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WOMEN





1

INTRODUCTION
While polluted drinking water can harm any person, pregnant women and babies are
particularly sensitive to certain pollutants. Category A, one portion of the state’s water
quality standards, protects surface waters from harmful levels of more than 80 pollutants,
including metals, organic compounds, and other toxic pollutants (See Appendix A).
Category A is the backbone for Clean Water Act protections for the state’s rivers, streams,
and reservoirs that serve as current and future drinking water sources. This document
explains the importance of Category A for protecting women’s reproductive health.

West Virginia’s water quality standards provide targets for
keeping rivers, streams, and reservoirs clean AND USEABLE
West Virginia’s water quality standards
protect the state’s rivers, streams, and
reservoirs now and in the future (47 CSR
2). Specific protections are provided for
different uses, and surface waters are
typically protected for more than one use.
Category A is shorthand for waters used
as public water supplies, defined as waters
that, after conventional treatment, are used
for human consumption. Other common
uses include Category C (water contact
recreation), Category B1 (warm water fishery
streams), and Category B2 (trout waters).
For each use, West Virginia’s water quality
standards provide numeric criteria for a
variety of parameters that can be measured
in the water or in fish. For many pollutants,
Category A criteria are the most stringent
among the uses, and in some cases, Category
A provides the only criteria.

Because Category A limits the amount of
toxic and cancer-causing chemicals allowed
in our water, it provides extremely important
protections for pregnant women and babies,
two particularly vulnerable populations.
Category A criteria are enforceable
targets for keeping streams clean and for
restoring impaired streams. Clean Water Act
discharge permits must be written to prevent
violations of Category A criteria. If violations
occur, a surface water is considered to be
impaired. Impaired waters are placed on the
state’s 303(d) list, and total maximum daily
loads (TMDLs) are then written to determine
which pollutant sources must be addressed
so that the stream can once again meet its
Category A criteria.

 2

Category A protects drinking water sources from toxic
pollution
The West Virginia Department of
Environmental Protection (WVDEP) has had
a longstanding policy of protecting every
surface water for Category A, in order to
ensure clean drinking water for all people
and businesses now and in the future.

Category A
pollutant
Iron
Polychlorinated
biphenyls (PCBs)

Impaired waters in
West Virginia
7,583 stream miles
54 reservoir acres
478 stream miles
630 reservoir acres

Dioxin

352 stream miles

Methylmercury

9,826 reservoir acres

While some states provide drinking water
protections only in defined areas around
known water intakes, WVDEP’s Category
A policy recognizes that clean drinking
water across West Virginia is a precious
resource, both for protecting the health of
the current population and as a foundation
for future economic development. Even with
Category A protections in place, the table
below shows that thousands of stream miles
need to be cleaned up in order to serve as
safe drinking water supplies.

Specific impaired rivers and streams
•

Numerous

•
•
•
•
•
•
•
•
•
•
•

Ohio River
Kanawha River
Bluestone River
Shenandoah Rivers
Flat Fork of the Kanawha River
R.D. Bailey Lake.
Ohio River
Kanawha River
Pocatalico River
Armour Creek of the Kanawha River
Numerous

 
  Source: West Virginia Department of Environmental Protection (Undated). Note: This is not a complete list of all Category
A pollutants with 303(d) listings. Also, some Category A pollutants, such as iron, have criteria for other uses. Waters listed
as impaired for such waters may violate the Category A criterion, other criteria, or multiple criteria.

 3

Category A pollutants impact women’s reproductive health
Many Category A pollutants have well-documented impacts on women’s reproductive health and
on the health of babies. While not a comprehensive list, the following summary lists some of the
potential hazards of exposure to chemicals that Category A limits.

IRON
•

High doses injected into pregnant rats
may result in embryo malformations, such
as being born with one or no eyes and a
condition in which fluid accumulates in the
brain, sometimes causing brain damage
(HSDB e).

•

Iron compounds can disturb the development of embryos and fetuses, could cause
birth defects, or may abort the
pregnancy (HSDB e).

•

Maternal blood manganese levels during
pregnancy are associated with birth
weight, suggesting that manganese may
affect fetal growth (Zota et al. 2009).

•

Dioxins may cause malformations of
human embryos. Malformations may
include central nervous system, cardiac,
and skeletal defects (HSDB a).

•

Consumption of methylmercurycontaminated food causes nervous
system damage in pregnant women and
very serious effects in the fetuses (Choi
1991).
Prenatal exposure to organic mercury is
associated with severe effects, including
seizures, spasticity, profound mental
retardation, and cerebral palsy (HSDB i).

MANGANESE
•

Manganese, an essential metal for
normal growth and development, is
neurotoxic with excessive exposure
(Aschner et al. 2015).

DIOXIN
•

Low birth weights and both growth
and neurological defects have been
associated with dioxin exposure
(HSDB a).

METHYLMERCURY
•

Pregnant women and young children
are most vulnerable to methylmercury
exposure. Common symptoms of
perinatal exposure include increased
visual deficits, motor impairment, and an
overall cognitive decline. The developing
cerebellum is particularly vulnerable
to methylmercury neurotoxicity (Patel
2013).

•

 4

LEAD
•
•

Unborn children are considered
particularly susceptible to lead poisoning
(HSDB f).
Lead is transferred across the placenta
and affects neurodevelopmental
milestones in children with prenatal
exposure. It can also affect reproduction
in males and females (HSDB f).

•

Prenatal exposure to lead is thought
to be a risk factor for attention-deficit
hyperactivity disorder (ADHD) (HSDB f).
Increased risk of abortion, premature
birth, birth defects, and delayed mental
and physical growth are associated with
exposure to lead during pregnancy (HSDB
f).
Maternal lead exposure is associated with
poor birth outcomes in populations with
moderate-to-high blood levels (HSDB f).

•

•

POLYCHLORINATED BIPHENYLS (PCBS)
•

•

PCBs are potentially toxic to the
developing brain, and prenatal
exposure to high background levels of
most PCBs seems to impair early motor
skills development (Berghuis et al. 2013).
A potential symptom of occupational
PCB overexposure is decreased birth
weight in offspring of exposed mothers
(HSDB g).

2,4-DICHLOROPHENOL
•

Animal test subjects exhibited decreases
in maternal body weight gain,
decreased fetal weight, and fetal and
material death at various concentrations
(Multivolume work 1999).

•

Although relatively small quantities
of PCBs reach the fetus, significant
PCB overexposure can cause embryo
malformations (HSDB g).
Prenatal exposure to PCBs is thought to be
a risk factor for ADHD (HSDB f).

•

ETHYLBENZENE
•

Ethylbenzene has been found to disturb
fetal development and can poison
a developing fetus or embryo in lab
animals. It has also been detected in
umbilical cord blood (HSDB d).

•

Ethylbenzene induced maternal and
fetal toxicity in rats and developmental
toxicity in rat pups at certain
concentrations (ChemView c).

 5

BENZENE
•

•

Benzene has been found in umbilical
cord blood. Benzene exposure has been
linked to menstrual changes, spontaneous
abortion, and stillbirth (HSDB c).
Benzene caused reproductive toxicity
in rats at certain concentrations. Effects
included decreased maternal and
placental weight and increases in number

PYRENE
•

Embryo malformations have been noted
(HSDB h).

Category A limits concentrations of a wide
range of pollutants, several of which, as
outlined above, are hazardous to women’s
reproductive health. In many cases, Category
A provides the most protective criteria
compared to all other uses. Currently, all
West Virginia surface waters must meet these
Category A criteria, in order to ensure that
West Virginia’s surface waters can be used
for human consumption after conventional
treatment.

of non-pregnant females, total resorptions
and postimplantation fetal loss (ChemView
b).
Benzene caused a significant increase in
mouse maternal mortality and embryonic
resorption and a significant decrease in
fetal weight following certain exposures
(ChemView a).

•

ARSENIC
•

Inorganic arsenic crosses the placenta
and may result in spontaneous abortion
or stillbirth with either acute or chronic
poisoning (HSDB b).

Removing Category A protections would
allow more harmful toxins into our rivers and
streams. It is imperative to preserve Category
A designation for all waters of the state to
protect women’s health, the health of future
generations, and the health of those living
downstream.

 6

APPENDIX A:

CATEGORY A POLLUTANTS AND CRITERIA IN WEST VIRGINIA
Pollutant
Concentration Unit
1,1-dichloroethylene
0.03
µg/L
1,1,1-trichloroethane
12
mg/L
1,1,2,2-tetrachloroethane
0.17
µg/L
1,2-dichlorobenzene
2.7
mg/L
1,2-dichloroethane
0.035
µg/L
1,3-dichlorobenzene
0.4
mg/L
1,4-dichlorobenzene
0.4
mg/L
2-Chloronaphthalene
1,000
µg/L
2-Chlorophenol
120
µg/L
2-methy 1-4,6-Dinitrophenol
13.4
µg/L
2,4-Dichlorophenol
93
µg/L
2,4-Dimethylphenol
540
µg/L
2,4-Dinitrophenol
70
µg/L
2,4-dinitrotoluene
0.11
µg/L
2,4,6-Trichlorophenol
2.1
µg/L
Acenaphthene
670
µg/L
Acrylonitrile
0.059
µg/L
Aldrin
0.071
ng/L
alpa-BHC
0.0039
µg/L
Anthracene
8,300
µg/L
Antimony
14
µg/L
Arsenic
10
µg/L
Barium
1.0
mg/L
Benzene
0.66
µg/L
Benzo(a) Anthracene
0.0038
µg/L
Benzo(a) Pyrene
0.0038
µg/L
Benzo(b) Fluoranthene
0.0038
µg/L
Benzo(k) Fluoranthene
0.0038
µg/L
Beryllium
4.0
µg/L
beta-BHC
0.014
µg/L
Bromoform
4.3
µg/L
Carbon tetrachloride
0.25
µg/L
Chlordane
0.46
ng/L
Chloride
250
mg/L
Chlorobenzene
0.68
mg/L
Chloroform
5.7
µg/L
Chromium
50
µg/L
Chrysene
0.0038
µg/L
Copper
1,000
µg/L
Cyanide
5.0
µg/L
DDT
0.024
ng/L
Dibenzo(a,h)Anthracene
0.0038
µg/L
Dichlorobromomethane
0.55
µg/L
Dieldrin
0.071
ng/L
Dioxin
0.013
pg/L
Dissolved oxygen
5
mg/L
mg/L=parts
per million, µg/L=parts
per billion,
ng/L= parts
Endrin
2.3
ng/L
per
billion
Ethylbenzene
3.1
mg/L
Fluoranthene
300
µg/L
Fluorene
1,100
µg/L
Fluoride
1.4
mg/L
gamma-BHC
0.019
µg/L
Heptachlor
0.21
ng/L
Hexachlorobenzene
0.72
ng/L
Indeno(1,2,3-cd)Pyrene
0.0038
µg/L
Iron
1.5
mg/L

Dibenzo(a,h)Anthracene
0.0038
µg/L
Dichlorobromomethane
0.55
µg/L
Dieldrin
0.071
ng/L
Pollutant
Concentration
Unit
Dioxin
0.013
pg/L
Antimony
145
µg/L
Dissolved oxygen
mg/L
Arsenic
102.3
µg/L
Endrin
ng/L
Barium
1.0
mg/L
Ethylbenzene
3.1
mg/L
Beryllium
4.0
µg/L
Fluoranthene
300
µg/L
Chloride
250
mg/L
Fluorene
1,100
µg/L
Chromium
501.4
µg/L
Fluoride
mg/L
Copper
1,0000.019
µg/L
gamma-BHC
µg/L
Cyanide
5.0
µg/L
Heptachlor
0.21
ng/L
Dissolved
oxygen
50.72
mg/L
Hexachlorobenzene
ng/L
Fluoride
1.4
mg/L
Indeno(1,2,3-cd)Pyrene
0.0038
µg/L
Iron
1.5
mg/L
Lead
50
µg/L
Lead
50
µg/L
Manganese
1.0
mg/L
Manganese
1.0
mg/L
Mercury-body
burden
0.5
µg/g
Mercury
0.14
µg/L
Mercury
0.14
µg/L
Mercury-body burden
0.5
µg/g
Nickel
5100.03
µg/L
Methoxychlor
Nitrate
10
mg/L
Methyl Bromide
47
µg/L
Chlordane
0.46
ng/L
Methylene Chloride
4.6
µg/L
DDT
0.024
ng/L
Nickel
510
µg/L
Aldrin
0.071
ng/L
Nitrate
10
mg/L
Dieldrin
0.071
ng/L
PCBs
0.044
Endrin
2.3
ng/L
Pentachlorophenol
0.28
µg/L
Toxaphene
0.73
ng/L
Phenol
21,000
µg/L
PCBs
0.044
ng/L
Pyrene
830
µg/L
Methoxychlor
0.03
µg/L
Selenium
50
µg/L
Dioxin
0.013
pg/L
Tetrachloroethylene
0.8
µg/L
Acrylonitrile
0.059
µg/L
Thallium
1.7
µg/L
Benzene
0.66
µg/L
Toluene
6.8
mg/L
1,2-dichlorobenzene
2.7
mg/L
Toxaphene
0.73
ng/L
1,3-dichlorobenzene
0.4
mg/L
Trichloroethylene
2.7
µg/L
1,4-dichlorobenzene
0.4
mg/L
Source:
47 CSR 2, Appendix E. Note:
2,4-dinitrotoluene
0.11 The water
µg/L quality
standards
rule includes more complex
Hexachlorobenzene
0.72 Category
ng/L A criteria for
cadmium,
fecal coliform, pH, radioactivity,
silver,
Carbon tetrachloride
0.25
µg/L threshold
odor,
and turbidity; these criteria 5.7
are not shown.
Chloroform
µg/L Cyanide as
free
cyanide HCN+CN-). Chromium
Bromoform
4.3 as dissolved
µg/L hexavalent.
Dichlorobromomethane
0.55Mercury-body
µg/L
Dissolved
Oxygen as minimum value.
burden
47any aquatic
µg/Lspecies as
asMethyl
total Bromide
organism body burden of
Methylene Chloride
µg/L water sample.
methylmercury.
Mercury as total in4.6any unfiltered
1,2-dichloroethane
0.035
µg/L
Nitrate as Nitrate-N. Dioxin as 2,3,7,8-TCDD.
Vinyl chloride
1,1,1-trichloroethane
12
mg/L
as chloroethene. Alpa-BHC as alpha- Hexachlorocyclohexane.
1,1,2,2-tetrachloroethane
0.17
µg/L
Beta-BHC as beta- Hexachlorocyclohexane. Gamma-BHC as
1,1-dichloroethylene
0.03
µg/L
gammaHexachlorocyclohexane. 2.7
Trichloroethylene
µg/L
Tetrachloroethylene
0.8
µg/L
Toluene
6.8
mg/L
Acenaphthene
670
µg/L
Anthracene
8,300
µg/L
Benzo(a) Anthracene
0.0038
µg/L
Benzo(a) Pyrene
0.0038
µg/L
Benzo(b) Fluoranthene
0.0038
µg/L
Benzo(k) Fluoranthene
0.0038
µg/L
Chrysene
0.0038
µg/L
Dibenzo(a,h)Anthracene
0.0038
µg/L
Fluorene
1,100
µg/L
Indeno(1,2,3-cd)Pyrene
0.0038
µg/L

 7

REFERENCES
Aschner, J.L., Anderson, A., Slaughter, J.C., Aschner, M., Steele, S., Beller, A., Mouvery, A., Furlong, H.M, and Maitre,
N.L. 2015. Neuroimaging identifies increased manganese deposition in infants receiving parenteral nutrition. The
American Journal of Clinical Nutrition.
Berghuis, S.A., Soechitram, S.D., Hitzert, M.M., Sauer, P.J., and Bos, A.F. 2013. Prenatal exposure to polychlorinated
biphenyls and their hydroxylated metabolites is associated with motor development of three-month-old infants.
Neurotoxicology.
ChemView a. Undated. Chemical Test Rule Data, Benzene 71-43-2, Developmental toxicity. http://java.epa.gov/
chemview#
ChemView b. Undated. Chemical Test Rule Data, Benzene 71-43-2, Reproductive toxicity. http://java.epa.gov/
chemview#
ChemView c. Undated. Chemical Test Rule Data, Ethylbenzene 100-41-4, Developmental toxicity. http://java.epa.
gov/chemview#
Choi, B.H. 1991. Effects of Methylmercury on the Developing Brain. Rochester Series on Environmental Toxicity.
Hazardous Substances Data Bank a. Undated.2,3,7,8-Tetrachlorodibenzo-P-Dioxin. https://toxnet.nlm.nih.gov/
newtoxnet/hsdb.htm
Hazardous Substances Data Bank b. Undated. Arsenic, Elemental. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Hazardous Substances Data Bank c. Undated. Benzene. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Hazardous Substances Data Bank d. Undated. Ethylbenzene. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Hazardous Substances Data Bank e. Undated. Iron Compounds. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Hazardous Substances Data Bank f. Undated. Lead, elemental. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Hazardous Substances Data Bank g. Undated. Polychlorinated biphenyls. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.
htm
Hazardous Substances Data Bank h. Undated. Pyrene. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Hazardous Substances Data Bank i. Undated. Methylmercury. https://toxnet.nlm.nih.gov/newtoxnet/hsdb.htm
Multivolume work. 1999. Monographs on the Evaluation of the Carcinogenic Risk of Chemicals to Humans. Geneva:
World Health Organization, International Agency for Research on Cancer, 1972-PRESENT. p. V71 789-90 http://
monographs.iarc.fr/ENG/Classification/index.php
Patel, E. and Reynolds, M. 2013. Methylmercury impairs motor function in early development and induces oxidative
stress in cerebellar granule cells. Toxicology letters.
West Virginia Department of Environmental Protection. Undated. 2014 West Virginia Integrated Water Quality
Monitoring and Assessment Report. http://www.dep.wv.gov/WWE/watershed/IR/Documents/IR_2014_
Documents/DraftIRtoEPA/DraftReportSupplements2014.pdf
Zota, A.R., Ettinger, A.S., Bouchard, M., Amarasiriwardena, C.J., Schwartz, J., Hu, H., Wright, R.O. 2009. Maternal
blood manganese levels and infant birth weight. Epidemiology.

This report was compiled with the technical assistance of Downstream Strategies, a West Virginia-based consulting firm.