II-4.
Validation tests were conducted according to NIOSH guidelines. The
accuracy and precision of the overall sampling and analytical procedure for
HEX were evaluated 1n the concentration range of -13-865 pg/m3 at
25-28'C and a relative humidity >9054. The LAQL of HEX was determined to be
25 ng/sorbent tube, assuming 1 ml of hexane-desorblng solvent and a 1 hour
desorptlon time by ultrasonlfUatlon. The upper limit of the method was
03620 "-11 °8/25/88
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TABLE 11-3
Characteristics of the Porapak* T Collection System3
Characteristic HEX Type/Value
Sorbent material Porapak* Tb
(80/100 mesh)
Breakthrough t1mec >8 hour (0.2 8,/mlnute)
Breakthrough volume0 >100 l
Tube capacity0 >100 g
Average desorptlon 0.94 (27.4 ng)
efficiency of Indicated
quantity of analyte
Sorbent tube 75 mg sorblng layer,
configuration^ 25 mg backup layer
Extraction solvent Hexane
aAdapted from Boyd et al., 1981
bTh1s material required cleaning by Soxhlet extraction (see text).
cFor these tests the temperature of the generator effluent was maintained
at 25-28°C and the relative humidity at >90%. The concentration of the
analyte 1n the generator effluent was 1 mg/m~3 of HEX.
dlhe sorbent tubes were Pyrex (7 cm long by 6 mm o.d. and 4 mm l.d.}.
Sllanlzed glass wool plugs separated the sections.
03620 11-12 08/11/88
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TABLE II-4
Optimized GC Analytical Procedure for HEX3
Characteristic
Type/Value
Detector
Column
Electron capture
3% OV-1 on Gas-Chrom Q
(100/120 mesh) 1n glass
(4 mm 1.d. by 2 m)
Carrier gas
{20 mt/m1nute)
Temperatures
Injection port
Column
Detector
Detector parameters
Solvent for compound0
OPERATING CONDITIONS
5%
150°C
135°C
250°C
, 95% Ar
Detector' purge, 5% CH4 with
95% Ar (80 mi/minute)
Kexane
aAdapted from Boyd et al., 1981
bA Hewlett-Packard 5750A gas chromatograph was used.
cThe Injection volume was 5 yi of sample and 1 vi of solvent flush.
03620
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08/11/88
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2500 ng/sorbent sample. This 2500 ng level represents the smallest amount
of HEX that can be determined with a recovery of >80% and a relative
standard deviation (RSD) of <10%. The desorptlon efficiency of 100% was
determined by averaging the levels ranging from near the LAQL of 25 ng to
1000 times the LAQL.
For analysis of HEX 1n water, adequate precautions must be taken since
HEX 1s sensitive to light 1n both organic and aqueous solutions; therefore,
the water samples, extracts and standard HEX solutions must be protected.
The rate of degradation Is dependent upon the Intensity and wavelength, with
the half-life of HEX being -1 days when the solution 1s exposed to ordinary
laboratory lighting conditions. Storing the HEX-conta1n1ng solutions In
amber or red (low actinic) colored glassware Is recommended for adequate
protection (BenoH and Williams, 1981).
The XAD-2 resin extraction has been used to concentrate HEX from large
volumes of water. Solvent extraction of water has also proved successful.
The detection limit used for the organic solvent extraction technique was 50
ng/a. vs. 0.5 ng/8. for the XAD-2 method. Using the solvent extraction
method under subdued laboratory lighting conditions, the efficiency of
recovery for an artificially loaded water sample was 1n the range of 79-88%.
The authors concluded that the XAD-2 resin could not be used to accurately
sample HEX In water, but could be used to screen samples qualitatively
because of the poor detection limit (Benolt and Williams. 1981).
DeLeon et al. (1980) developed a method for determining volatile and
semlvolatlle organochlorlne compounds 1n soil and chemical waste disposal
03620 II-H 08/25/88
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site samples. This' procedure Involves hexane extraction followed by
analysis of the extract by temperature -programmed gas chromatography on
high-resolution glass capillary columns using ECD; GC/HS 1s used for
confirmation of the presence of the chlorocarbons. The method has a
detection limit of 10
When a soil sample was spiked with a 10 pg/g concentration of HEX, the
recovery was 59.8% (S.D. 6.1); at 100 yg/g, 95.9% (S.O. 15.9); at 300
wg/g, 90.2% (S.D. 4.1). Of the 11 different compounds tested, the 100
yg/g HEX sample had the highest standard deviation. Indicating that
utilizing this method for HEX may have limitations (DeLeon et al.t 1980).
Velslcol Chemical Corporation (1979) has developed analytical methods
that have been used for detecting HEX 1n urine, adipose tissue, liver,
kidney and muscle tissues. The respective recoveries and standard
deviations for these tests were (1n percentages): 80+.1Q (1-50 ppb), 85+2,
69M, 7U3 and 76+4. The level of fortification for, the tissue samples was
10 ppb. For urine, <31% HEX could be degraded when the fortified urine
sample was stored overnight 1n a cooler.
Urine was extracted with hexane, the hexane passed through anhydrous
sodium sulfate, and evaporated to 1 mn. The limit of detection for HEX
without concentrating the extract was 0.5 ppb. For cattle, poultry and fish
tissues, the tissues were extracted with 2:1 pentane/acetone, the hpmogenate
diluted with 10% sodium chloride solution, centrlfuged, and the pentane/
acetone layer transferred Into a separatory funnel. The residues were then
partitioned Into ac'etonltrlle (3 times), water diluent added to the aceto-
nHMle, and then back-extracted with pentane. The pentane extract was
03620
11-15 08/25/88
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treated with concentrated sulfudc add and then water, and concentrated to
"3 ml. Upon dilution to 10 mi with hexane, the solution was treated
with a 1:1 concentrated sulfudc acid/fuming sulfuMc add solution, water,
and a 9:1 mixture (solid) of sodium sulfate/sodlum carbonate. Packed
columns (3% OV-1 on Gas Chrom Q-100/120 mesh-1n 2 m x 2 mm 1.d. glass
column) or capillary columns (30 m x 0.25 mm SE-30 WCOT) can be used for GC
using a *3N1-electron capture detector,
Summary
HEX 1s an unsaturated, highly reactive, chlorinated cyc-Hc hydrocarbon
of low water solubility and high volatility. HEX Is used primarily as a
chemical Intermediate In the manufacture of chlorinated pesticides and flame
retardants with essentially no end uses of Us own. Low levels of HEX have
been detected 1n the environment; however, when present, It Is rapidly
degraded by a number of physical processes.
Several analytical methods have been developed for Identifying and
quantifying HEX. 1n various media. Although HEX may be found 1n water,
because of Its physical and chemical characteristics, only a small amount
can be expected to persist. In water, HEX may undergo photolysis,
hydrolysis and blodegradatlon. In shallow water, HEX has a photolytlc
half-life of <1 hour. In deeper water where photolysis 1s precluded, the
hydro!ytYc half-life of HEX 1s several days, while blodegradatlon 1s
predicted to occur more slowly. The rate of volatilization of HEX from
distilled water may be as high as 4.7-8.8Vhour. The rate of volatilization
from natural waters will depend upon depth, turbulence and wind speed.
Adsorption to sediments will also greatly reduce the rate of evaporation
from natural waters.
03620 11-16 08/25/88
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III. TOXICOKINETICS
Introduction
Limited studies on pharmacoklnetlc parameters of HEX have been reported
In the literature. Those studies that have addressed the disposition and
fate of HEX have been conducted with the 14C-labeled compound and dealt
with the total radioactivity rather than HEX per se. No metabolites of HEX
have been unequivocally Identified; however, some characteristics, such as
their volatility and solubility, have been recorded.
The principal route of HEX entry Into the human body as a. contaminant 1n
water would be by the oral route, although In Industrial settings H Is
conceivable that HEX could form an aerosol mist or exist at fairly low con-
centrations as a vapor; therefore, there Is the potential for pulmonary
uptake. Dermal exposure during handling procedures or accidental spills
should also be considered as a possible route of HEX uptake.
Intravenous Route
Yu and Atallah (1981) administered, a dose of 0.25 mg (-0.75 mg/kg) of
l*C-HEX (with an activity of 10.& mC1/mmole) as 0.3 mfi. of a solution 1n
20% Emulphor EL620/sal1ne 1n the lateral caudal vein of male and female
Sprague-Dawley rats weighing between 240 and 350 g. Sequential blood
samples, taken over a period of 24 hours post-dosing, revealed that the
elimination of HEX followed a two-compartment .open pharmacoklnetlc model
with a half-life of -0.7 and -32 hours for the Initial and terminal phases,
respectively. .
Following the administration of the 1.v. dose, Yu and Atallah (1981)
found that -1854 of the 14C-labeled HEX was excreted In the feces and -21%
03630
08/15/88
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In the urine. The radlolabel was found in all examined animal tissues.
However, at 24 hours post-dosing, the bulk of the radlolabel was still 1n
the blood (-20%), with lower amounts 1n the liver (-5%), kidneys (-2%) and
the fat (-2%). Also, 9% of the administered radlolabel was found 1n the GI
tract (duodenum, large and small Intestine), which Is consistent with the
earlier observation by Mehendale (1977) that some excretion occurred In the
bile. Of the total administered dose, 67% was recovered with In 24 hours
post-dosing. Metabolites were not characterized In the part of the study
concerned with the fate of HEX after 1.v. administration.
Lawrence and Dorough (1982) examined the uptake, deposition and .elimina-
tion of HEX following 1.v. exposure of female albino Sprague-Dawley rats.
Intravenous doses of 0.01 mg/kg of "C-HEX were administered 1n DHSO or
10:4:1 sa!1ne:propylene glycol:ethanol In 0.2 ma of solution. Recovery of
radiocarbon Immediately after treatment was 101.2+4.7%, based on calculated
doses. Elimination of the dose occurred predominantly during the first 24
hours 1n the feces and urine. Within 72 hours following treatment, 22% of
the radiocarbon was excreted In the urine, 31.4% was found In the feces and
31% was retained In the body. Of the 31% retained In the body, the kidneys
(22.3%), lungs (14.9%) and liver (9.6%) were the sites of residue
accumulation. Accumulation 1n adipose tissue was not significant. Biliary
excretion was <14%, Indicating that ~50% of the radiocarbon excreted In the
feces was unabsorbed.
In a similar study. El Dareer et al. (1983) administered male Fischer
344 rats doses of 0.59 mg/kg 14C-HEX 1n Emulphor EL-620:ethanol:water
(1:1:4 v/v) In a volume of 0.15 ml/150 g bw. A specific activity of 18
03630 III-2 08/15/88
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vC1/mg HEX was used for the 1.v. dose. At 72 hours after treatment 34.0,
15.8 and 39.0% of the dose was found 1n the feces, urine and body tissues,
respectively. Of the 39% retained In the body, 13.9 and 18.4% were found In
the liver and carcass, respectively. About 0.1% was excreted as
14C-carbon dioxide during the observation period.
Oral Route
In the same communication 1n which the pharntacoklnetlcs of HEX after
1.v. administration was reported, Lawrence and Dorough (1982) also described
the results of administering a single oral dose of HEX to rats. Female
Sprague-Dawley rats (175-250 g bw) were administered 5 vg/kg "C-HEX by
Intubation as 0.5 ma of solution 1n corn oil. Recovery of the radiocarbon
Immediately after oral treatment based on calculated dose was 98.0%. At 72
hours, 68.2% of the 5 v9/kg of 14C-HEX had been eliminated 1n the feces,
24.4% In the urine and 2.8% of the dose was retained In the body. Biliary
excretion accounted for 18% of the oral dose, Indicating the radiocarbon
eliminated 1n the feces (-50% of the dose) was not absorbed from the Gl
tract.
Mehendale (1977) administered 14C-HEX (5 v^ole; 6 mg/kg) 1n corn oil
to four male Sprague-Dawley rats by oral Intubation. Dally urine and fecal
samples were collected. After 7 days ~33% of the administered dose was
excreted 1n the urine, 87% of which was eliminated within the first 24 hours
v
after treatment. Fecal excretion was equivalent to 10% of the dose, -60% of
which was excreted within 24 hours. Only a small amount (-0.5%) of the
original dose was recovered In the kidneys and liver. Mehendale (1977)
speculated that, In view of the low total recovery of the administered dose,
03630 III-3 08/15/88
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a major part of the dose (>50%) had been excreted through the lung.
Subsequent studies by Dorough (1979) found that <1X of an oral, dose of
14C-HEX was excreted In the lungs. El Dareer et al. (1983) reported that,
after oral dosing, HEX and Us volatile metabolites can be readily lost 1f
the samples were dried and powdered In their analysis.
Dorough (1979) and Dorough and RanleH (1984) Investigated the accumula-
tion, distribution and excretion of radlolabeled HEX following Its adminis-
tration to male and female Sprague-Dawley albino rats and mice, either as a
single oral dose or as a component of their diet. To effectively account
for the radiocarbon administered to the test animals, two female rats were
dosed by gavage with 14C-HEX at 20 mg/kg 1n 0.9 ml of corn oil. The
animals were Immediately placed In separate metabolism cages through which
air was drawn at 600 ma/minute. Passing the expired air through, toluene
traps showed that <1% of the administered dose was voided as respiratory
gases.
Single dose studies (Dorough, 1979; Dorough and Ranlerl, 1984) were
conducted by administering 14C-HEX at doses of either 2.5 or 25 mg/kg bw
dissolved 1n 0.9 mi of corn oil for rats and 0.2-0.3 ml to mice using a
feeding needle. Animals were killed at 1, 3 and 7 days post-dosing and
samples of muscle, brain, liver, kidney, fat and either ovaries or testes
were removed and analyzed for 14C-act1vHy. Urine and feces were also
collected during the period between dosing and tissue sample collection. No
appreciable differences due to sex or species were found 1n the excretion
patterns. After 7 days, animals administered 2.5 and 25 mg/kg HEX had
eliminated an average of 16.4 and 15.8% of the dose In urine, and 63.3 and
03630 III-4 08/15/88
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75.2% In the feces, respectively. The liver, kidney and fat were the most
<
Important sites of deposition for l*C-res1dues In bojh rats and mice, the
levels In the kidneys of rats and liver for mice being the highest.
In the same study, rats and mice were also placed on diets containing 0,
1. 5 or 25 ppm of "C-HEX for 30 days. Assuming a dally Intake of IS g
for rats and 5 g for mice, this would give dose rates of 0, 0.066, 0.330 and
1.666 mg/kg/day for rats and 0, 0.182, 0.910 and 4.55 mg/kg/day for mice.
Feed was replaced 1n the feeders every 12 hours to minimize the loss of
"C-HEX (from volatilization) and killed at 1. 3, 7, 12; 1'5 and 30 days.
The surviving animals were then returned to a normal diet for <30 days and,
during this post-treatment period, animals were killed at 1, 3, 7, 15 and 30
days after the last day of treatment.
The total excretion (urine and feces) of the radlolabel ranged from
63-79% of the consumed 14C-HEX. In all cases, the Hver, kidney and fat
contained the highest amounts of 14C-label and a steady-state for these
levels appeared to be reached after 15 days of the feeding phase. A good
correlation was observed between the level of HEX 1n the diet and the
14C-levels found 1n all of the tissues examined. In a separate experiment
with male rats, 1n which the bile duct was cannulated and a single dose of
25 mg/kg of i4C-HEX was administered orally, only 16% of the dose was
excreted 1n the bile.
The extraction characteristics of the radiocarbon compounds 1n the
excreta showed that they were largely polar metabolites, some of which were
capable of being changed to organic soluble compounds after add catalyzed
hydrolysis.
03630
III-5
08/15/88
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In a comparative study of the pharmacoklnetlcs of 1-C-HEX after 1.v.
and oral dosing, Yu and Atallah (1981) administered single oral doses of 3
or 6 mg of i4C-HEX (specific activity, 0.267 mC1/mmole) to Sprague-Dawley
rats (240-350 g bw). The doses ranged from 8.5-25.6 mg/kg. The
l*C-act1vHy appeared In the blood within 30 minutes of dosing and reached
a maximum after ~4 hours.
Tissues were analyzed for "C-HEX at 8, 24, 48, 72. 96 and 120 hours
post-dosing. The kidney and liver had higher residue levels than any other
tissue after oral dosing, although these were generally, much lower than
those observed after 1.v. dosing. The kidneys and liver were found to
contain 0.96 and 0.75%, respectively, of the administered oral dose while
these organs retained 2.92 and 4.68%, respectively, of the administered 1.v.
dose at 24 hours post-dosing. Significantly, a higher proportion (15.07%)
of the l*C-act1v1ty was found In the digestive system (duodenum, large and
small Intestines) after oral dosing. In addition, the Increased rate and
extent of fecal excretion after oral administration (-72%), as compared with
that after .1.v. dosing (-20%), would suggest that only a fraction of the
orally administered dose was absorbed. About 17% of the oral dose was
excreted 1n the urine.
Both urinary and fecal metabolites were characterized as polar due to
their lack of solubility 1n organic solvents* Unchanged HEX was not
detected In any of the samples examined. Only 11% of the 14C-content was
soluble In organic solvents and a further 32% was rendered organo-soluble
after add catalyzed hydrolysis Indicating, perhaps, the formation of
metabolic ester-conjugates.
03630 111-6 08/15/88
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Yu and Atallah (1981) also examined the capability of liver, fecal and
gut homogenates to metabolize HEX .In. vitro. In an apparent first-order
process, HEX was metabolized by gut content, fecal and liver homogenates
with half-lives of 10.6, 1.6 and 14.2 hours, respectively. Nhen mercurH
chloride (HgClJ was added to the gut and fecal homogenates, as a bacte-
rlodde, the half-lives were Increased to 17.2 and ,6.2 hours, respectively.
Indicating that there was an Important contribution of the gut and fecal
flora to the metabolism of HEX. Denaturatlon of the liver homogenate had
virtually no effect on the In vitro metabolic rate, Indicating that there
was limited Involvement of enzyme-dependent processes.
Lawrence and Dorough (1982), In a comparative study of the uptake,
disposition and elimination of HEX, by the l.v.. Inhalation and oral routes,
orally dosed Sprague-Oawley rats (175 and 250 g) with either 5 vg or 6
mg/kg of radlolabeled HEX. Doses 1n the mlcrogram range were useful for
monitoring the urinary and fecal excretion of HEX; however, an oral dose of
6 mg/kg, 250 and 600 times the Inhaled and 1.v. tioses, respectively, was
necessary to measure tissue residue levels. The authors attributed this to
the poor b1oava1lab1l1ty of HEX when administered by. the oral route.
The total recovery of the radlolabel Immediately following the adminis-
tration of the oral dose was 98.0+5.3% (mean +. standard deviation). Rats
^ /
dosed orally voided 2-3 times more of the dose ;1n the feces than those
animals dosed by the l.v. or Inhalation route. Blood levels were measured
<6 hours after dosing and reached a maximum at 2 hours. The low level of
radiocarbon (~1 ng/mi) appearing 1n the blood as compared with animals
dosed 1.v. and by Inhalation Indicate .that there was poor absorption of HEX
03630 II1-7 08/15/88
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from the GI tract. The data were not obtained over a sufficient post-dosing
period to allow any estimate of the elimination rate.
Biliary excretion accounted for 18% of the administered dose after oral
exposure as compared with -13% after l.v. and ~8% after Inhalation. This
observation agreed with the report of Yu and Atallah (1981) who adminis-
tered comparable dose levels by the oral route. Lawrence and Dorough (1982)
also reported that the fecal material contained predominantly polar or
unextractable material. This was the case even 1n animals where bile was
collected, Indicating that degradation of HEX to polar products was taking
place 1n the gut. The authors suggested that the poor absorption of HEX
from the GI tract may be partially related to Us high affinity for binding
with the stomach contents and gut mucosa.
In a more recent comparative study (El Career et al., 1983), male
Fischer 344 rats (169 g) were dosed at 4.1 and 61 mg/kg with -1 ml of a
solution of 14C-HEX dissolved 1n a 1:1:4 mixture of Emulphor EL620,
ethanol and water. Little radioactivity (-1%) appeared as exhaled
14CO~, 2.4% remained 1n the tissues at 72 hours, <79.5% was excreted In
the feces, and <35.5 was eliminated 1n the urine.
Inhalation Route -
In a report originally produced for the Velslcol Chemical Corporation,
(Dorough, 1980) and later reported by Lawrence and Dorough (1981, 1982). on
the comparative uptake of HEX when administered by various routes, rats were
exposed to 14C-HEX vapor In a specially designed single animal exposure
system. Essentially, a known amount of 14C-HEX was applied as a solution
03630 II1-8 08/15/88
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1n hexane to the Inside .of a 3.7 I generating ' flask. Air was drawn
through the flask that was slowly rotated to allow the deposition of HEX on
the walls of the flask as the hexane evaporated. The animal was'then
exposed to the vapors 1n a rodent respirator and the exhaust vapors from the
system were passed through a filter pad made from expanded polyurethane
foam. The polyurethane foam was demonstrated to entrap all of the
l*C-HEX, which could then be solvent extracted for analysis.
Rats were exposed for a period of 1 hour to the HEX vapors and received
doses that ranged from 1.4-37.4 vg/kg bw {Lawrence and Oorough, 1981).
Immediately following this 1-hour exposure, the recovery of the retained
dose was found 'to be 91.8+8.5% (mean £ standard deviation). Tbe exposed
I
animals were Immediately placed In metabolism cages for 72 hours during
which time expired air, feces and urine were collected. The animals were
then killed and specific tissues analyzed for 14C activity. Less than IX
of the retained radiocarbon was expired during a 24-hour period Immediately
following exposure and no radiocarbon was detected as 14CO_. Only -69%
of the Inhaled dose was recovered, which was much lower than that recovered
after 1.v. or oral dosing (85% and 82%, respectively). Since recovery of
the dose Immediately following the administration of the Inhalation dose was
-92%, the reduced recovery during the 72-hour post-dosing period led to the
speculation that a volatile metabolite was formed during this post-exposure
period, but attempts to collect and Identify such a material were not
successful.
Blood concentration-time data during a 1-hour exposure and for >6 hours
postexposure were also presented. It would appear that the levels 1n the
03630
1II-9
04/12/91
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systemic circulation had barely reached steady state during the exposure
period. Elimination during the subsequent 6 hours appeared to relate to a
complex pharmacoklnetlc model with a terminal rate comparable with that
reported for the 1.v. route, with a half-life of -30 hours.
The elimination In the bile appeared to be low, with only -8% of the
administered dose being eliminated by this route, as compared with 13 and
18% after 1.v. or oral administration, respectively (Lawrence and Oorough,
1981. 1982).
The trachea and lungs contained the highest concentrations of 14C-HEX
when the tissues from animals killed at 72 hours after exposure were
^
analyzed. These concentrations were higher In these tissues than when the
dose was administered by other routes. The kidneys were also a site for
residue accumulation. Lawrence and Dorough (1981, 1982) concluded that.
Irrespective of the route of administration, the lung appeared to be the
primary target organ for toxldty.
The fraction of the dose recovered 1n the feces and urine (23 and 33%,
respectively) was about the same as that recovered after the 1.v. dose,
except that more was recovered In the urine than from the feces after the
Inhalation exposure, while the reverse was observed after the l.v. dose.
In a comparative study of the uptake, disposition and elimination of
14C-HEX, El Oareer et a.l. (1983) placed Fischer 344 rats (125-190 g) 1n
Delmar-Roth type metabolism cages; 1.1 mg of 14C-HEX (15 WC1) 1n 0.05
ma. of ethanol was then placed 1n glass U-tubes situated In the Incoming
03630 111-10 04/12/91
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air line of the metabolism cages. After 2 hours, >90% of the radioactivity
had volatilized and the dose received by each rat was calculated from the
total amounts of radioactivity recovered from the tllssues, feces, urine and
exhaled air. The fur of the animals was not Included. The dose-received by
the exposed animals was between 1.3 and l.B mg/kg bw.
The animals were killed at either 6 or 24 hours after removal from the
Inhalation exposure. Whole blood, plasma, liver, kidney, voluntary muscle
i
(gastrocnemlus), subcutaneous fat, brain, skin (ears) and the residual
carcass (except for the skin and fur) were analyzed for 14C activity. The
principal sites of deposition were the lungs, kidney and liver. Only -1% of
the radlolabel was Identified as "CO-. No Intact HEX was found 1n any
£ *
of the tissues. The majority of the radlolabel extracted from the tissues
was polar (water-soluble).
In a separate experiment, El Dareer et al. (1983) Incubated 14C-HEX
with homogenates of liver, feces and Intestinal (large and small) contents
as well as with whole blood and plasma. These jj» vitro studies were
designed to assess the binding of HEX to substrates present 1n the homogen-
ates. The mixtures were Incubated at 37°C with gentle shaking. Samples
t
were taken at 0, 5 and 60 minutes and extracted twice, first with chloroform
and then, after acidification with 1 ml of IN HC1, with chloroform:metha-
nol (2:1 v/v). The radiocarbon content of each of the samples was deter-
mined and selected samples .were also analyzed for .HEX, per se, by an HPLC
method. The results, presented In Table III-l, demonstrated the chemical
reactivity of HEX and Us ability to bind components of biological material.
03630
iii-n
08/15/88
-------�
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03630
111-12
08/15/88
-------�
Percutaneous Route
There were no studies on the pharmacoklnetlcs or disposition of HEX
found 1n a survey of the published literature or In the technical research
documents provided to the U.S. EPA by Industry under the Toxic Substances
Control Act reporting requirements. While no quantitative studies or
estimates of the uptake of HEX through skin were found, studies have been
reported In which discoloration, edema and necrosis of the skin was observed
following the dermal application of HEX (Treon et al., 1955; IROC, 1972).
In these reports, a toxic response, leading to death, was observed In
several Instances, which would suggest that HEX was absorbed transderrnally
Into the systemic circulation.
Comparative Studies
It was evident, from the available published literature, that the four
principal studies on the uptake and disposition of HEX each Involved more
than one route of uptake and that the comparison of the exposure route was
at least one objective of the study. The principal comparative observations
were as follows:
1. Irrespective of the route of application, the lung was the
target organ for toxldty.
2. The principal routes of elimination were the urine and feces.
Considerably more of the administered dose was excreted In the
feces after oral administration than after dosing by the l.v.
or Inhalation route. More of the administered dose was
excreted In the urine than the feces after Inhalation exposure
while the reverse was the case after 1.v. administration.
3. Biliary excretion occurred after administration by all three
routes. For similar doses, elimination was 1n the following
order: oral > 1.v. > Inhalation.
03630
111-13
08/15/88
-------�
4. Results of distribution studies are presented 1n Tables III-2,
III-3 and I1.I-4. The highest HEX accumulation was 1n the
kidneys,'lung and liver following oral and l.v, exposure. The
lung and trachea contained the highest concentration of HEX
after Inhalation exposure.
Summary
A number of studies are available regarding the absorption, distribution
and excretion of HEX and Its metabolites following oral. Inhalation and 1.v.
exposure. Comparative pharmacoklnetlc studies of 14C-HEX have shown
higher levels of fecal excretion following oral exposure than 1.v. or
Inhalation exposure (El Career et al., 1983; Lawrence and Oorough, 1982).
Increased elimination of radiocarbon following oral exposure is consistent
with toxUUy data that Indicate that HEX Is more toxic following Inhalation
than oral exposure. Following Inhalation exposure to 3*C-HEX,
considerable amounts of the radlolabel remain In the lung and trachea.
Indicating that HEX reacts with biological material In the lung (Oorough,
1980). .
The low level of 14C02 or 14C-HEX (<1%) exhaled from the lungs
following inhalation or oral exposure Indicates that the respiratory tract
does not play a major role In the excretion of HEX (Dorough, 1979). Urinary
excretion predominates following Inhalation exposure.
Following oral exposure, the highest levels of HEX are found In the
kidney and liver. Poor absorption of HEX from the Gl tract has been
attributed to the low bloavallablllty of HEX 1n the gut and Us rapid
metabolism by Intestinal flora following oral exposure (El Dareer et al.,
1983). Dietary exposure to HEX for 30 days showed a good correlation
03630
111-14
04/12/91
-------�
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03630
IH-15
08/15/88
-------�
TABLE III-3
Fate of Radiocarbon Following Oral, Inhalation and
Intravenous Exposure to 14C-HEX In Rats
Expressed as Percentage of Administered Dosea
Cumulative Percent of Dose
Oralb
Intravenous0
Inhalation*3
Urine
Feces
~^
Urine
Feces
Urine
Feces
Body
Total Recovery
22.2
62.2
24.0
67.7
24.4
68.2
0.2
92.8
+ 1
± 8
+ 1
i 5
+ 1
+ 5
7 o
7 4
.8
.0
.9
.1
.9
.1
.2
.7
24-Hour
18
21
48-Hour
20
30
72-Hour
22
47
15
65
.3
.1
.7
.4
.1
.4
.7
.2
_+
+
^
+
^
^
+
i
5.
7.
5.
1.
5.
1.
7.
4.
2
1
6
7
7
9
8
8
29
17
32
21
33
23
12
69
.7
.0
.5
.0
.1
.1
.9
.1
* 4.5
7 7.5
* 5.1
i 7.5
> 4.5
+ 5.7
* 4.7
* 9.6
aSource: Adapted from Dorough, 1980, and Lawrence and Dorough, 1982
bDoses administered In 0.5 ml corn oil at 7 yg/kg bw
cDoses administered tn 0.2 ma 10:4:1 sa!1ne:propylene glycol:ethanol by
Injection Into the femoral vein at 5 yg/kg bw.
dDoses administered as vapors over a 1-hour exposure period to achieve
doses of -24 yg/kg bw.
03630
111-16
08/15/88
-------�
TABLE 111-4
Distribution of HEX Equivalents 1n Tissues and Excreta of Rats
72 Hours After Oral, Inhalation and Intravenous Exposure to "C-
Sample
Oral Dose
(6 mg/kg)d
Inhaled Dose
(-24 yg/kg)
Intravenous Dose
(10 tig/kg)
Trachea
Lungs
Liver
Kidneys
Fat
Remaining carcass
ng/g of Tissue
292 * 170
420 + 250
539 I 72
3272 I 84
311 + 12
63 + 40
107,0 * 65.0
71.5 + 55.2
3.6 + 1.9
29.5 * 20.2
2.8 7 0.4
1.3 + 0.6
3.3 + 1.7
14.9 * 1.1
9.6 T 1.1
22.3 + 0.6
2.3 * 0.2
0.5 + 0.1
Percent of Dose
Whole
Urine
Feces
Total
Body
Recovery
2
15
63
81
.8 + 1.
.3 + 3.
.6 + 8.
.7 * 6.
1
3
5
7
12
33
23
69
.9 +
.1 +
.1 +
.1 +
4
4
5
9
.7
.5
.7
.6
31
22
31
84
.0
.1
.4
.6
* 7.8
+ 5.7
* 1.9
+ 4.6
aSource: Adapted from Dorough, 1980 and Lawrence and' Dorough, 1982
bOne HEX equivalent Is defined as the amount of radlolabel equivalent to
one nanogram of HEX based on the specific activity of the dosing solution.
CA11 values are.-the Mean * S.D. of three replicates.;
dNote that the oral dose was 250 and 600 times that of the Inhaled and
1.v. doses, respectively. That was necessary since residues were not
detected In Individual tissues of animals treated orally at doses of 5-25
wg/kg.
03630
111-17
08/15/88
-------�
between 14C levels found In all tissues and levels of HEX In the diet;
steady-state levels were reached after 15 days of exposure.
There 1s very limited data available regarding the pharmacoklnetlcs of
dermal exposure to HEX. Harked discoloration of the skin has resulted
following dermal application of HEX.
Hetabolltes of HEX have not been characterized. At least four polar
metabolHIes were separated from tissues and excreta regardless of the route•
of admlnstratlon. Fractions of the polar metabolites could be rendered
organo-soluble by treatment w.Hh an aqueous strong add, which suggested
that these are conjugated metabolites. Very little of the radlolabel In
tissues or excreta was extractable with organic solvents and no unchanged
HEX was detected 1n any of these fractions.
The available studies not are adequate for assessing the nature and
mechanisms Involved In the uptake, metabolism, distribution and excretion of
HEX by the 1.v., Inhalation and oral routes. Insufficient data are
available to make any quantitative estimate of dermal uptake. . The precise
characterization and chemical nature of the metabolites of HEX are not
available.
03630 111-18 06/19/90
-------�
IV. HUMAN "EXPOSURE
Text to be provided by the Office of Drinking Water,
03640
IV-T
10/16/85
-------�
-------�
V. HEALTH EFFECTS IN ANIHALS
Overview
Hexachlorocyclopentadlene toxUUy has been reported 1n many short-term
studies, several of which have been reviewed 1n other documents. Including
HAS (1978) and U.S. EPA (1980, 1984). Although : different 1n scope and
emphasis (earlier U.S. EPA documents addressed ambient water and air
toxldty, respectively) a large amount of the scientific knowledge
pertaining to HEX 1s Included 1n these documents. To avoid unnecessary
duplication, studies previously discussed 1n the above documents will not be
reviewed In great detail 1n this section, except when they are used In the
presentation of critical health effects of HEX.
Acute ToxIcUy
An approximate oral lethal dose (ALD) for female rabbits was determined
to be 420-620 mg/kg. The oral ALDs for male and female rats were <28Q and
>280 mg/kg, respectively. An oral LD,Q of 505 mg/kg for male rats was
also calculated (Treon et al., 1955). IRDC (1968) determined the oral
LD50 for male albino rats to be 926 mg/kg for HEX given 1n corn oil. In a
later study, IRDC (1972) reported oral t-D5Qs of 630, 530 and 584 mg/kg for
male, females, and male and female rats combined, ; respectively. In a more
recent study, Dorough (1979) reported an approximate lethal dose of 65 mg/kg
for male and female Sprague-Dawley rats and approximate lethal dose of 180
and 600 mg/kg for Sprague-Dawley male and female mice, respectively.
The acute toxldty studies of HEX are summarized In Table V-l. Treon et
al. (1955) conducted a series of oral toxldty studies using female rabbits
(strain unspecified) and Carworth rats of both sexes. HEX was administered
03650
V-l
04/12/91
-------�
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03650
V-3
08/11/88
-------�
as a 5% solution 1n peanut oil by gavage. In addition. Southern Research
Institute {SRI, 1980a) reported the oral LD5Q for male and female weanling
B6C3F1 mice to be 600-1200 mg/kg and the oral L05Q for weanling Fischer
344 male and female rats to be between 300 and 600 mg/kg.
Treon et al. (1955) reported an approximate dermal lethal dose for
rabbits between 430 and 610 mg/kg while IRDC (1972) reported that In male
New Zealand white rabbits, an approximate lethal dose for dermal exposure
was <200 mg/kg.
Treon et al. (1955) reported a 3.5-hour IC™ of 3.1 ppm for Carworth
rats of both sexes, and 2.1 and 7.1 ppm In male and female guinea pigs,
respectively. Rand et al. (1982a) reported a 4-hour LC5Q of 1.6 ppm for
male Sprague-Dawley rats and 3.5 ppm for female rats.
Treon et al. (1955) reported HEX to be a primary skin Irritant In
rabbits (strain unspecified) at a dose level of 250 mg/kg. Monkeys (strain
unspecified) were also tested by Treon et al. (1955). Discoloration,
necrosis and edema of the skin were noted when 0.05 ms. of a 10% HEX
solution was applied for 3 consecutive days. Application of 0.01 mi of
0.1-1054 solutions of HEX resulted In no skin Irritation. IROC (1972)
reported HEX to be a dermal Irritant 1n New Zealand white rabbits based upon
edema observed following the application of 200 mg/kg HEX. In this study,
Intense discoloration of the skin was also noted.
In a Russian study, Na1shte1n and Llsovskaya (1965) studied the effects
of HEX applied to the shaved area of the skin of rabbits (strain unspeci-
fied) dally for 10 days. According to the authors, no effects were noted 1n
03650 V-4 08/25/88
-------�
control and test animals given dally doses of 0.5-0.6 ma of a 20 mg/a
solution of HEX.
The acute oral toxldty of HEX was tested In male CD-I mice (6/group)
following a single gavage dose of 0, 0.05, 0.1, 0.5, 1.0 or 5.0 g/kg HEX In
DHSO (Litton Blonetlcs, 1978b). Mortality was observed 1n 6/6 mice exposed
to both the 1.0 and 5.0 g/kg dose. At doses of 0.05, 0.1 and 0.5 g/kg. 1/6,
1/6 and 3/6 deaths were observed, respectively. .In a follow-up study,
exposures of 7.6, 25.3 or 76 ing/kg HEX for 5 consecutive days resulted In
6/10, 9/10 and 10/10 deaths, respectively.
Fischer 344 rats and B6C3F1 mice (5/sex/group) were administered a
single gavage dose of 0, 75, 150, 300, 600 or 1200 mg/kg HEX and observed
for 14 days (SRI, 1980a). Treatment-related mortality was seen 1n 5/5 male
and 5/5 female rats at >600 mg/kg and In 2/5 females at the 300 mg/kg dose
level. No other treatment-related deaths were recorded. Animals exposed to
>300 mg/kg HEX also experienced decreased activity, ruffled fur and
diarrhea; the severity and duration was directly related to the dose level.
Animals In the 75 and 150 mg/kg dose groups experienced none of the effects
observed at the higher exposure levels with the exception of "wet fur In the
anal area", which the authors suggested may be an Indication of mild Gl
disturbances. ,
In the mice, all animals exposed at 1200 mg/kg died, while only one
female and one male died at the 600 mg/kg level. At the other exposure
levels (<300 mg/kg) only minor effects were observed.
03650 V-5 08/25/88
-------�
In a follow-up range finding study {SRI, 1980b), rats and mice were
administered HEX 1n corn oil at 25, 50, 100, 200 and 400 mg/kg for rals and
50, 100, 200, 400 and 800 mg/kg for mice on a 12-day schedule (days 1-5,
8-12, 15 and 16). Five mice and five rats of each sex were dosed at each
level, with at least two consecutive dosing days before sacrifice. Body
weights were taken on days 0, 7 and 17. All animals were observed twice
dally for signs of toxlclty and clinical symptoms.
In the rat experiment (SRI, 1980b), all males and 4/5 females at the 400
mg/kg HEX dose level died, while at the 200 mg/kg dose. 1/5 males and 4/5
females died. For the remaining males, there was a dose-related decrease 1n
body weight gain of 8, 17, 43 and 135% for the 25, 50, 100 and 200 mg/kg
dose groups, respectively. Significant gross changes- 1n the stomach Includ-
ing ulceratlon and thickening of the stomach wall were observed In all the
surviving animals at doses >100 mg/kg and 1n 5/5 males and 2/5 females at
the 50 mg/kg dose level.
In the mouse experiments (SRI, 1980b), all-of the treated animals at the
400 and 800 mg/kg dose level died. No treatment-related mortality was seen
at <200 mg/kg and only minor effects were observed at <1QO mg/kg HEX. The
weight gain depression seen 1n the rat study was not evidenced In the mouse
study. .'
Rand et al. (1982a) conducted a range-finding study In which groups of
10 male and 10 female Sprague-Dawley rats were exposed to atmospheres 0.022,
0.11 or 0.5 ppm HEX, 6 hours/day, 5 days/week for a total of 10 exposures.
Nine male rats and one female rat exposed to 0.5 ppm HEX were dead or morl-
03650 V-6 04/12/91
-------�
bund after 5-7 exposures. Prior to death, these rats had dark red eyes,
labored breathing, and paleness of extremities. No 'deaths were noted In the
other exposure groups; however, the males In the 0.022 and 0.11 ppm groups
experienced a significant (p<0.05) concentration-related reduction In mean
body weight. Mean lung weights were significantly Increased In males and
females exposed to 0.5 ppm. Significant reduction 1n kidney, adrenal and
ovary weights were also observed 1n the 0.5 ppm group. In males, liver
weight was reduced 8-9% of control at >0.022 ppm dose levels and In females
in the 0.11 and 0.5 ppm groups.
Subchronlc and Chronic Toxlclty
Subchronlc toxUHy studies of HEX are summarized In Table V-2. Oral
toxUlty studies In B6C3F1 mice and Fischer 344 rats have been conducted by
SRI (1981a,b; Abdo, 1984) under contract with NTP. In the mouse study (SRI,
1981a), dose levels of 0, 19, 38, 75, 150 and 300 mg/kg HEX (94;3-97.4%) 1n
corn oil were administered by gavage to 10 mice of each sex, 5 days/week for
13 weeks "(91 days). At the highest dose level (300 mg/kg), all male mice
died by day 8 and three females died by day 14. In female mice, there was
significant dose-related enlargement of the liver. Toxic nephrosis In
females at doses of >75 mg/kg was characterized by lesions In the terminal
portions of the convoluted tubules, with basophllla In the Inner cortical
zone and cytoplasmlc vacuollzatlon. Nephrosis was not observed In male mice
at any dose level. Levels of >38 mg/kg HEX caused lesions In the fore-
stomach. Including Inflammation and hyperplasla In both males and females
and a decrease 1n relative body weight gain. These lesions Increased 1n
severity and Incidence with Increased dose. At the 19 mg/kg dose level, no
significant hlstologlc changes were seen In any of the organs examined.
03650
V-7
04/12/91
-------�
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Slight Increases In organ weights were noted. A dose level of 38 mg/kg was
considered a LOAEL In mice based on the Increasesd Incidence and severity of
nephrosls 1n females and an Incidence of hyperplasla and Inflammation In
males and females. The 19 mg/kg dose level was considered a NOAEL for mice.
In the rat study (SRI, 1981b; Abdo et al., 1984), dose levels of 10, 19,
38,' 75 and ISO mg/kg HEX 1n corn oil were administered by gavage to groups
of 10 male and female F344 rats, 5 days/week for 13-weeks. At doses of >38
mg/kg HEX, epithelial hyperplasla and Inflammation of the forestomach.
Increased mortality and toxic nephrosls were observed In males and females.
A significant (p<0.05) dose-related depression In body weight gain was
observed 1n males at levels of >38 mg/kg and! females at >75 mg/kg.
t
Liver-to-brain weight ratios were significantly (p<0.05) Increased In
females at >38 mg/kg and k1dney-to-bra1n weight ratios at >75 mg/kg. At
doses >19 mg/kg, epithelial hyperplasla and focal Inflammation of the fore-
stomach, and toxic nephrosls were noted 1n females. Decreases .In body
weight gain relative to the controls were observed 1n males at all dose
levels; however, these were not significant at the 10 or 19 mg/kg dose
levels. In females, dose-related decreases In body weight gain were
observed at doses >38 mg/kg/day. No significant adverse effects were
observed In rats at the 10 mg/kg dose level. A summary of these results are
presented 1n Table V-3.
Fourteen-week Inhalation.studies In rats and monkeys have been performed
(Rand et al., 1982a,b; Alexander et al., I960). Groups of 40 male and. 40
female Sprague-Dawley rats, weighing 160-224 g or groups of 12 cynomolgus
monkeys (6/sex), weighing 1.5-2.5 kg, were exposed to HEX, 6 hours/day, 5
days/week, for as long as 14 weeks. Levels of exposure were 0, 0.01, 0.05
03650
V-9
04/12/91
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V-10
08/11/88
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V-ll
08/11/88
-------�
and 0.20 ppm HEX. In monkeys, there were no deaths, or adverse clinical
signs, or significant changes 1n weight gain, pulmonary function, eye
morphology, hematologlc parameters, clinical chemistry or hlstopathology at
any dose level tested.
Male rats had a transient appearance of dark-red eyes at 0.05 and 0.2
ppm HEX. At 12 weeks, there were marginal but not statistically significant
Increases 1n hemoglobin concentration and erythrocyte count In 0.01 ppm
males, 0.05 ppm females, and 0.20 ppm males and females. There were small
but nonsignificant changes In mean liver weight of all treatment groups and
similar changes In the kidneys of all treated males. There were no
treatment-related abnormalities 1n gross pathology or hlslopathology. On
this basis, the NOAEL In rats was 0.2 ppm HEX.
In another study by Rand et al. (1982b), no treatment-related ultra-
structural changes were observed 1n monkeys exposed to HEX vapors. Exposure
was Identical to that described 1n the previous study (Rand et al., 1982a).
This study took an In-depth look at the Clara cells of the lung; the results
showed a statistically significant (p<0.01) Increase 1n the mean number of
electron-lucent Inclusions 1n the apex and base of the Clara cells In the
exposed animals as compared with the controls. According to some
researchers (Evans et al., 1978), Clara cells respond to Injury by regres-
sion to a more primitive cell type. Rand el al. (1982b) noted that some of
the ultrastructural changes 1n the exposed animals resembled those of the
Evans study. The biologic significance of these results are "not known;
however, Clara cells play an Important part 1n producing the extracellular
lining of the peripheral airways. Alteration of this lining may result 1n
subsequent Impaired breathing (Rand et al., 1982b).
03650 V-12 04/12/91
-------�
Treon et al. (1955) exposed two guinea pigs, six rabbits, four rats and
five mice to a concentration of 0.34 ppm HEX for 7. hours/day, 5 days/week
for 25-30 exposures. Guinea pigs survived the 30 exposures, while only two
rabbits survived and no rats or mice survived 5 exposures. Degenerative
changes were observed In the brain, heart, liver, adrenal glands and
kidneys. Severe pulmonary edema, hyperemla and acute necrotlzlng bronchitis
was also observed. Using a lower concentration (0.15 ppm HEX}, 2/2 guinea
pigs, 3/3 rabbits and 4/4 rats survived 150 seven-hour exposure periods. ,ln
mice, only 1/5 animals survived. Slight renal and 'hepatic degeneration was
noted In all species and rats, mice and guinea pigs also developed lung
lesions.
In an NTP-sponsored study (Battelle Northwest Laboratories, 1984; Abdo
et a!., 1986), F344 rats and B6C3F1 mice (10/group/sex) were exposed to HEX
(99.42%) at 0', 0.04, 0.15, 0.4, 1 or 2 ppm (0, 0.45, 1.67, 4.46, 11.1 or
22.3 mg/m3) 6 hours/day, 5 days/week for 13 weeks. All .rats and mice
exposed to >1 ppm died; 5/10 male and 2/10 female mice at the 0.4 ppm also
died. In male rats, there were statistically significant (p<0.05)
reductions 1n body weight and Increases 1n relative lung weight at 0.4 ppm.
Similar but less severe effects were seen In females. Dose-related
hlstopathologlc changes were observed 1n the respiratory tract epithelium of
males and females at >0.4 ppm. Changes Included necrosis and acute
Inflammation. No statistically significant adverse effects were observed 1n
rats at <0.15 ppm.
In mice (Abdo et al., 1986), exposure to >0.4 ppm HEX resulted In a 10%
reduction 1n body weight gain In males and females. Dose-related
03650
V-13
04/12/91
-------�
hlstopathologlc alterations In the respiratory epithelium, Including
hyperplasla and metaplasia, were observed 1n all treated mice at levels
>0.15 ppm. No adverse effects were seen 1n mice exposed at 0.04 ppm.
A chronic oral toxlclty study of HEX being conducted by SRI for the NIP
was terminated 1n April 1982 because Inhalation was determined to be the
more relevant route of exposure. No other chronic oral toxldty data were
available for this report. There were no chronic dermal toxlclty studies
found 1n the available literature.
A 30-week Inhalation study 1n rats of technical grade HEX, 96% pure with
hexachlorobuta-l,3-d1ene and octachlorocyclopentene as Impurities, was
conducted by Shell Toxicology Laboratory (D. Clark et a!., 1982). Four
groups of 8 male and 8 female Wlstar albino rats were exposed to HEX at
nominal, concentrations of 0, 0.05, 0.1 and 0.5 ppm for 6 hours/day, 5 days/
week, for 30 weeks and were observed for a 14-week recovery period without
HEX exposure. At the highest dose level 4 males and 2 females died. In
males, there was a depressed body weight gain In the 0.5 ppm group relative
to controls beginning at 7 weeks of exposure and persisting throughout the
remainder of the study. In females, body weights were significantly
Increased during the first half of the exposure period but were signifi-
cantly (p<0.01) decreased at the end of the recovery period at 0.5 and 0.1
ppm. At 0.5 ppm, there were pulmonary degenerative changes noted 1n both
sexes although the males were affected more severely. At the 0.5 ppm dose,
there were mild degenerative changes 1n the liver and kidneys at 30 weeks 1n
a few rats and kidney weights were significantly Increased 1n the females.
After 30 weeks of study, there was no biologically significant toxldty
noted In animals exposed to concentrations of 0.05 or 0.1 ppm HEX.
03650 V-14 04/12/91
-------�
Hutaqenldty
Goggelman et al. (1978) found, that HEX was not mutagenlc with or without
liver mlcrosomal activation at 2.7x10~3 M 1n an EscheMchla coll K12- back
mutation system. In this test there was 7054 survival of bacteria at 72
hours. HEX was not tested at higher concentrations:because 1t was cytotoxlc
to |_. coll. A previous report .from the same laboratory (Grelm et al., 1977)
Indicated that HEX was also not mutagenlc In Salmonella typhlmurlum strains
TA1535 (base-pair :mutant) or TA1538 (frame shift mutant) after liver mlcro-
somal activation;, however, no details of the concentrations tested we.«
given. Although tetrachlorocyclopentadlene Is mutagenU 1n these systems,
probably through metabolic conversion to the dlenone, H appears that the
chlorine atoms at the C-l position of HEX hindered metabolic oxidation to
the corresponding acylatlng dlenone {Grelm et al., 1977).
A study conducted by Industrial Bio-Test Laboratories (IBT, 1977) also
suggests that HEX Is not mutagenU In S. typhlmurlum. Both HEX and 11s
vapors were tested with and without metabolic activation. The vapor test
was done In desiccators with only the TA100 strain of S. typhlmurlum. It Is
not clear from the data whether sufficient amounts of HEX or adequate times
of exposure were used. Exposure times of 30, 60 or 120 minutes were studied.
At concentrations of <1.25xlO~3 iig/mi. 1n the presence of an S-9
liver activating system, HEX was not mutagenU In the mouse lymphoma muta-
tion assay. MutagenUHy could not be evaluated at higher concentrations
'because of the cytotoxUHy of HEX (Litton Blonetlcs, Inc., 1978a).
03650
V-15 04/12/91
-------�
Williams (1978) found that HEX (10~* M) was Inactive In the liver
epithelial culture hypoxanth1ne-guan1ne-phosphorlbosyl transferase (HGPRT)
locus/mutation assay. At 10"5 M It also failed to stimulate DNA repair
synthesis In hepatocyte primary cultures. Negative results were also
obtained In an additional unscheduled DNA synthesis assay (Brat, 1983}.
Two recent studies provided by NTP (Haworth et a!., 1983) also did not
demonstrate the mutagenldty of HEX. In S. typhlmurlum strains 1A98, TA100,
TA1535 and TA1537, levels of <3.3 yg/plate were not mutagenlc without
activation and levels of <100.0 v9/plate were not mutagenlc after mlcro-
somal activation. Higher levels could not be tested because of excessive
killing of the bacteria. In the DrosophUa sex-linked recessive lethal
test, HEX was not mutagenlc. The doses used In this study were 40 ppm by
feeding for 3 days or a single Injection of 2000 ppm.
HEX has also been assayed In the mouse dominant lethal test (Litton
Blonetlcs, Inc., 1978b). In this assay, -0.1. 0.3 or 1.0 mg/kg HEX was
administered by gavage to 10 male CD-I mice for 5 days and these mice were
then mated throughout spermatogenesls (7 weeks). This test determines
whether the compound Induces lethal genetic damage to the • germ cells of
males. There was no evidence of dominant lethal activity at any dose level
by any parameter (e.g., fertility Index, Implantations/pregnancy, average
resorptlons/pregnancy).
Carc1nogen1c1ty
An NTP bloassay of HEX for cardnogenlcHy by the Inhalation route 1n
rats and mice 1s 1n progress (NTP, 1991). The ability of HEX to Induce
03650 V-16 . 04/12/91
-------�
morphologic transformation of BALB/3T3 cells jjn vitro has been studied by
Litton B1onet1cs, Inc. (1977), Evaluation of the potential for carcinogenic
activity was based on the following criteria:
The endpolnt of carcinogenic activity Is determined by the presence
of f1broblast1c-l1ke colonies, which are altered morphologically 1n
comparison to the cells observed In normal cultures. These (trans-
formed) cells grow In criss-cross, randomly oriented fashion with
overlapping at the periphery of the colony. The colony exhibits
dense piling up of cells. On staining the foci are deeply stained
and the cells are basophlllc In character and variable In size.
These changes are not observed 1n normal cultures, which' stain
uniformly.
Assays were performed at levels of 0.0, l.OxlO*5, 2.0xlO~s,
3.9xlO"5, 7.8xlO~s and 1.56x10"* yl/mi. The cultures were exposed
for 48 hours followed by an Incubation period of 3-4 weeks. The doses
selected allowed an 80-100%' survival of cells as compared with solvent
negative controls. 3-Hethylcholanthrene at a dose level of .5 yg/mj. was
used as a positive control. Results Indicated that HEX was not responsible
for any significant malignant transformation.
Teratogen1c1ty
.The teratogenU potential of HEX was evaluated 1n pregnant Charles River
CD-I rats administered HEX, (98.25%) In corn oil, by gastlc Intubation, at
dose levels of 3, 10 and 30 mg/kg/day from days 6 through 15 of gestation.
A control group received the vehicle (corn oil) at a dose volume of 10
ml/kg/day. Survival was 100%, and there was no difference 1n mean
maternal body weight gain between dosed groups and controls. A persistent
anogenHal staining was observed In dams at the highest dose. There were no
differences In the mean number of Implantations, corpora lutea, live
fetuses, mean fetal body weights or male/female sex ratios among any of the
03650
V-17
04/12/91
-------�
groups. There were no statistical differences 1n malformation or develop-
mental variations compared with, the controls when external, soft tissue and
skeletal examinations were performed (IRDC, 1978).
Hurray et al. (1980) evaluated the teratogenlc potential of HEX {98%) In
CF-1 mice and New Zealand white rabbits. Mice were dosed at 0, 5, 25 or 75
mg/kg/day HEX by gavage.from days 6-15 of gestation while rabbits received
the same dose from days 6-18 of gestation. In the mice, no evidence of
maternal toxUUy, embryotoxUHy or teratogenlc effects was observed. A
total of 249-374 fetuses (22-33 Utters) were examined 1n each dose group.
In rabbits, maternal toxlclty was noted at 75 mg/kg/day (diarrhea,
weight loss and mortality), but there was no evidence of maternal toxldty
at the lower levels. There were no embryotoxlc effects at any dose level.
Although there was an Increase In the proportion of fetuses with 13 ribs at
75 mg/kg/day, this was considered a minor skeletal variation, and the
authors concluded that HEX was not teratogenlc at the levels tested.
Studies on the teratogenlc potential of Inhaled HEX were not located 1n
the review of the scientific literature. No data were located that
addressed the reproductive effects of HEX.
Summary
Although there are some Interspecles differences among guinea pigs,
rabbits, rats and mice, HEX vapors are toxic to all species tested. HEX
appears most toxic when administered by Inhalation, with oral and dermal
administration being less toxic routes. The acute lethal concentration
03650
V-18
06/19/90
-------�
(LC50) of 1.6 and 3.5 ppm In male and female rats, respectively, has been
demonstrated. The oral L05Q for adult animals is >500 mg/kg; however,
approximate lethal doses of 180 and 280 mg/kg were determined for mice and
rats, respectively.
Subchronlc oral dosing of rats (38 mg/kg/day) and mice (75 mg/kg/day)
for 91 days produced nephrosls and Inflammation and hyperplasla of the
forestomach. No overt, signs of toxUlty were noted when mice and rats were
exposed by Inhalation at 0.2 ppm of HEX (6 hours/day, 5 days/week) for 14
weeks. However, Inhalation exposure of rats at 0.5 ppm for 30 weeks caused
degenerative changes 1n the liver, respiratory tract and kidneys. jUi vitro
test results from three species have not shown HEX to be a mutagen. HEX was
also Inactive In the mouse dominant lethal assay. In rabbits, maternal
toxUUy has been noted at high oral levels of HEX (75 mg/kg/day), but there
was no evidence of maternal toxUUy at lower levels. Other research has
not shown any maternal toxUUy to mice. Long-term studies of HEX inhala-
tion are presently being conducted by the NTP.
03650
V-19
06/19/90
-------�
-------�
VI. HEALTH EFFECTS IN HUHANS
According to a NIOSH estimate, 1427 workers are occupatlonally exposed
to HEX (NIOSH, 1980). Velslcol officials estimate that -157 employees are
potentially exposed to HEX In their production facilities. Acute human
exposure has been reported In homes near waste sites where HEX has been
disposed (C. Clark et al.. 1982; Ella et al., 1983).
Very little detailed Information Is available concerning the human
health effects of HEX exposure. The most noticeable effect Is the pungent,
Irritating odor produced by HEX. Levins (1980) reported that the odor
threshold of 0.0017 mg/m3 (0.00015 ppm) represented the recognition level
for 100% of the Individuals on a test panel. The study design and method-
ology were not given. Based upon animal studies and observations by
researchers, HEX vapors are very Irritating to all mucous membranes, causing
tearing, sneezing and salivation; skin contact can cause blisters and burns.
Inhalation of vapors or mist can result 1n the secretion of excess fluid In
the lung, while Inhalation or Ingestlon may cause nausea, vomiting,
diarrhea, lethargy, respiratory Impairment and Injury to the liver or
kidneys.
Acute Exposure Studies
Treon et al. (1955) reported that members of a group conducting toxlclty
tests developed headaches when they were accidentally exposed to unknown
concentrations of HEX, which had escaped Into the room when an aerated
exposure chamber was opened.
03660
VI-1
08/25/88
-------�
A well-documented Incident of acute human exposure to HEX occurred 1n
March 1977 at the Morris Forman Wastewater Treatment Plant 1n Louisville,
KY. The Incident has been described and reviewed In several papers (HUson
et al., 1978; Morse et al., 1979; KomVnsky et al.. 1980). The complete
details of the original NIOSH Hazard Evaluation and Technical Assistance
Report Number TA-77-39 are found In Komlnsky and Wlsseman (1978).
In 1977, the Louisville treatment facility was contaminated with -6 tons
of HEX and smaller amounts of OCCP, a waste by-product of HEX manufacture
(Horse et al., 1979). The contamination was traced to one large sewer line
that passed through several populated areas. Concentrations of HEX detected
In the sewage water at the. plant ranged <1000 ppm, and levels 1n the sewer
Hne ranged <100 ppm. A1r samples from the sewer line showed HEX
concentrations <400 ppb. Although airborne concentrations of HEX at the
time of the exposure were unknown, airborne concentrations 1n the primary
treatment areas (screen and grit chambers) ranged between 270 and 970 ppb 4
days after the plant had closed. (The ACGIH TWA for HEX was 10 ppb 1n
1977.) During the cleanup, when workers used steam to remove the
contamination, levels of 19.2 ppm HEX were reported (Komlnsky et al., 1980).
The Centers for Disease Control (CDC) and NIOSH developed questionnaires
regarding the type and duration of symptoms (Morse et al.., 1979; Komlnsky et
al., 1980). A total of 193 employees were Identified as those potentially
exposed for 2 or more days during the 2 weeks before the plant was closed
(Morse et al., 1979). Of the 193 employees exposed, 145 (75X) responded.
Physical examinations and blood and urine samples were collected from
workers reporting symptoms of mucous membrane Irritation.
03660 VI-2 08/25/88
-------�
Results of the CDC and NIOSH questionnaires showed that the odor of HEX
was detected before the onset of symptoms by 94% of the workers. The most
common symptoms reported were eye Irritation (59%), headaches (45%) and
throat Irritation (27%) (Table VI-1). Of the 41 workers physically
examined, 6 had physical signs of eye Irritation (I.e., tearing or redness)
and 5 had signs of skin Irritation. Laboratory analyses of blood and urine
specimens from these workers showed elevations of lactic dehydrogenase (LDH)
In 27% and protelnurla In 15%. However, no clinical abnormalities were
reported by the plant physician, the local hospital, or by the Independent
laboratory 3 weeks later (Horse et al., 1978, 1979).
During clean-up procedures, clinical chemistry parameters were moni-
tored. The only abnormalities noted were several m1n1mal-to-m1ld altera-
tions In liver function tests (Komlnsky et al., 1980). These abnormalities
are listed In Table VI-2. All workers showing these symptoms also had
physical signs of mucous membrane Irritation. Table VI-3 summarizes data
for nine workers exposed at the site (Komlnsky et al., 1980). The exposure
levels could not be estimated accurately because of possible prior exposure
and because the workers had used protective equipment.
A questionnaire was also given to a selected sample of residents of a
48-block area surrounding the contaminated sewer line. A total of 212
occupants were surveyed. Very few residents noted an unusual odor (3.8%).
The most prevalent symptoms were stomachaches (5.2%). burning or watering
eyes (4.7%) and headaches (4.7%). There was no association between symptom
rates and the distance of households from the contaminated sewer line.
03660
VI-3
08/11/88
-------�
TABLE VI-1
Symptoms of 145 Wastewater Treatment Plant Employees
Exposed to HEX (Louisville, KY, March 1977)*
Symptom
Eye Irritation
Headache
Throat Irritation
Nausea
Skin Irritation
Cough
Chest pain
Difficult breathing
Nervousness
Abdominal cramps
Decreased appetite
Decreased memory
Increased saliva
No. of Employees
with Symptom
B6
65
39
31
29
28
28
23
21
17
13
6
6
Percent of Employees
with Symptom
59
45
27
21
20
19
19
16
14
12
9
4
4
*Source: Morse et al., 1978
03660
VI-4
09/19/85
-------�
TABLE VI-2
Abnormalities for 18 of 97 Cleanup Workers
at the Morris Forman Treatment Plant3
Abnormal Results
Laboratory Test Normal Range
Serum Glutamate-
Oxalacetate Transamlnase (SGOT) 7-40 mil/ml
Serum Alkaline Phosphatase 30-100 mil/mi
Serum Total BlUrubln 0.15-10 mg/%
Serum Lactate Dehydrogenase 100-225 mU/mst
Range
40-49
50-59
60-69
70-79
80-89
90-99
100-109
110-119
120-129
1.0-1.9
230-239
No.
5
1
4
0
1
1
3
1
1
lc
1
aSource: Komlnsky et a!., 1980
bFor Individuals with more than one serial blood test, only the most
abnormal result 1s tabulated.
Associated with serum glutamate-oxalacetate transamlnase of 66
U * Units of enzyme activity
03660
VI-5
08/11/88
-------�
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03660
VI-6
08/11/88
-------�
The authors stated that no significant ambient air concentrations of HEX
were found 1n these areas (Komlnsky and Wlsseman, 1978). Residents reported
the same types and frequency of symptoms reported by workers assoclated'wilh
HEX exposure, which led the authors to suggest that these symptoms were
unrelated to HEX exposure or may be due to other confounding environmental
factors (Horse et al., 1978).
Several papers have documented 'a similar Incident of HEX exposure -In
Hardeman County, TN. (C. Clark et aK, 1982; Meyer, 1983; EUa et al.,
1983). In 1978, workers at the treatment plant began complaining of acute
symptoms similar to those found In the Louisville plant. Air and wastewater
levels were monitored, and urine, blood and liver function tests were
analyzed, as well as data obtained from an Illness symptom questionnaire.
In the original study design, workers were compared with a control group
from another Memphis treatment plant, which did not receive wastes from the
pesticide manufacturing plant. In a later survey, workers at two other
municipal facilities were used for comparison. In the analysis of the
various monitoring tests, C. Clark et al. (1982) found no statistical
difference 1n urine samples from both of the Memphis treatment facilities.
In the liver function tests, there were no statistically significant
differences among the values obtained for all survey groups.
At the same time the wastewater treatment plant study was being
performed, an Investigation of residential wells In Hardeman County was
conducted In response to complaints of foul odors and bad taste (Meyer,
1983). In this area also lies a 200 acre chemical land dump, which was
operated from 1964-1972. In 1978, the U.S. Geologic Survey (Sprinkle, 1978;
Rlma, 1979) confirmed the contamination of wells. However, HEX was not
03660
VI-7
04/12/91
-------�
detected 1n any samples. Urine surveys and liver function analyses were
conducted on residents. A summary of this data Is presented 1n Table. Vl-4.
The situation at the Memphis treatment facility Is the only known existing
case of essentially continuous low-level chronic exposures with Intermittent
higher acute exposures, especially during an accidental discharge .from the
nearby pesticide manufacturing facility (Ella et al., 1983).
Epldemlologlc Studies
Mortality studies have been conducted on workers Involved In the produc-
tion of HEX or formulation of HEX products. The Shlndell and Associates
(1980) report was a cohort study of workers employed at the Velslcol
Chemical Corporation plant at Marshall, Illinois between 1946 and 1979. The
purpose was to evaluate the vital statistics of all former and current
employees (>3 months) who were present during the manufacture of chlordane.
In preparing the cohort, the authors noted the difficulties 1n tracing some
of the employees. In the final cohort of 783 Individuals, 97.4% of the
employees were located and their vital status Included 1n the study. The
analysis showed no significant differences 1n mortality rates between these
employees and the U.S. population. The observed deaths for all causes,
Including heart disease and cancer, were fewer than the calculated expected
deaths among members of the U.S. population (Shlndell and Associates, 1980).
Wang and MacMahon (1979) conducted a study of 1403 males employed at the
Marshall and Memphis plants for >3 months. There were 113 observed deaths
compared with 157 expected, yielding a standardized mortality ratio (SMR) of
72. The two highest SMRs were 134 for lung cancer and 183 for. cerebrovascu-
lar disease, but only the latter was statistically significant (p<0.05).
03660 VI-8 08/11/88
-------�
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03660
VI-9
08/11/88
-------�
The authors suggested that these effects were unrelated to exposure because
the deaths showed no consistent pattern with duration of employment or with
duration of follow-up.
A study of >1000 employees (93% of the cohort) at the Memphis, TN plant
from 1952-1979 was conducted by Shlndell and Associates (1981). The
researchers found no significant difference 1n mortality between the control
and exposure groups and fewer deaths 1n the study group than predicted from
vital statistics rates. The Investigators also reported there was no excess
mortality by job function.
Buncher et al. (1980) studied the mortality rates of workers at a
chemical plant that produced HEX. The Investigators reviewed personnel
records for those who worked for at least 90 days between October 1, 1953
and December 31, 1974. There were, 341 workers (287 male and 54 female) who
fit the criteria. Health status was ascertained through 1978 and expected
numbers of. deaths were calculated based upon the U.S. population and
specifics for sex, age and calendar year. The SMR was 69 showing the
workers to be healthier than the general population. Deaths caused by
specific cancers, all cancers, disease of the circulatory and digestive
systems were fewer than the expected numbers. The authors noted that the
time since Initial exposure, <25 years, reduced the power of the study to
detect cancers, which may have a 10-40 year latent period.
Summary
There Is only limited Information on the effects of HEX 1n humans.
Acute Inhalation exposure has resulted 1n headaches and severe Irritation of
the eyes, nose, throat and lungs. Dermal contact may cause severe burns and
03660 - VK10 08/25/88
-------�
skin Irritation. Ep1dem1olog1c studies have generally shown no significant
differences 1n mortality rates of workers exposed to HEX 1n the workplace
and the general population. Although a significant excess of deaths from
cerebrovascular disease was reported 1n one study, no consistent pattern was
observed with duration of employment or follow-up.
Current human exposure 1s limited to Improper handling and disposal and
proximity to either manufacturing sites utilizing HEX or disposal sites. No
other chronic human health effects data from HEX exposure have been located
In the literature.
03660
VI-11
08/25/88
-------�
-------�
VII. MECHANISMS OF TOXICITY
The mechanisms underlying HEX toxUHy are not well understood, mainly
because of Us high chemical reactivity and ability to polymerize even at
low temperature. HEX has been shown to react with oleflns and other organic
molecules, such as aromatic compounds. In vitro studies by El Oareer et al.
(1983) have Indicated that HEX readily binds to organic material and can be
easily extracted.
While the available literature does not provide any single mechanism to
account for HEX toxldty, Lawrence and Oorough (1982) showed that all routes
of exposure caused necrotlc lung tissue. Exposure to HEX vapors results In
Irritation of the respiratory tract and may lead to bronchopneumonla and
respiratory failure (D. Clark et al., 1982). In comparison, the degenera-
tive changes 1n the liver and kidneys are mild and unlikely to contribute to
the chemical's toxlclty (NAS, 1978; SRI, 1980a,b).
Absorption from the Gl tract was reported to be relatively Inefficient.
This may be due to the poor bloavallabllHy of HEX when administered by the
oral route or to Us rapid hepatic metabolism and biliary excretion (El
Dareer et al., 1983; Lawrence and Dorough, 1962). Studies by Yu and Atallah
(1981) Indicate that the gut and fecal flora may have a major role In the
metabolism of HEX and that enzyme dependent processes may be limited.
Absorption following dermal exposure resulted In marked distinct skin
discoloration, and In some cases, mortality. This might suggest a "site of
uptake" Interaction, which may be similar to that observed In the lung after
pulmonary uptake.
03670
VII-1
08/25/88
-------�
Following Inhalation and the diffusion of HEX through the lung tissue to
the blood, metabolism to water-soluble compounds may occur, but attempts to
collect and Identify metabolites have been unsuccessful. The relatively
slow elimination of the radlolabel from the systemic circulation after 1.v.
dosing with 14C-HEX (approximate terminal half-life of 30 hours) suggests
potential for bloaccumulatlon or repeated dosing (Lawrence and Dorough,
1981, 1982).
Rand et al. (1982b) showed that significant changes at the cellular
level 1n lung tissue occurred after HEX Inhalation. HEX vapors affect the
extracellular lining, and 1n some cases, cause significant Increases 1n
hemoglobin and red blood cells. Although more severe effects seem to occur
1 i
by Inhalation, Impaired breathing was seen 1n most experiments regardless of
the route of exposure.
Summary
Little 1s known about the mechanism of HEX toxldty. Because of Us
high reactivity and volatility, attempts to Identify the reactive metabo-
lites of HEX and to characterize Us mechanism of toxldty have been largely
'unsuccessful. Data gaps remain In several areas: 1) the question of
whether similar metabolites are formed following administration by different
routes; 2) comparison of toxldty of the parent compound and Its metabolites
1n eliciting the toxic effects seen following HEX exposure; and 3) Inter-
action of HEX with organic compounds such as hemoglobin. Finally, HEX Is
often contaminated by products used 1n Us manufacture or 1n the manufactur-
ing of other products; therefore, the possibility for co-exposure may exist.
03670 VII-2 08/30/88
-------�
VIII. QUANTIFICATION OF TOXICOLOGIC EFFECTS
Introduction
The quantification of toxlcologlc effects of a chemical consists of
separate assessments of noncarclnogenU and carcinogenic health effects.
Chemicals that do not produce carcinogenic effects! are believed to have a
threshold dose below which no adverse, noncarcinogenic health effects occur,
while carcinogens are assumed to act without a threshold.
In the quantification of noncardnogenic effects, a Reference Dose
(RfD), [formerly termed the Acceptable Daily Intake (ADI)] is 'calculated.
- . . i
The RfD 1s an estimate (with uncertainty spanning perhaps an order magni-
tude) of a dally exposure to the human population (Including sensitive
subgroups) that is likely to be without an appreciable risk of deleterious
health effects during a lifetime. The RfD 1s derived from a no-observed-
adverse-effect level (NOAEL), or lowest-observed-adverse-effect level
(LOAEL), Identified from a subchronlc or chronic study, and divided by an
uncertainty factor(s) times a modifying factor. The RfD Is calculated as
follows: .
RfD . = mg/kg bw/day
[Uncertainty Factor(s) x Modifying Factor]
Selection of the uncertainty factor to be employed 1n the calculation of
the RfD 1s based upon professional judgment, while considering the entire
data base of toxlcologlc effects for the chemical. In order to ensure that
uncertainty factors are selected and applied in a consistent manner, the
03680 VIII-1 04/12/91
-------�
U.S. EPA (1991) employs a modification to the guidelines proposed by the
National Academy of Sciences (NAS, 1977, 1980) as follows:
Standard Uncertainty Factors (UFs)
Use a 10-fold factor when extrapolating from valid experimental
results from studies using prolonged exposure to average healthy
humans. This factor Is Intended to account for the variation
In sensitivity among the members of the human population. [10H]
• Use an additional 10-fold factor when extrapolating from valid
results of long-term studies on experimental animals when
results of studies of human exposure are not available or ares
Inadequate. This factor 1s Intended to account for the uncer-
tainty 1n extrapolating animal data to the case of humans.
[IDA]
Use an additional 10-fold factor when extrapolating from less
than chronic results on experimental animals when there Is no
useful long-term human data. This factor Is Intended to
account for the uncertainty In extrapolating from less than
chronic NOAELs to chronic HOAELs. |10S]
Use an additional 10-fold factor when deriving an RfD from a
LOAEL Instead of a NOAEt. This factor 1s Intended to account
for the uncertainty In extrapolating from LOAELs to NOAELs.
[10L]
Modifying Factor (MF)
Use professional judgment to determine another uncertainty
factor (MF) that 1s greater than zero and less than or equal to
10. The magnitude of the MF depends upon the professional
assessment of scientific uncertainties of the study and data
base not explicitly treated above, e.g., the completeness of
the overall data base and the number of species tested. The
default value for the MF Is 1.
The uncertainty factor used for a specific risk assessment Is based
principally upon scientific judgment rather than scientific fact and
accounts for possible Intra- and Interspedes differences. Additional
considerations not Incorporated 1n the NAS/OOW guidelines for selection of
an uncertainty factor Include the use of a less than lifetime study for
deriving an RfD, the .significance of the adverse health effects and the
counterbalancing of beneficial effects.
03680 VII1-2 04/12/91
-------�
From the RfO, a Drinking Water Equivalent Level (DWEL) can.be calcu-
lated. The DWEL represents a medium specific (I.e., drinking water)
lifetime exposure at which adverse, noncarclnogenlc health effects are not
anticipated to occur. The DWEL assumes 100% exposure from drinking water.
The DWEL provides the noncarclnogenlc health effects basis for establishing
a drinking water standard. For 1ngest1on data, the DWEL Is derived as
t
follows:
DWEL
(RfD) x (Body weight In kg)
Drinking Water Volume 1n i/day
mg/si
where:
Body weight - assumed to be 70 kg for an adult
Drinking water volume = assumed to be 2 l/day for an adult
In addition to the RfD and the DWEL, Health Advisories (HAs) for expo-
sures of shorter duration (1-day, 10-day and longer-term) are'determined.
The HA values are used as Informal guidance to municipalities and other
organizations when emergency spills or contamination situations occur. The
HAs are calculated using an equation similar to the RfD and DWEL; however,
the NOAELs or LOAELs are Identified from acute or subchronlc studies. The
HAs are derived as follows:
HA _ (NOAEL or LQAEL) x (bw) _
(UF) x ( I/day) = —
mg/8.
Using the above equation, the following drinking water HAs are developed
for noncarclnogenlc effects:
1. 1-day HA for a 10 kg child Ingesting 1 8. water per day.
2. 10-day HA for a 10 kg child Ingesting 1 8, water per day.
3. Longer-term HA for a 10 kg child Ingesting 1 I water per day.
4. Longer-term HA for a 70 kg adult Ingesting 2 8. water per day.
03680
VIII-3
04/10/88
-------�
The 1-day HA calculated for a 10 kg child assumes a single acute
exposure to the chemical and Is generally derived from a study of <7 days
duration. The 10-day HA assumes a limited exposure period of 1-2 weeks and
1s generally derived from a study of <30 days duration. The longer-term HA
Is derived for both the 10 kg child and a 70 kg adult and assumes an
exposure period of -7 years (or 10% of an Individual's lifetime). The
longer-term HA 1s generally derived from a study of subehronlc duration
(exposure for 10% of animal's lifetime).
The U.S. EPA categorizes the carcinogenic potential of a chemical, based
on the overall we1ght-of-ey1dence, according to the following scheme:
Group A: Human Carcinogen. Sufficient evidence exists from
epidemiology studies to support a causal association between
exposure to the chemical and human cancer.
Group 8: Probable Human Carcinogen. Sufficient evidence of
cardnogenlclty In animals with limited (Group 81) or Inade-
quate (Group B2) evidence 1n humans.
Group C: Possible Human Carcinogen. Limited evidence of
cardnogenlclty 1n animals In the absence of human data.
Group D: Not Classified as to Human Cardnogenlclty. Inade-
quate human and animal evidence of cardnogenlclty or for which
no data are available.
Group E: Evidence of Noncardnoqenldty for Humans. No
evidence of cardnogenlclty In at least two adequate animal
tests 1n different spedes or In both adequate epldemlologlc
and animal studies.
.If toxlcologlc evidence leads to the classification of the contaminant
as a known, probable or possible human carcinogen, mathematical models are
used to calculate the estimated excess cancer risk associated with the
Ingesllo'n of the contaminant In drinking water. The data used In these
03680 -, VIII-4 04/12/91
-------�
estimates usually come from lifetime exposure studies using animals. In
order to predict the risk for humans from animal data, animal doses must be
converted to equivalent human doses. This conversion Includes correction
for noncontlnuous exposure, less than lifetime studies and for differences
1n size. The factor that compensates for the size difference 1s the cube
root of the ratio of the animal and human body weights. It Is assumed that
•t
the average adult human body weight 1s 70 kg and' that the average water
consumption of an adult human 1s 2 I of water per day.
For contaminants with a carcinogenic potential, chemical levels are
correlated with a carcinogenic risk estimate by employing a cancer potency
(unH risk) value together with the assumption for; lifetime exposure from
1ngest1on of water. The cancer unit risk Is usually derived from a linear-
ized multistage model with a 95% upper confidence limit providing a low dose
estimate; that Is, the true risk to humans, while not Identifiable, 1s not
likely to exceed the upper limit estimate and, 1n fact, may be lower.
Excess cancer risk estimates may also be calculated using other models such
as the one-hit, Welbull, loglt and problt. There 1s little basis In the
current understanding of the biologic mechanisms Involved In cancer to
suggest that any one of these models Is able to predict risk more accurately
than any other. Because each model Is based upon differing assumptions, the
estimates derived for each model can differ by several orders of magnitude.
The scientific data base used to calculate and support the .setting of
cancer risk rate levels has an Inherent uncertainty that Is due to the
systematic and random errors 1n scientific measurement. In most cases, only
v
studies using experimental animals have been performed. Thus, there 1s
03680 VII1-5 04/12/91
-------�
uncertainty when the data are extrapolated to humans. When developing
cancer risk rate levels, several other areas of uncertainty exist, such as
the Incomplete knowledge concerning the health effects of contaminants 1n
drinking water, the Impact of the experimental animal's age, sex an.d
species, the nature of the target organ system(s) examined and the actual
rate of exposure of the Internal targets In experimental animals or humans.
Dose-response data usually are available only for high levels of exposure
and not for the lower levels of exposure closer to where a standard may be
set. When there 1s exposure to more than one contaminant, additional
uncertainty results from a lack of Information about possible synerglstU or
antagonistic effects,
*.
Noncardnogenlc Effects
Limited quantitative Information 1s available regarding the human health
effects resulting from HEX exposure; however, transient or acute exposure to
HEX vapor has been associated with Irritation to the eyes, nose and throat,
as well as headaches and nausea. In animals, comparative studies have
Indicated that HEX exposure 1s more toxic following Inhalation than oral
exposure.
Short-term studies by IRDC (1978) and SRI (1980a,b, 1981a,b) provide
substantial data on oral toxldty to rats and mice. The Southern Research
Institute (SRI, 1981a,b) studies are of longer duration and provide NOAELs
and LOAELs. A Russian study by Na1shte1n and Llsovskaya (1965) was
conducted for 6 months and also yielded no-effect levels; however, an HA
cannot be recommended since the complete study design was not reported.
03680 VIII-6 06/19/90
-------�
More recent studies have been published (SRI, 1980a,b, 1981a,b), which
provide greater detail, use more appropriate toxlcologlc endpoinU .and
define NOAELs and LOAELs than the earlier study by •Nalshteen and llsovskaya
(1965) which served as the basis for the 1980 Ambient Hater Quality Criteria
Document (U.S. EPA, 1980). These studies are reviewed below and have been
used 1n the calculations of the 1-day, 10-day and longer-term HAs and the
lifetime DWEL.
SRI (1980a) conducted a gavage study using HEX with male and female F344
rats and B6C3F1 mice. Dose levels of, 0, 75, 150, 300, 600 and 1200 mg/kg
HEX In corn oil were administered to both rats and mice by gavage. One dose
at each of the five levels was given to five animals of each sex.% Clinical
observations related to the administration of HEX Included a decrease In
activity, ruffled fur, wet fur 1n the anal area and diarrhea. These
alterations occurred within 6-24 hours of dosing; severity and duration were
related to the dose level. All rats In the 600 and 1200 mg/kg dose groups
died, while 1n the 300 mg/kg dose group, two female rats died. In the 150
and 75 mg/kg rat dose groups, ruffled fur occurred, but no deaths. In the
mouse study, all 1200 mg/kg dose group animals died. At the 600 mg/kg
level, only one female and one male mouse died. At the other levels, only
minor effects were observed. The 150 mg/kg rat level, was observed to be the
NOAEL In rats, while the 300 mg/kg was chosen as the NOAEL In mice.
The SRI (1980b) conducted a repeated-dose study In which F344 rats and
B6C3F1 mice were exposed to 0, 25, 50, 100, 200 and 400 mg/kg HEX and 0,
50, 100, 200, 400 -and 800 mg/kg HEX In rats and mice, respectively. All
doses were administered by gavage with corn oil .used as the vehicle. Five
03680
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04/12/91
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mice and five rats of each sex were used for each dose level on a schedule
of 12 dosing days {days 1-5, 8-12, 15 and 16), with at least 2 consecutive
dosing days before the terminal sacrifice began.
In the raj study (SRI, 19805), all males and 4/5 females at the 400
mg/kg HEX dose level died, while at the 200 mg/kg dose, 1/5 males and 4/5
females died. Clinical observations were performed twice dally. At the 100
mg/kg dose level, ruffled fur occurred In all rats. The Investigators Rioted
that there was significant weight depression In both the males and the
females at this dose rate, but there were no deaths or life-threatening
clinical and gross observations. At the 50 mg/kg HEX dose level, there were
no significant clinical signs, but there were gross changes to the stomach
wall and a depression In weight gain. The gross observations at the 50
mg/kg dose level Included discolored raised areas on the mucosal surface of
the stomach 1n 3/5 females and 3/5 males. The decrease In weight gain 1n
males was -17% and females -22%. At the 25 mg/kg level, the clinical and
gross observations did not find any Irregularities. The weight gain
depressions were 8% for males and 11% for females. The 25 mg/kg dose level
was selected as the NOAEL for rats.
In the mouse study (SRI, 1980b), all of the. animals treated at the 800
and 400 mg/kg dose level died. However, one of these deaths was attributed
to Improper gavage technique. At the 200 mg/kg dose level, two animals died
because of Inappropriate experimental techniques, as did one at the 50 mg/kg
level and two of the controls. One animal's death at the 200 mg/kg level
was attributed to chemical toxlclty. The 100 mg/kg HEX dose was determined
to be the NOAEL, since there were effects but none considered adverse.
03680 VIII-8 04/12/91
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In a "13-week oral toxldty study (SRI, 1981a,b; Abdo et al., 1984), HEX
was administered In corn oil by gavage to groups of 10 male and 10 female
F344 rats at doses of 0, 10, 19, 38, 75 and 150 mg/kg and to 10 mice of each
sex at doses of 0, 19, 38, 75, 150 and 300 mg/kg. The doses were glve'n
dally, 5 days a week for 13 weeks. Compared with the previously-reviewed
shorter-term studies, HEX was found to be more toxic at the lower dose
levels. All 10 male and 3 female mice died at' the 300 mg/kg HEX dose
level. At the 150 mg/kg level, six male rats died, while one rat \n the 75
mg/kg group died as a result of chemical toxlclty. Other deaths occurred,
but these were attributed to Improper gavage technique by the Investi-
gators. Stomach lesions (hyperplasla and focal Inflammation) were observed
1n male and female rats at the 38, 75 and 150 mg/kg dose groups and only
female /ats at the 19 mg/kg dose level. At higher doses (>150 mg/kg) toxic
nephrosls In females was observed. According to, the Investigators, these
lesions decreased 1n severity with decreasing dose, with hyperplasla being
the primary lesion. One female rat at the 19 mg/kg dose level had a
squamous cell papllloma of the epithelial surface. The only effect reported
for the 10 mg/kg dose was a slight depression In body weight 1n both males
and females.
In mice (SRI, 1981a), the stomach lesions occurred at the 38 mg/kg and
higher dose levels, Including deaths at the two highest levels. In the
published results (Abdo et al,., 1984), the "no observed toxic effect level"
of HEX was stated to be at the 19 mg/kg level for rats. In addition, the
authors stated that rats of both sexes and female mice are approximately
equally susceptible to the toxic effects.of HEX administered by gavage over
a 90-day period. Therefore, the NOAEL was 10 mg/kg HEX for rats and 19
03680
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04/12/91
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mg/kg for mice. The lower "level 1n rats was selected because' the lesions
were still considered toxic effects, but 1n the long-term may or may not be
adverse. Therefore, by using this level, an added margin of safety Is
Inherent In the calculation of the DUEL. Because HEX toxldty Increase's
with duration,_this NOAEL would accommodate the possibility of these effects
becoming adverse over the longer-term.
Quantification of Honcardnogenlc Effects
Although there 1s some question as to the route of HEX transport In the
body, the kidneys, liver and lungs appear to be the major target organs.
Investigators have observed sex and species differences In toxic response to
HEX. In addition, some observed effects In these studies may have resulted
from a combined exposure to HEX and other compounds. In the Abdo et al.
(1984) study, hexachloro-1,3-butad1ene (HCBD) was present as a contaminant
of HEX. Since HCBD Is a known nephrotoxln 1n rodents, some of the adverse
effects seen 1n the study may be attributed to either or both compounds.
Derivation of 1-Day HA. In the range-finding study by SRI (1980a)
rats exposed to a single oral dose of 150 mg/kg HEX experienced "wet fur 1n
anal area" and ruffled fur when observed for 14 days. No other toxic
effects were seen at this dose level. At higher doses, mortality and
diarrhea were observed. A NOAEL of ISO mg/kg can be derived based on the
absence of adverse effects seen at this level.
The 1-day HA for a child 1s calculated as follows:
i H*U UA 150 mg/kq x 10 kg 1C m .a
1-day HA = a—• a =15 mg/l
100 x 1 a/day
03680 VI11-10 04/12/91
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where:
150 mg/kg = determined to be the NOAEL of the SRI (19803). rat
study
10 kg = assumed body weight of a child
1 l/day = assumed water consumption by a child
100 = uncertainty factor chosen In accordance with
NAS/ODW and Agency guidelines In using a NOAEL from
an animal study
This HA 1s equivalent to 15 mg/day or 1.5 mg/kg/day. It should be noted
that this level (15 mg/l) 1s above the reported water solubility of HEX
(1.2-3.4 mg/l) under normal ambient conditions; however, under certain
conditions (e.g.. Increased temperature) the water solubility of HEX can
&
Increase.
Derivation of 10-Day HA. The SRI (1980b) repeated-dose toxldty study
was used. In this study a NOAEL of 25 mg/kg, based on no significant
decreases 1n weight gain 1n .male and female rats was defined following
-exposure to 25, 50, 100. 200 and 400 mg/kg HEX for 12 days (days 1-5, 8-12,
and 15 and 16).
The 10-day HA for a child Is calculated as follows:
10-day HA = 2S "^ x 10 k9 x °-714 = i.e ng/t (rounded to 2 mg/t)
100 x 1 l/day y
where:
25 mg/kg * determined to be the NOAEL of the SRI (1980b) female
rat study
10 kg = assumed body weight of a child
0.714 = the correction factor (5/7) to adjust for continuous
exposure from a 5- to 7-day exposure
03680
VIII-11 . 06/11/91
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100 = uncertainty factor chosen 1n accordance with NAS/ODW
and Agency guidelines for use with a NOAEL from an
animal study
1 s,/day = assumed water consumption by a child
This HA Is equivalent to 1.8 mg/day or 0.18 mg/kg/day.
Derivation of Longer -Term HA. The 13-week oral tox1c1ty study by SRI
(1981b) 1s the only longer-term oral study of sufficient duration and
experimental design that can be used for calculating longer-term HAs. In
this study, HEX was administered In corn oil by gavage to groups of 10 male
and female F344 rats at doses of 0, 10, 19, 38, 75 and 150 mg/kg.
TreatmentTrelated dose-dependent adverse effects Including Inflammation of
the stomach were seen with . Increasing severity at >19 mg/kg. The only
«
effect reported at the 10 mg/kg dose was a slight depression In body weight
1n males and females.
The longer-term HA for a chl.ld Is calculated as follows:
Longer-term HA . 10 "^ x 10 "* x °'714 . 0.7 mgA
100 x 1 t/day
This HA Is equivalent to 0.07 mg/kg/day.
where:
10 mg/kg = NOAEL from the SRI (1981b; Abdo et al., 1984) study
based on absence of stomach lesions
10 kg = assumed body weight of a child
0.714 = the correction factor (5/7) to adjust for
continuous exposure from a 5- to 7-day exposure
100 = uncertainty factor chosen 1n accordance with
NAS/ODW and Agency guidelines for use with a NOAEL
from an animal study
03680 VIII-12 04/12/91
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1 I/day = assumed water consumption by a chUd
For an adult:
u*
Longer-term HA .
10 mq/kq x 70 kg x 0.714
- 2i/day xlOOj roundeo 3 ng/i)
_ ? 5 .
ll't
where:
10 mg/kg = NOAEL from the SRI (19815; Abdo- et al., 1984) study
based on absence of stomach lesions
70 kg = assumed body weight of an adult
0.714 = the correction factor {5/7') to adjust for
continuous exposure from a 5- to 7-day exposure
2 I/day = assumed water'consumption by arradult
100 = uncertainty factor chosen 1n accordance with
NAS/ODW and Agency guidelines for use with a NOAEL
from an animal study
Assessment of Lifetime Exposure and Derivation of DHEL. In a 13-week
oral toxlclty study by SRI (1981b), rats (10/sex/group) were exposed by
gavage with 0, 10, 19, 38, 75 or 150 mg HEX/kg bw 'for 5 days/week.
Epithelial hyperplasla, focal Inflammation of the forestomach and stomach
lesions, and nephrosls were observed with Increased Incidence and severity
1n both sexes at >38 mg/kg bw. At the 19 mg/kg/day dose similar effects
were observed In males only. A slight but nonsignificant depression 1n body
weight gain was seen at 10 mg/kg In males and, 1n females at 19 mg/kg.
Therefore the 10 mg/kg dose was considered a NOAEL and the 19 mg/kg dose a
LOAEL.
Step 1; Determination of RfD
RfD
10 mq/kq x 0.714
100 x 10
0.00714 mg/kg/day (rounded to 0.007 mg/kg/day)
03680
. VIII-13
06/11/91
-------�
where:
10 mg/kg = NOAEL from the SRI (19815; Abdo et al., 1984) study
based on a lack of adverse effects
0.714 = the correction factor (5/7) to adjust for. continuous
exposure from a 5- to 7-day exposure
100 •* uncertainty factor chosen In accordance with NAS/ODW
and Agency guidelines for use with a NOAEL from an
animal study
10 = uncertainty factor appropriate for use with study data
that are significantly Iess-than-l1fet1me 1n duration
Step 2: Determination of the Drinking Hater Equivalent Level (DWEL)
DHEL = 0.007 mq/kq/dayx 70 kq __ ^ '
2 a/day
where: .
0.007 mg/kg/day = RfD
70 kg = assumed weight of an adult
2 I/day • = assumed water consumption by an adult
A summary of noncarclnogenlc effects 1s listed 1n Table VIII-1.
Carcinogenic Effects
The data base 1s neither extensive nor adequate for 'assessing the
cardnogenldty of HEX. The National Toxicology Program (NTP) has completed
a subchronlc animal Inhalation study and Is presently conducting a lifetime
animal Inhalation bloassay using both rats and mice. A judgment of
carcinogenic potential will be deferred until the results of the long-term
NTP bloassay are available. Using the IARC criteria, the available evidence
matches the overall Group 3 category. According to the U.S. EPA Guidelines
for Carcinogen Risk Assessment, this chemical 1s classified 1n the Group 0
03680 VIII-14 06/11/91
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TABLE VIII-1
Summary of HAs and DWEL for Noncarclnogenlc Effects
Drinking Water
Concentration
(mg/l)
Reference
1-Day HA (10 kg child)
10-Day HA (10 kg child)
Longer-term HA (10 kg child)
Longer-term HA (70 kg adult)
DWEL
15
2
0.7
3
0.3
SRI, 1980a
SRI, 1980b
SRI, 1981b
SRI, 1981b
SRI, 1981b
03680
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06/12/91
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category, which Indicates that the available data base 1s Inadequate to
assess the carcinogenic potential of this substance (U.S. EPA, 1986).
Exlsuing Guidelines. Recommendations and Standards
EPA Guidelines. An RfD of 0.007 mg/kg/day was verified by the RfO
Work Group on-10X09/85 (U.S. EPA, 1991). The CRAVE Work Group verified a
classification of Group D (not classifiable as to cardnogenlcHy for
humans) for HEX on 10/05/89 (U.S. EPA, 1991).
Occupational Standards. There 1s no current Occupational Safety and
Health Administration (OSHA) standard for HEX levels In the workplace.
However, the American Conference of Governmental Industrial Hyg1en1sts
(ACGIH, 1986) has adopted a TIV, expressed as an 8-hour TWA of'0.1 mg/m3
(0.01 ppm}. The levels are based on the data from the Inhalation study by
Treon et al. (1955).
The National Institute for Occupational Safety and Health (N10SH, 1978)
classlfed HEX 1n the Group II pesticide category and recommended criteria
for standards for occupations 1n pesticide manufacturing and formulating.
These standards rely on engineering controls, work practices and medical
surveillance programs, rather than workplace air limits, to protect workers
from the adverse effects of pesticide exposure In manufacturing and formu-
lating (NIOSH, 1978).
Transportation Regulations. The Hazardous Materials Transportation
Act specifies the requirements to be observed 1n the preparation for ship-
ment and transport of hazardous materials. The transport of HEX by air,
03680 . VIII-16 04/12/91
-------�
land and water 1s regulated by these statutes, and the Department of Trans-
portation has designated HEX as "hazardous material," a "corrosive material"
and a "hazardous substance." The maximum net quantity for transport by
passenger-carrying aircraft or rallcar has been set at 10 gallons per
package. Transport on deck or below deck by cargo vessel 1s also permitted.
Solid Haste Regulations. Under the Resource Conservation and Recovery
Act (RCRA), the U.S. EPA has designated HEX as a hazardous toxic waste.
Hazardous Haste No. U 130, subject to disposal and permit regulations (40
CFR 262-265 and 122-124).
Food Tolerances. Under the Federal Insecticide Fumlgant and RodenU-
dde Act (F1FRA), a tolerance of 0.3 ppm has been established for chlordane
residues, which are not to contain >1% of HEX (40 CFR 180.122).
Hater Regulations. Under Section 311 of the: Federal Water Pollution
Control Act, the U.S. EPA designated HEX as a hazardous substance and estab-
lished a reportable quantity (RQ) of 1 pound (0.454 kg) for HEX. Discharges
equal to or greater than .the RQ Into or upon U.S. waters are prohibited
unless the discharge Is 1n compliance with applicable permit programs.
Under the Clean Water Act, the U.S. EPA has designated HEX as a toxic
pollutant (I.e., priority pollutant). Effluent limitations guidelines, new
source performance standards, and pretreatment standards have been developed
or will be developed for the.priority pollutants for 21 major Industries.
Under the Clean Water Act, an ambient water quality criteria level for
HEX was also developed (U.S. EPA, 1980). Based on available toxlclty data
03680 V1II-17 04/12/91
-------�
for the protection of public health the level derived was 206
Using organoleptlc data for controlling undesirable taste and odor of
ambient water, the estimated level was 1 vg/i (U.S. EPA, 1980).
A1r Regulations. HEX 1s not regulated under the Clean Air Act. The
U.S.. EPA, after evaluating the current exposure data and ambient air levels
of HEX, Issued a decision not to list HEX as a hazardous air pollutant.
Other Regulations. Pursuant to rules under sections 8(a) and 8(d) of
the Toxic Substances Control Act (TSCA), all manufacturers of HEX are
required to report health and safety Information on HEX to the U.S. EPA's
Office of Toxic Substances. The deadline for submission of Preliminary
Assessment Information Manufacturer's Report on HEX was November 19, 1982.
In 1979, the Interagency Testing Committee (ITC) recommended that HEX be
considered for health and environmental effects testing under Section 4{a)
of the TSCA (44 FR 31866). This recommendation was based on evidence of
potential human exposure and a potential for environmental persistence and
bloaccumulatlon. The U.S. EPA (1982) responded 1n the Federal Register.
The following 1s the statement from that notice:
EPA has decided not to Initiate rulemaklng to require testing of
HEX under section 4 of TSCA because EPA does not believe that there
Is a sufficient basis to find that current manufacture, distribu-
tion In commerce, processing, use or disposal of HEX may present an
•unreasonable risk of Injury to the environment or of mutagenlc and
teratogenlc health effects. Neither has the EPA found evidence
that there Is substantial or significant environmental release of
HEX. In addition, certain new studies have become available since
the ITC's report or are underway, making additional testing for
chronic and oncogenlc effects unnecessary.
03680 V1II-18 04/12/91
-------�
Special Groups at Risk
While very little data are available concerning the effects of HEX
exposure on humans, H 1s apparent that those Individuals with respiratory
problems or diffidences will be most sensitive to HEX exposure. Workers
repeatedly exposed to HEX vapors are also at high risk.
03680
VI1I-19
04/12/91
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-------�
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04/12/91
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