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WHO/SDE/WSH/03.04/92
                                        English only




    Endosulfan in Drinking-water


 Background document for development of
WHO Guidelines for Drinking-water Quality
© World Health Organization 2004

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expression of any opinion whatsoever on the part of the World Health Organization concerning the legal
status of any country, territory, city or area or of its authorities, or concerning the delimitation of its
frontiers or boundaries.
The mention of specific companies or of certain manufacturers' products does not imply that they are
endorsed or recommended by the World Health Organization in preference to others of a similar nature
that are not mentioned. Errors and omissions excepted, the names of proprietary products are
distinguished by initial capital letters.
The World Health Organization does not warrant that the information contained in this publication is
complete and correct and shall not be liable for any damage incurred as a results of its use.
Preface

One of the primary goals of WHO and its member states is that “all people, whatever
their stage of development and their social and economic conditions, have the right to
have access to an adequate supply of safe drinking water.” A major WHO function to
achieve such goals is the responsibility “to propose ... regulations, and to make
recommendations with respect to international health matters ....”

The first WHO document dealing specifically with public drinking-water quality was
published in 1958 as International Standards for Drinking-water. It was subsequently
revised in 1963 and in 1971 under the same title. In 1984–1985, the first edition of the
WHO Guidelines for Drinking-water Quality (GDWQ) was published in three
volumes: Volume 1, Recommendations; Volume 2, Health criteria and other
supporting information; and Volume 3, Surveillance and control of community
supplies. Second editions of these volumes were published in 1993, 1996 and 1997,
respectively. Addenda to Volumes 1 and 2 of the second edition were published in
1998, addressing selected chemicals. An addendum on microbiological aspects
reviewing selected microorganisms was published in 2002.

The GDWQ are subject to a rolling revision process. Through this process, microbial,
chemical and radiological aspects of drinking-water are subject to periodic review,
and documentation related to aspects of protection and control of public drinking-
water quality is accordingly prepared/updated.

Since the first edition of the GDWQ, WHO has published information on health
criteria and other supporting information to the GDWQ, describing the approaches
used in deriving guideline values and presenting critical reviews and evaluations of
the effects on human health of the substances or contaminants examined in drinking-
water.

For each chemical contaminant or substance considered, a lead institution prepared a
health criteria document evaluating the risks for human health from exposure to the
particular chemical in drinking-water. Institutions from Canada, Denmark, Finland,
France, Germany, Italy, Japan, Netherlands, Norway, Poland, Sweden, United
Kingdom and United States of America prepared the requested health criteria
documents.

Under the responsibility of the coordinators for a group of chemicals considered in the
guidelines, the draft health criteria documents were submitted to a number of
scientific institutions and selected experts for peer review. Comments were taken into
consideration by the coordinators and authors before the documents were submitted
for final evaluation by the experts meetings. A “final task force” meeting reviewed the
health risk assessments and public and peer review comments and, where appropriate,
decided upon guideline values. During preparation of the third edition of the GDWQ,
it was decided to include a public review via the world wide web in the process of
development of the health criteria documents.
During the preparation of health criteria documents and at experts meetings, careful
consideration was given to information available in previous risk assessments carried
out by the International Programme on Chemical Safety, in its Environmental Health
Criteria monographs and Concise International Chemical Assessment Documents, the
International Agency for Research on Cancer, the joint FAO/WHO Meetings on
Pesticide Residues and the joint FAO/WHO Expert Committee on Food Additives
(which evaluates contaminants such as lead, cadmium, nitrate and nitrite, in addition
to food additives).

Further up-to-date information on the GDWQ and the process of their development is
available on the WHO internet site and in the current edition of the GDWQ.
Acknowledgements

The first draft of Endosulfan in Drinking-water, Background document for
development of WHO Guidelines for Drinking-water Quality, was prepared by Dr P.
Toft, Canada, to whom special thanks are due.

The work of the following working group coordinators was crucial in the
development of this document and others in the third edition:

       Mr J.K. Fawell, United Kingdom (Organic and inorganic constituents)
       Dr E. Ohanian, Environmental Protection Agency, USA (Disinfectants and
          disinfection by-products)
       Ms M. Giddings, Health Canada (Disinfectants and disinfection by-products)
       Dr P. Toft, Canada (Pesticides)
       Prof. Y. Magara, Hokkaido University, Japan (Analytical achievability)
       Mr P. Jackson, WRc-NSF, United Kingdom (Treatment achievability)

The contribution of peer reviewers is greatly appreciated. The draft text was posted on
the world wide web for comments from the public. The revised text and the comments
were discussed at the Final Task Force Meeting for the third edition of the GDWQ,
held on 31 March to 4 April 2003, at which time the present version was finalized.
The input of those who provided comments and of participants in the meeting is
gratefully reflected in the final text.

The WHO coordinators were as follows:

       Dr J. Bartram, Coordinator, Water Sanitation and Health Programme, WHO
          Headquarters, and formerly WHO European Centre for Environmental
          Health
       Mr P. Callan, Water Sanitation and Health Programme, WHO Headquarters
       Mr H. Hashizume, Water Sanitation and Health Programme, WHO
          Headquarters

Ms C. Vickers provided a liaison with the International Chemical Safety Programme,
WHO Headquarters.

Ms Marla Sheffer of Ottawa, Canada, was responsible for the scientific editing of the
document.

Many individuals from various countries contributed to the development of the
GDWQ. The efforts of all who contributed to the preparation of this document and in
particular those who provided peer or public domain review comment are greatly
appreciated.
Acronyms and abbreviations used in the text

ADI     acceptable daily intake
ATSDR   Agency for Toxic Substances and Disease Registry (USA)
CAS     Chemical Abstracts Service
FAO     Food and Agriculture Organization of the United Nations
IPCS    International Programme on Chemical Safety
JMPR    Joint FAO/WHO Meeting on Pesticide Residues
LC50    median lethal concentration
LD50    median lethal dose
NOAEL   no-observed-adverse-effect level
USA     United States of America
WHO     World Health Organization
Table of contents

1. GENERAL DESCRIPTION....................................................................................... 1
   1.1 Identity .................................................................................................................. 1
   1.2 Physicochemical properties .................................................................................. 1
   1.3 Major uses............................................................................................................. 1
   1.4 Environmental fate................................................................................................ 1

2. ANALYTICAL METHODS ...................................................................................... 2

3. ENVIRONMENTAL LEVELS AND HUMAN EXPOSURE................................... 2
   3.1 Air ......................................................................................................................... 2
   3.2 Water..................................................................................................................... 2
   3.3 Food ...................................................................................................................... 2
   3.4 Estimated total exposure and relative contribution of drinking-water.................. 3

4. KINETICS AND METABOLISM IN LABORATORY ANIMALS AND
HUMANS ....................................................................................................................... 3

5. EFFECTS ON EXPERIMENTAL ANIMALS AND IN VITRO TEST SYSTEMS.. 3

6. EFFECTS ON HUMANS........................................................................................... 7

7. CONCLUSIONS......................................................................................................... 7

8. REFERENCES ........................................................................................................... 7
Endosulfan has negligible residues in drinking water   who report
1. GENERAL DESCRIPTION

1.1 Identity

 CAS No.:                   115-29-7
 Molecular formula:         C9H6Cl6O3S

The chemical name of endosulfan is 6,7,8,9,10,10-hexachloro-1,5,5a,6,9,9a-
hexahydro-6,9-methano-2,4,3-benzodioxathiepin-3-oxide. Technical endosulfan is a
brown crystalline substance consisting of α- and β-isomers in the ratio of
approximately 70:30. Endosulfan’s chemical structure is shown below:




1.2 Physicochemical properties

Technical endosulfan is usually sold in the form of brown crystalline flakes.

 Property                Value
 Melting point           79–100 °C
 Vapour pressure         1.3 × 10-3 Pa at 25 °C
 Solubility in water     60–150 µg/litre; increases with decreasing pH

1.3 Major uses

Endosulfan is a contact and stomach poison that has been used to control insects such
as the Colorado potato beetle, flea beetle, cabbageworm, peach tree borer and
tarnished plant bug, as well as several species of aphid and leafhopper. It is used in
countries throughout the world to control pests on fruit, vegetables and tea and on
non-food crops such as tobacco and cotton. In addition to its agricultural use and its
use in the control of the tsetse fly, endosulfan is used as a wood preservative and for
the control of home garden pests (IPCS, 1984).

1.4 Environmental fate

Both endosulfan isomers undergo photolysis upon exposure to sunlight. The half-life
is about 7 days. Endosulfan diol is the primary photolysis product; it is subsequently
degraded to endosulfan α-hydroxy ether (ATSDR, 2000).

In water, endosulfan undergoes hydrolysis to endosulfan diol. The rate of hydrolysis
is influenced by pH. Oxidative degradation also occurs. At pH 7, the half-lives for
hydrolysis and oxidation were 23 and 25 days, respectively; at pH 5, the half-lives
were 54 and 51 days, respectively (ATSDR, 2000).
                                                  1
ENDOSULFAN IN DRINKING-WATER


Endosulfan released to soil is subject to biodegradation. Biodegradation in soil and
water is dependent on climatic conditions and on the type of microorganisms present.
Endosulfan sulfate is the major degradation product in soil and is persistent in the soil
(ATSDR, 2000).

2. ANALYTICAL METHODS

The method of choice for the determination of endosulfan involves extraction from
water with methylene chloride followed by gas chromatography combined with
electron capture detection. In considering residue levels, the sum of the α- and β-
isomers plus the endosulfan sulfate metabolite, which is similar in toxicity to the
parent compound, have to be considered. Detection limits are 0.015 µg/litre for α-
endosulfan, 0.024 µg/litre for β-endosulfan and 0.015 µg/litre for endosulfan sulfate
(ATSDR, 2000).

3. ENVIRONMENTAL LEVELS AND HUMAN EXPOSURE

3.1 Air

Residues of α- and β-endosulfan have been detected in ambient air samples in the
USA (Kutz et al., 1976). Between 1970 and 1972, α-endosulfan was found in 2.11%
of samples tested in the USA at a mean concentration of 111.9 ng/m3 and a maximum
of 2256 ng/m3. During the same period, β-endosulfan was present in 0.32% of the
samples at a mean concentration of 22.0 ng/m3 and a maximum of 54.5 ng/m3. This
information suggests that the α-isomer is more persistent in air. Both α- and β-
endosulfan have been detected at levels up to 12 ng/litre in precipitation in the Great
Lakes area of Canada and the USA (Strachan et al., 1980).

3.2 Water

Endosulfan contamination does not appear to be widespread in the aquatic
environment, but endosulfan has been found in agricultural runoff and rivers in
industrialized areas where it is manufactured or formulated (IPCS, 1984). Endosulfan
(one or both of its isomers) has been identified in 24 surface water and 103
groundwater samples collected from 164 hazardous waste sites in the USA. Surface
water samples in the USA generally contain less than 1 µg/litre (ATSDR, 2000).

3.3 Food

The main source of exposure of the general population is food, but residues have
generally been found to be well below the FAO/WHO maximum residue limits
(IPCS, 1984). These residue tolerances refer to the total residue of α- and β-
endosulfan and endosulfan sulfate. Because of its use in tobacco farming, smoking
may be an additional source of endosulfan exposure.


                                         2
ENDOSULFAN IN DRINKING-WATER

In a market basket survey conducted in the USA in 1986–1991, intakes of 2.3–3.8 ×
10-6 mg/kg of body weight for α-endosulfan and 6.5–9.9 × 10-6 mg/kg of body weight
for β-endosulfan were reported (ATSDR, 2000).

3.4 Estimated total exposure and relative contribution of drinking-water

With good agricultural practice, endosulfan residues in food should not be significant.
Generally, endosulfan concentrations in air and water are very low and localized and
accordingly of no significance as far as risk for the general population is concerned
(IPCS, 1984). The most important routes of exposure to endosulfan for the general
population are ingestion of food and the use of tobacco products with endosulfan
residues remaining after treatment (ATSDR, 2000).

4. KINETICS AND METABOLISM IN LABORATORY ANIMALS AND
   HUMANS1

More than 90% of an oral dose of endosulfan was absorbed in rats, with maximum
plasma concentrations occurring after 3–8 h in males and about 18 h in females.
Elimination occurs mainly in the faeces and to a lesser extent in the urine, more than
85% being excreted within 120 h. The highest tissue concentrations were in the
kidneys. The metabolites of endosulfan include endosulfan sulfate, diol, hydroxy-
ether, ether and lactone, but most of its metabolites are polar substances that have not
yet been identified. Endosulfan would not be expected to accumulate significantly in
human tissues.

5. EFFECTS ON EXPERIMENTAL ANIMALS AND IN VITRO TEST
   SYSTEMS2

A battery of tests for acute toxicity in several species with technical-grade endosulfan
showed that it is highly toxic after oral or dermal administration, with respective LD50
values of 10–160 mg/kg of body weight and 45–135 mg/kg of body weight. The LC50
value for rats in a single study was 13 mg/m3 in females and 35 mg/m3 in males.
Endosulfan, administered by any route, is more toxic to female than to male rats.
Clinical signs of acute intoxication include piloerection, salivation, hyperactivity,
respiratory distress, diarrhoea, tremors, hunching and convulsions. WHO (2001) has
classified endosulfan as “moderately hazardous.”

The kidney is the target organ for toxicity. The renal effects include increased renal
weights and granular pigment formation after short-term administration and
progressive, chronic glomerulonephrosis or toxic nephropathy after long-term
exposure, although the observation of progressive glomerulonephrosis is complicated
by the fact that this is a common lesion in aging laboratory rats and occurs at high
incidence in control rats.


1
    This section has been taken from FAO/WHO (1999).
2
    This section has been taken from FAO/WHO (1999).
                                                3
ENDOSULFAN IN DRINKING-WATER

In a 90-day feeding study in rats, the cytoplasm of isolated cells in the renal proximal
convoluted tubules had a yellowish colour, particularly in males, at all dietary
concentrations from 10 mg/kg. The presence of this yellow pigmentation was largely
reversible during a 4-week recovery period, and it did not appear to indicate
nephrotoxicity. A darker, more particulate, granular and/or clumped pigment was also
observed, predominantly in cells of the straight portions and occasionally in the
proximal convoluted tubules, at dietary concentrations of 30 mg/kg and above. This
darker pigment was more persistent than the yellow one, and urinalysis revealed
darker urine and marginally more ketones at doses from 60 mg/kg and marginally
more protein, particularly in males, indicating renal damage, at doses of 360 mg/kg
and above. Similar findings emerged from a multigeneration study but not from a 2-
year study of carcinogenicity in rats. The changes in pigmentation were considered to
be due to the presence of endosulfan and/or its metabolites in the enlarged lysosomes.
To test this hypothesis, a 4-week feeding study was conducted in which male rats
were given dietary concentrations of 360 or 720 mg of endosulfan per kg. Light and
electron microscopy of the kidneys of these animals clearly showed increases in the
number of lysosomes and the size of cells in the convoluted tubule, probably as a
result of accumulation of the test material and/or its metabolites. Lysosomal changes
were not observed in either brain or liver, and the renal changes receded appreciably
during a 30-day recovery period. Chemical analysis of the kidneys indicated the
presence of α-endosulfan and, to a lesser extent, β-endosulfan sulfate and endosulfan
lactone. The concentrations of the dominant α-endosulfan in the kidneys were about
50 times those in the liver. The concentrations in blood were usually below the level
of detection. After the 30-day recovery period, renal α-endosulfan was detected only
in traces and β-endosulfan not at all. Similar analysis of tissues from rats in the 2-year
study of toxicity and carcinogenicity did not reveal the presence of these substances in
the kidney, although measurable α-endosulfan was found in the liver at 75 mg/kg. The
yellow colour therefore indicates the presence of endosulfan and/or its metabolites,
rather than either a stage in the pathogenesis of nephropathy or an independent
expression of toxicity. It was postulated that in longer studies, its removal from
lysosomes is accelerated by enzyme induction, which has not been investigated.

Groups of 50 Sprague-Dawley rats of each sex were fed diets containing endosulfan
at concentrations of 0, 3, 7.5, 15 or 75 mg/kg, equal to 0, 0.1, 0.3, 0.6 and 2.9 mg/kg
of body weight per day for males and 0, 0.1, 0.4, 0.7 and 3.8 mg/kg of body weight
per day for females, for 104 weeks. Reductions in body weights and body weight
gains were observed in males and females at 75 mg/kg, but no clinical signs of
poisoning were seen at any dose. No increase in mortality rates was observed in
treated groups. Increased incidences of enlarged kidneys in females and of aneurysms
and enlarged lumbar lymph nodes in males were seen at 75 mg/kg. Histopathological
examination showed that males at 75 mg/kg had an increased incidence of aneurysm
and marked progressive glomerulonephrosis. The most common neoplasms were
pituitary tumours in males and females and mammary tumours in females, but the
increased incidences did not appear to be related to treatment. The NOAEL was 15
mg/kg, equal to 0.6 mg/kg of body weight per day, on the basis of reduced body
weights and pathological findings at higher doses.

                                          4
ENDOSULFAN IN DRINKING-WATER

Groups of 50 B6C3F1 mice of each sex were fed diets containing technical-grade
endosulfan at time-weighted average concentrations of 3.5 or 6.9 mg/kg for males and
2 or 3.9 mg/kg for females for 78 weeks. There were no clear compound-related
effects on appearance or behaviour in the treated groups, and the body weights of both
males and females were unaffected by treatment. The mortality rate of males at the
high dose was increased early in treatment, whereas the mortality rates of female mice
were not affected by treatment. No treatment-related clinical signs were recorded, and
no treatment-related neoplastic lesions were seen in the females. Owing to the high
early mortality rates, no conclusion could be drawn about the carcinogenic potential
of endosulfan in males. None of the non-neoplastic changes seen in the kidneys and
sex organs of male and female mice could be attributed to treatment. The NOAEL for
female mice was 3.9 mg/kg, equal to 0.58 mg/kg of body weight per day.

Groups of six beagle dogs of each sex were fed diets containing technical-grade
endosulfan at concentrations of 0, 3, 10 or 30 mg/kg for 1 year, calculated to be
equivalent to 0, 0.23, 0.77 and 2.3 mg/kg of body weight per day. Some animals given
endosulfan at 30 mg/kg throughout the 12-month study had violent contractions of the
abdominal muscles (without vomiting), and males at this dose had reduced body
weight gains throughout the study and slightly reduced body weights in the latter
stages of the study, in comparison with control animals. Cholinesterase activity was
measured in serum, erythrocytes and brain, but difficulty appears to have been
experienced in measuring these activities, and there were large variations within
groups for the brain enzyme, the group mean of which was increased in dogs at 30
mg/kg. No other effects related to treatment were observed, and no increase in the
incidence of neoplastic or non-neoplastic lesions was observed in treated animals. The
NOAEL was 10 mg/kg, calculated to be equivalent to 0.77 mg/kg of body weight per
day, on the basis of clinical signs and reductions in body weight.

In a 78-week study, exposure of rats to endosulfan at a high dose of 20 mg/kg of body
weight per day resulted in testicular atrophy, characterized by degeneration and
necrosis of the germinal cells lining the seminiferous tubules. In addition, decreased
sperm counts accompanied by an increased incidence of sperm abnormalities have
been reported in mice, again at high doses of endosulfan. Reductions in the activities
of some testicular xenobiotic-metabolizing enzymes and some hormones that are
necessary for normal testicular function were also seen in a 30-day study in rats at 10
mg/kg of body weight per day, but not at 7.5 mg/kg of body weight per day. The
functional significance of these findings was not clear, as studies of reproductive and
developmental toxicity in rats and rabbits showed neither impaired fertility nor any
increase in the incidence of defects or abnormalities in offspring. Given the high
doses at which these testicular effects were observed, it would appear that they are of
little human significance.

No genotoxic activity was observed in an adequate battery of tests for mutagenicity
and clastogenicity in vitro and in vivo. The JMPR Meeting concluded that endosulfan
is not genotoxic.


                                          5
ENDOSULFAN IN DRINKING-WATER

No carcinogenic effect was observed in mice at 18 mg/kg for 24 months, in female
rats at 445 mg/kg for 78 weeks in one study or in male or female rats at 75 mg/kg or
100 mg/kg for 2 years in two other studies. The JMPR Meeting noted the differences
in the dietary concentrations used in these studies, but non-neoplastic responses were
seen even at the lower doses.

Endosulfan at dietary concentrations of 0, 3, 15 or 75 mg/kg did not affect
reproductive performance or the growth or development of the offspring of rats over
the course of a two-generation study. The NOAEL was 75 mg/kg, the highest dose
tested, equal to 5 mg/kg of body weight per day for males and 6.2 mg/kg of body
weight per day for females. The NOAEL for parental toxicity was 15 mg/kg, equal to
1 mg/kg of body weight per day for males and 1.2 mg/kg of body weight per day for
females, on the basis of increased liver and kidney weights at 75 mg/kg.

In two studies of developmental toxicity in rats given oral doses of 0, 0.66, 2 or 6
mg/kg of body weight per day, the NOAEL for maternal toxicity was 0.66 mg/kg of
body weight per day in one study and 2 mg/kg of body weight per day in the other. In
the first case, the basis was decreased body weight gain at 2 mg/kg of body weight per
day and decreased body weight gain and clinical signs of toxicity at 6 mg/kg of body
weight per day; in the second case, the basis was mortality, clinical signs of toxicity
and decreased body weight gain at 6 mg/kg of body weight per day. In both studies,
the NOAEL for developmental toxicity was 2 mg/kg of body weight per day, in the
first case on the basis of delayed development and a low incidence of skeletal
variations seen at 6 mg/kg of body weight per day and in the second on the basis of an
increased incidence of fragmented thoracic vertebral centra seen at 6 mg/kg of body
weight per day. In neither study was there any treatment-related major malformation.

In a study of developmental toxicity in rabbits given oral doses of 0, 0.3, 0.7 or 1.8
mg/kg of body weight per day, the NOAEL for maternal toxicity was 0.7 mg/kg of
body weight per day on the basis of clinical signs of toxicity at 1.8 mg/kg of body
weight per day. The NOAEL for developmental toxicity was 1.8 mg/kg of body
weight per day, the highest dose tested.

Several recent studies have shown that endosulfan, alone and in combination with
other pesticides, may bind to estrogen receptors and may perturb the endocrine
system. The available studies show only very weak binding to hormone receptors in
vitro, and the evidence for their relevance to adverse physiological effects in vivo is
extremely limited. Long-term assays of toxicity and studies of reproductive and
developmental toxicity in experimental mammals did not indicate that endosulfan
induces functional aberrations that might result from loss of endocrine homeostasis.

The absence of immunotoxic effects in a large number of bioassays with endosulfan
suggested that it does not have an adverse effect on the immune function of laboratory
animals. However, in two studies, rats given endosulfan in the diet at 30 or 50 mg/kg
for 6 weeks or 20 mg/kg for 22 weeks had reduced serum titres of tetanus toxoid
antibody, reduced immunoglobulins G and M and inhibition of migration of both
leukocytes and macrophages. These findings have not been confirmed.
                                        6
ENDOSULFAN IN DRINKING-WATER


6. EFFECTS ON HUMANS3

In a summary of case reports of human poisoning incidents, the lowest reported dose
that caused death was 35 mg/kg of body weight. Higher doses caused death within 1
h. The clinical signs in these patients were dominated by tonic-clonic convulsions,
consistent with the observations in experimental animals.

7. CONCLUSIONS

An ADI of 0.006 mg/kg of body weight was established on the basis of the NOAEL
of 0.6 mg/kg of body weight per day in the 2-year dietary study of toxicity in rats and
using a safety factor of 100. The ADI is supported by similar NOAEL values in the
78-week dietary study of toxicity in mice (0.58 mg/kg of body weight per day), the 1-
year dietary study of toxicity in dogs (0.77 mg/kg of body weight per day) and the
study of developmental toxicity in rats (0.66 mg/kg of body weight per day for
maternal toxicity).

A health-based value of 20 µg/litre can be calculated on the basis of the ADI of 0.006
mg/kg of body weight, with an allocation of 10% of the ADI to drinking-water, and
with the assumption that a 60-kg adult consumes 2 litres of drinking-water per day.
However, endosulfan usually occurs at concentrations in drinking-water well below
those at which toxic effects can be expected to occur, and it is therefore not
considered necessary to derive a guideline value for endosulfan in drinking-water.

8. REFERENCES
ATSDR (2000) Toxicological profile for endosulfan. Atlanta, GA, US Department of Health and
Human Services, Public Health Service, Agency for Toxic Substances and Disease Registry.

FAO/WHO (1999) Pesticide residues in food — 1998 evaluations. Part II — Toxicological. Geneva,
World Health Organization, Joint FAO/WHO Meeting on Pesticide Residues (WHO/PCS/99.18).

IPCS (1984) Endosulfan. Geneva, World Health Organization, International Programme on Chemical
Safety (Environmental Health Criteria 40).

Kutz FW, Yobs AR, Yang HSC (1976) National pesticide monitoring programs. In: Lee RE, ed. Air
pollution from pesticides and agricultural processes. Boca Raton, FL, CRC Press, pp. 95–135.

Strachan WMJ et al. (1980) Organochlorines in precipitation in the Great Lakes region. In: Afghan BK,
McKay D, eds. Hydrocarbons and halogenated hydrocarbons in the aquatic environment. New York,
NY, Plenum Press, pp. 387–396.

WHO (2001) The WHO recommended classification of pesticides by hazard and guidelines to
classification 2000–2002. Geneva, World Health Organization, International Programme on Chemical
Safety (WHO/PCS/01.5).




3
    This section has been taken from FAO/WHO (1999).
                                                 7

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Endosulfan has negligible residues in drinking water who report

  • 1. WHO/SDE/WSH/03.04/92 English only Endosulfan in Drinking-water Background document for development of WHO Guidelines for Drinking-water Quality
  • 2. © World Health Organization 2004 Requests for permission to reproduce or translate WHO publications - whether for sale of for non- commercial distribution - should be addressed to Publications (Fax: +41 22 791 4806; e-mail: permissions@who.int. The designations employed and the presentation of the material in this publication do not imply the expression of any opinion whatsoever on the part of the World Health Organization concerning the legal status of any country, territory, city or area or of its authorities, or concerning the delimitation of its frontiers or boundaries. The mention of specific companies or of certain manufacturers' products does not imply that they are endorsed or recommended by the World Health Organization in preference to others of a similar nature that are not mentioned. Errors and omissions excepted, the names of proprietary products are distinguished by initial capital letters. The World Health Organization does not warrant that the information contained in this publication is complete and correct and shall not be liable for any damage incurred as a results of its use.
  • 3. Preface One of the primary goals of WHO and its member states is that “all people, whatever their stage of development and their social and economic conditions, have the right to have access to an adequate supply of safe drinking water.” A major WHO function to achieve such goals is the responsibility “to propose ... regulations, and to make recommendations with respect to international health matters ....” The first WHO document dealing specifically with public drinking-water quality was published in 1958 as International Standards for Drinking-water. It was subsequently revised in 1963 and in 1971 under the same title. In 1984–1985, the first edition of the WHO Guidelines for Drinking-water Quality (GDWQ) was published in three volumes: Volume 1, Recommendations; Volume 2, Health criteria and other supporting information; and Volume 3, Surveillance and control of community supplies. Second editions of these volumes were published in 1993, 1996 and 1997, respectively. Addenda to Volumes 1 and 2 of the second edition were published in 1998, addressing selected chemicals. An addendum on microbiological aspects reviewing selected microorganisms was published in 2002. The GDWQ are subject to a rolling revision process. Through this process, microbial, chemical and radiological aspects of drinking-water are subject to periodic review, and documentation related to aspects of protection and control of public drinking- water quality is accordingly prepared/updated. Since the first edition of the GDWQ, WHO has published information on health criteria and other supporting information to the GDWQ, describing the approaches used in deriving guideline values and presenting critical reviews and evaluations of the effects on human health of the substances or contaminants examined in drinking- water. For each chemical contaminant or substance considered, a lead institution prepared a health criteria document evaluating the risks for human health from exposure to the particular chemical in drinking-water. Institutions from Canada, Denmark, Finland, France, Germany, Italy, Japan, Netherlands, Norway, Poland, Sweden, United Kingdom and United States of America prepared the requested health criteria documents. Under the responsibility of the coordinators for a group of chemicals considered in the guidelines, the draft health criteria documents were submitted to a number of scientific institutions and selected experts for peer review. Comments were taken into consideration by the coordinators and authors before the documents were submitted for final evaluation by the experts meetings. A “final task force” meeting reviewed the health risk assessments and public and peer review comments and, where appropriate, decided upon guideline values. During preparation of the third edition of the GDWQ, it was decided to include a public review via the world wide web in the process of development of the health criteria documents.
  • 4. During the preparation of health criteria documents and at experts meetings, careful consideration was given to information available in previous risk assessments carried out by the International Programme on Chemical Safety, in its Environmental Health Criteria monographs and Concise International Chemical Assessment Documents, the International Agency for Research on Cancer, the joint FAO/WHO Meetings on Pesticide Residues and the joint FAO/WHO Expert Committee on Food Additives (which evaluates contaminants such as lead, cadmium, nitrate and nitrite, in addition to food additives). Further up-to-date information on the GDWQ and the process of their development is available on the WHO internet site and in the current edition of the GDWQ.
  • 5. Acknowledgements The first draft of Endosulfan in Drinking-water, Background document for development of WHO Guidelines for Drinking-water Quality, was prepared by Dr P. Toft, Canada, to whom special thanks are due. The work of the following working group coordinators was crucial in the development of this document and others in the third edition: Mr J.K. Fawell, United Kingdom (Organic and inorganic constituents) Dr E. Ohanian, Environmental Protection Agency, USA (Disinfectants and disinfection by-products) Ms M. Giddings, Health Canada (Disinfectants and disinfection by-products) Dr P. Toft, Canada (Pesticides) Prof. Y. Magara, Hokkaido University, Japan (Analytical achievability) Mr P. Jackson, WRc-NSF, United Kingdom (Treatment achievability) The contribution of peer reviewers is greatly appreciated. The draft text was posted on the world wide web for comments from the public. The revised text and the comments were discussed at the Final Task Force Meeting for the third edition of the GDWQ, held on 31 March to 4 April 2003, at which time the present version was finalized. The input of those who provided comments and of participants in the meeting is gratefully reflected in the final text. The WHO coordinators were as follows: Dr J. Bartram, Coordinator, Water Sanitation and Health Programme, WHO Headquarters, and formerly WHO European Centre for Environmental Health Mr P. Callan, Water Sanitation and Health Programme, WHO Headquarters Mr H. Hashizume, Water Sanitation and Health Programme, WHO Headquarters Ms C. Vickers provided a liaison with the International Chemical Safety Programme, WHO Headquarters. Ms Marla Sheffer of Ottawa, Canada, was responsible for the scientific editing of the document. Many individuals from various countries contributed to the development of the GDWQ. The efforts of all who contributed to the preparation of this document and in particular those who provided peer or public domain review comment are greatly appreciated.
  • 6. Acronyms and abbreviations used in the text ADI acceptable daily intake ATSDR Agency for Toxic Substances and Disease Registry (USA) CAS Chemical Abstracts Service FAO Food and Agriculture Organization of the United Nations IPCS International Programme on Chemical Safety JMPR Joint FAO/WHO Meeting on Pesticide Residues LC50 median lethal concentration LD50 median lethal dose NOAEL no-observed-adverse-effect level USA United States of America WHO World Health Organization
  • 7. Table of contents 1. GENERAL DESCRIPTION....................................................................................... 1 1.1 Identity .................................................................................................................. 1 1.2 Physicochemical properties .................................................................................. 1 1.3 Major uses............................................................................................................. 1 1.4 Environmental fate................................................................................................ 1 2. ANALYTICAL METHODS ...................................................................................... 2 3. ENVIRONMENTAL LEVELS AND HUMAN EXPOSURE................................... 2 3.1 Air ......................................................................................................................... 2 3.2 Water..................................................................................................................... 2 3.3 Food ...................................................................................................................... 2 3.4 Estimated total exposure and relative contribution of drinking-water.................. 3 4. KINETICS AND METABOLISM IN LABORATORY ANIMALS AND HUMANS ....................................................................................................................... 3 5. EFFECTS ON EXPERIMENTAL ANIMALS AND IN VITRO TEST SYSTEMS.. 3 6. EFFECTS ON HUMANS........................................................................................... 7 7. CONCLUSIONS......................................................................................................... 7 8. REFERENCES ........................................................................................................... 7
  • 9. 1. GENERAL DESCRIPTION 1.1 Identity CAS No.: 115-29-7 Molecular formula: C9H6Cl6O3S The chemical name of endosulfan is 6,7,8,9,10,10-hexachloro-1,5,5a,6,9,9a- hexahydro-6,9-methano-2,4,3-benzodioxathiepin-3-oxide. Technical endosulfan is a brown crystalline substance consisting of α- and β-isomers in the ratio of approximately 70:30. Endosulfan’s chemical structure is shown below: 1.2 Physicochemical properties Technical endosulfan is usually sold in the form of brown crystalline flakes. Property Value Melting point 79–100 °C Vapour pressure 1.3 × 10-3 Pa at 25 °C Solubility in water 60–150 µg/litre; increases with decreasing pH 1.3 Major uses Endosulfan is a contact and stomach poison that has been used to control insects such as the Colorado potato beetle, flea beetle, cabbageworm, peach tree borer and tarnished plant bug, as well as several species of aphid and leafhopper. It is used in countries throughout the world to control pests on fruit, vegetables and tea and on non-food crops such as tobacco and cotton. In addition to its agricultural use and its use in the control of the tsetse fly, endosulfan is used as a wood preservative and for the control of home garden pests (IPCS, 1984). 1.4 Environmental fate Both endosulfan isomers undergo photolysis upon exposure to sunlight. The half-life is about 7 days. Endosulfan diol is the primary photolysis product; it is subsequently degraded to endosulfan α-hydroxy ether (ATSDR, 2000). In water, endosulfan undergoes hydrolysis to endosulfan diol. The rate of hydrolysis is influenced by pH. Oxidative degradation also occurs. At pH 7, the half-lives for hydrolysis and oxidation were 23 and 25 days, respectively; at pH 5, the half-lives were 54 and 51 days, respectively (ATSDR, 2000). 1
  • 10. ENDOSULFAN IN DRINKING-WATER Endosulfan released to soil is subject to biodegradation. Biodegradation in soil and water is dependent on climatic conditions and on the type of microorganisms present. Endosulfan sulfate is the major degradation product in soil and is persistent in the soil (ATSDR, 2000). 2. ANALYTICAL METHODS The method of choice for the determination of endosulfan involves extraction from water with methylene chloride followed by gas chromatography combined with electron capture detection. In considering residue levels, the sum of the α- and β- isomers plus the endosulfan sulfate metabolite, which is similar in toxicity to the parent compound, have to be considered. Detection limits are 0.015 µg/litre for α- endosulfan, 0.024 µg/litre for β-endosulfan and 0.015 µg/litre for endosulfan sulfate (ATSDR, 2000). 3. ENVIRONMENTAL LEVELS AND HUMAN EXPOSURE 3.1 Air Residues of α- and β-endosulfan have been detected in ambient air samples in the USA (Kutz et al., 1976). Between 1970 and 1972, α-endosulfan was found in 2.11% of samples tested in the USA at a mean concentration of 111.9 ng/m3 and a maximum of 2256 ng/m3. During the same period, β-endosulfan was present in 0.32% of the samples at a mean concentration of 22.0 ng/m3 and a maximum of 54.5 ng/m3. This information suggests that the α-isomer is more persistent in air. Both α- and β- endosulfan have been detected at levels up to 12 ng/litre in precipitation in the Great Lakes area of Canada and the USA (Strachan et al., 1980). 3.2 Water Endosulfan contamination does not appear to be widespread in the aquatic environment, but endosulfan has been found in agricultural runoff and rivers in industrialized areas where it is manufactured or formulated (IPCS, 1984). Endosulfan (one or both of its isomers) has been identified in 24 surface water and 103 groundwater samples collected from 164 hazardous waste sites in the USA. Surface water samples in the USA generally contain less than 1 µg/litre (ATSDR, 2000). 3.3 Food The main source of exposure of the general population is food, but residues have generally been found to be well below the FAO/WHO maximum residue limits (IPCS, 1984). These residue tolerances refer to the total residue of α- and β- endosulfan and endosulfan sulfate. Because of its use in tobacco farming, smoking may be an additional source of endosulfan exposure. 2
  • 11. ENDOSULFAN IN DRINKING-WATER In a market basket survey conducted in the USA in 1986–1991, intakes of 2.3–3.8 × 10-6 mg/kg of body weight for α-endosulfan and 6.5–9.9 × 10-6 mg/kg of body weight for β-endosulfan were reported (ATSDR, 2000). 3.4 Estimated total exposure and relative contribution of drinking-water With good agricultural practice, endosulfan residues in food should not be significant. Generally, endosulfan concentrations in air and water are very low and localized and accordingly of no significance as far as risk for the general population is concerned (IPCS, 1984). The most important routes of exposure to endosulfan for the general population are ingestion of food and the use of tobacco products with endosulfan residues remaining after treatment (ATSDR, 2000). 4. KINETICS AND METABOLISM IN LABORATORY ANIMALS AND HUMANS1 More than 90% of an oral dose of endosulfan was absorbed in rats, with maximum plasma concentrations occurring after 3–8 h in males and about 18 h in females. Elimination occurs mainly in the faeces and to a lesser extent in the urine, more than 85% being excreted within 120 h. The highest tissue concentrations were in the kidneys. The metabolites of endosulfan include endosulfan sulfate, diol, hydroxy- ether, ether and lactone, but most of its metabolites are polar substances that have not yet been identified. Endosulfan would not be expected to accumulate significantly in human tissues. 5. EFFECTS ON EXPERIMENTAL ANIMALS AND IN VITRO TEST SYSTEMS2 A battery of tests for acute toxicity in several species with technical-grade endosulfan showed that it is highly toxic after oral or dermal administration, with respective LD50 values of 10–160 mg/kg of body weight and 45–135 mg/kg of body weight. The LC50 value for rats in a single study was 13 mg/m3 in females and 35 mg/m3 in males. Endosulfan, administered by any route, is more toxic to female than to male rats. Clinical signs of acute intoxication include piloerection, salivation, hyperactivity, respiratory distress, diarrhoea, tremors, hunching and convulsions. WHO (2001) has classified endosulfan as “moderately hazardous.” The kidney is the target organ for toxicity. The renal effects include increased renal weights and granular pigment formation after short-term administration and progressive, chronic glomerulonephrosis or toxic nephropathy after long-term exposure, although the observation of progressive glomerulonephrosis is complicated by the fact that this is a common lesion in aging laboratory rats and occurs at high incidence in control rats. 1 This section has been taken from FAO/WHO (1999). 2 This section has been taken from FAO/WHO (1999). 3
  • 12. ENDOSULFAN IN DRINKING-WATER In a 90-day feeding study in rats, the cytoplasm of isolated cells in the renal proximal convoluted tubules had a yellowish colour, particularly in males, at all dietary concentrations from 10 mg/kg. The presence of this yellow pigmentation was largely reversible during a 4-week recovery period, and it did not appear to indicate nephrotoxicity. A darker, more particulate, granular and/or clumped pigment was also observed, predominantly in cells of the straight portions and occasionally in the proximal convoluted tubules, at dietary concentrations of 30 mg/kg and above. This darker pigment was more persistent than the yellow one, and urinalysis revealed darker urine and marginally more ketones at doses from 60 mg/kg and marginally more protein, particularly in males, indicating renal damage, at doses of 360 mg/kg and above. Similar findings emerged from a multigeneration study but not from a 2- year study of carcinogenicity in rats. The changes in pigmentation were considered to be due to the presence of endosulfan and/or its metabolites in the enlarged lysosomes. To test this hypothesis, a 4-week feeding study was conducted in which male rats were given dietary concentrations of 360 or 720 mg of endosulfan per kg. Light and electron microscopy of the kidneys of these animals clearly showed increases in the number of lysosomes and the size of cells in the convoluted tubule, probably as a result of accumulation of the test material and/or its metabolites. Lysosomal changes were not observed in either brain or liver, and the renal changes receded appreciably during a 30-day recovery period. Chemical analysis of the kidneys indicated the presence of α-endosulfan and, to a lesser extent, β-endosulfan sulfate and endosulfan lactone. The concentrations of the dominant α-endosulfan in the kidneys were about 50 times those in the liver. The concentrations in blood were usually below the level of detection. After the 30-day recovery period, renal α-endosulfan was detected only in traces and β-endosulfan not at all. Similar analysis of tissues from rats in the 2-year study of toxicity and carcinogenicity did not reveal the presence of these substances in the kidney, although measurable α-endosulfan was found in the liver at 75 mg/kg. The yellow colour therefore indicates the presence of endosulfan and/or its metabolites, rather than either a stage in the pathogenesis of nephropathy or an independent expression of toxicity. It was postulated that in longer studies, its removal from lysosomes is accelerated by enzyme induction, which has not been investigated. Groups of 50 Sprague-Dawley rats of each sex were fed diets containing endosulfan at concentrations of 0, 3, 7.5, 15 or 75 mg/kg, equal to 0, 0.1, 0.3, 0.6 and 2.9 mg/kg of body weight per day for males and 0, 0.1, 0.4, 0.7 and 3.8 mg/kg of body weight per day for females, for 104 weeks. Reductions in body weights and body weight gains were observed in males and females at 75 mg/kg, but no clinical signs of poisoning were seen at any dose. No increase in mortality rates was observed in treated groups. Increased incidences of enlarged kidneys in females and of aneurysms and enlarged lumbar lymph nodes in males were seen at 75 mg/kg. Histopathological examination showed that males at 75 mg/kg had an increased incidence of aneurysm and marked progressive glomerulonephrosis. The most common neoplasms were pituitary tumours in males and females and mammary tumours in females, but the increased incidences did not appear to be related to treatment. The NOAEL was 15 mg/kg, equal to 0.6 mg/kg of body weight per day, on the basis of reduced body weights and pathological findings at higher doses. 4
  • 13. ENDOSULFAN IN DRINKING-WATER Groups of 50 B6C3F1 mice of each sex were fed diets containing technical-grade endosulfan at time-weighted average concentrations of 3.5 or 6.9 mg/kg for males and 2 or 3.9 mg/kg for females for 78 weeks. There were no clear compound-related effects on appearance or behaviour in the treated groups, and the body weights of both males and females were unaffected by treatment. The mortality rate of males at the high dose was increased early in treatment, whereas the mortality rates of female mice were not affected by treatment. No treatment-related clinical signs were recorded, and no treatment-related neoplastic lesions were seen in the females. Owing to the high early mortality rates, no conclusion could be drawn about the carcinogenic potential of endosulfan in males. None of the non-neoplastic changes seen in the kidneys and sex organs of male and female mice could be attributed to treatment. The NOAEL for female mice was 3.9 mg/kg, equal to 0.58 mg/kg of body weight per day. Groups of six beagle dogs of each sex were fed diets containing technical-grade endosulfan at concentrations of 0, 3, 10 or 30 mg/kg for 1 year, calculated to be equivalent to 0, 0.23, 0.77 and 2.3 mg/kg of body weight per day. Some animals given endosulfan at 30 mg/kg throughout the 12-month study had violent contractions of the abdominal muscles (without vomiting), and males at this dose had reduced body weight gains throughout the study and slightly reduced body weights in the latter stages of the study, in comparison with control animals. Cholinesterase activity was measured in serum, erythrocytes and brain, but difficulty appears to have been experienced in measuring these activities, and there were large variations within groups for the brain enzyme, the group mean of which was increased in dogs at 30 mg/kg. No other effects related to treatment were observed, and no increase in the incidence of neoplastic or non-neoplastic lesions was observed in treated animals. The NOAEL was 10 mg/kg, calculated to be equivalent to 0.77 mg/kg of body weight per day, on the basis of clinical signs and reductions in body weight. In a 78-week study, exposure of rats to endosulfan at a high dose of 20 mg/kg of body weight per day resulted in testicular atrophy, characterized by degeneration and necrosis of the germinal cells lining the seminiferous tubules. In addition, decreased sperm counts accompanied by an increased incidence of sperm abnormalities have been reported in mice, again at high doses of endosulfan. Reductions in the activities of some testicular xenobiotic-metabolizing enzymes and some hormones that are necessary for normal testicular function were also seen in a 30-day study in rats at 10 mg/kg of body weight per day, but not at 7.5 mg/kg of body weight per day. The functional significance of these findings was not clear, as studies of reproductive and developmental toxicity in rats and rabbits showed neither impaired fertility nor any increase in the incidence of defects or abnormalities in offspring. Given the high doses at which these testicular effects were observed, it would appear that they are of little human significance. No genotoxic activity was observed in an adequate battery of tests for mutagenicity and clastogenicity in vitro and in vivo. The JMPR Meeting concluded that endosulfan is not genotoxic. 5
  • 14. ENDOSULFAN IN DRINKING-WATER No carcinogenic effect was observed in mice at 18 mg/kg for 24 months, in female rats at 445 mg/kg for 78 weeks in one study or in male or female rats at 75 mg/kg or 100 mg/kg for 2 years in two other studies. The JMPR Meeting noted the differences in the dietary concentrations used in these studies, but non-neoplastic responses were seen even at the lower doses. Endosulfan at dietary concentrations of 0, 3, 15 or 75 mg/kg did not affect reproductive performance or the growth or development of the offspring of rats over the course of a two-generation study. The NOAEL was 75 mg/kg, the highest dose tested, equal to 5 mg/kg of body weight per day for males and 6.2 mg/kg of body weight per day for females. The NOAEL for parental toxicity was 15 mg/kg, equal to 1 mg/kg of body weight per day for males and 1.2 mg/kg of body weight per day for females, on the basis of increased liver and kidney weights at 75 mg/kg. In two studies of developmental toxicity in rats given oral doses of 0, 0.66, 2 or 6 mg/kg of body weight per day, the NOAEL for maternal toxicity was 0.66 mg/kg of body weight per day in one study and 2 mg/kg of body weight per day in the other. In the first case, the basis was decreased body weight gain at 2 mg/kg of body weight per day and decreased body weight gain and clinical signs of toxicity at 6 mg/kg of body weight per day; in the second case, the basis was mortality, clinical signs of toxicity and decreased body weight gain at 6 mg/kg of body weight per day. In both studies, the NOAEL for developmental toxicity was 2 mg/kg of body weight per day, in the first case on the basis of delayed development and a low incidence of skeletal variations seen at 6 mg/kg of body weight per day and in the second on the basis of an increased incidence of fragmented thoracic vertebral centra seen at 6 mg/kg of body weight per day. In neither study was there any treatment-related major malformation. In a study of developmental toxicity in rabbits given oral doses of 0, 0.3, 0.7 or 1.8 mg/kg of body weight per day, the NOAEL for maternal toxicity was 0.7 mg/kg of body weight per day on the basis of clinical signs of toxicity at 1.8 mg/kg of body weight per day. The NOAEL for developmental toxicity was 1.8 mg/kg of body weight per day, the highest dose tested. Several recent studies have shown that endosulfan, alone and in combination with other pesticides, may bind to estrogen receptors and may perturb the endocrine system. The available studies show only very weak binding to hormone receptors in vitro, and the evidence for their relevance to adverse physiological effects in vivo is extremely limited. Long-term assays of toxicity and studies of reproductive and developmental toxicity in experimental mammals did not indicate that endosulfan induces functional aberrations that might result from loss of endocrine homeostasis. The absence of immunotoxic effects in a large number of bioassays with endosulfan suggested that it does not have an adverse effect on the immune function of laboratory animals. However, in two studies, rats given endosulfan in the diet at 30 or 50 mg/kg for 6 weeks or 20 mg/kg for 22 weeks had reduced serum titres of tetanus toxoid antibody, reduced immunoglobulins G and M and inhibition of migration of both leukocytes and macrophages. These findings have not been confirmed. 6
  • 15. ENDOSULFAN IN DRINKING-WATER 6. EFFECTS ON HUMANS3 In a summary of case reports of human poisoning incidents, the lowest reported dose that caused death was 35 mg/kg of body weight. Higher doses caused death within 1 h. The clinical signs in these patients were dominated by tonic-clonic convulsions, consistent with the observations in experimental animals. 7. CONCLUSIONS An ADI of 0.006 mg/kg of body weight was established on the basis of the NOAEL of 0.6 mg/kg of body weight per day in the 2-year dietary study of toxicity in rats and using a safety factor of 100. The ADI is supported by similar NOAEL values in the 78-week dietary study of toxicity in mice (0.58 mg/kg of body weight per day), the 1- year dietary study of toxicity in dogs (0.77 mg/kg of body weight per day) and the study of developmental toxicity in rats (0.66 mg/kg of body weight per day for maternal toxicity). A health-based value of 20 µg/litre can be calculated on the basis of the ADI of 0.006 mg/kg of body weight, with an allocation of 10% of the ADI to drinking-water, and with the assumption that a 60-kg adult consumes 2 litres of drinking-water per day. However, endosulfan usually occurs at concentrations in drinking-water well below those at which toxic effects can be expected to occur, and it is therefore not considered necessary to derive a guideline value for endosulfan in drinking-water. 8. REFERENCES ATSDR (2000) Toxicological profile for endosulfan. Atlanta, GA, US Department of Health and Human Services, Public Health Service, Agency for Toxic Substances and Disease Registry. FAO/WHO (1999) Pesticide residues in food — 1998 evaluations. Part II — Toxicological. Geneva, World Health Organization, Joint FAO/WHO Meeting on Pesticide Residues (WHO/PCS/99.18). IPCS (1984) Endosulfan. Geneva, World Health Organization, International Programme on Chemical Safety (Environmental Health Criteria 40). Kutz FW, Yobs AR, Yang HSC (1976) National pesticide monitoring programs. In: Lee RE, ed. Air pollution from pesticides and agricultural processes. Boca Raton, FL, CRC Press, pp. 95–135. Strachan WMJ et al. (1980) Organochlorines in precipitation in the Great Lakes region. In: Afghan BK, McKay D, eds. Hydrocarbons and halogenated hydrocarbons in the aquatic environment. New York, NY, Plenum Press, pp. 387–396. WHO (2001) The WHO recommended classification of pesticides by hazard and guidelines to classification 2000–2002. Geneva, World Health Organization, International Programme on Chemical Safety (WHO/PCS/01.5). 3 This section has been taken from FAO/WHO (1999). 7