Provisional Peer Reviewed Toxicity Values for Thiocyanates (Multiple CASRNs)


United States
Environmental Protection
1=1 m m Agency
EPA/690/R-06/023F
Final
3-15-2006
Provisional Peer Reviewed Toxicity Values for
Thiocyanates
(Multiple CASRNs)
Derivation of Subchronic and Chronic Oral RfDs
Superfund Health Risk Technical Support Center
National Center for Environmental Assessment
Office of Research and Development
U.S. Environmental Protection Agency
Cincinnati, OH 45268

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ACRONYMS AND ABBREVIATIONS
Bw	body weight
cc	cubic centimeters
CD	Caesarean Delivered
CERCLA	Comprehensive Environmental Response, Compensation and Liability Act
of 1980
CNS	central nervous system
cu.m	cubic meter
DWEL	Drinking Water Equivalent Level
FEL	frank-effect level
FIFRA	Federal Insecticide, Fungicide, and Rodenticide Act
g	grams
GI	gastrointestinal
HEC	human equivalent concentration
Hgb	hemoglobin
i.m.	intramuscular
i.p.	intraperitoneal
i.v.	intravenous
IRIS	Integrated Risk Information System
IUR	inhalation unit risk
kg	kilogram
L	liter
LEL	lowest-effect level
LOAEL	lowest-observed-adverse-effect level
LOAEL(ADJ)	LOAEL adjusted to continuous exposure duration
LOAEL(HEC)	LOAEL adjusted for dosimetric differences across species to a human
m	meter
MCL	maximum contaminant level
MCLG	maximum contaminant level goal
MF	modifying factor
mg	milligram
mg/kg	milligrams per kilogram
mg/L	milligrams per liter
MRL	minimal risk level
MTD	maximum tolerated dose
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MTL
median threshold limit
NAAQS
National Ambient Air Quality Standards
NOAEL
no-observed-adverse-effect level
NOAEL(ADJ)
NOAEL adjusted to continuous exposure duration
NOAEL(HEC)
NOAEL adjusted for dosimetric differences across species to a human
NOEL
no-ob served-effect level
OSF
oral slope factor
p-IUR
provisional inhalation unit risk
p-OSF
provisional oral slope factor
p-RfC
provisional inhalation reference concentration
p-RfD
provisional oral reference dose
PBPK
physiologically based pharmacokinetic
ppb
parts per billion
ppm
parts per million
PPRTV
Provisional Peer Reviewed Toxicity Value
RBC
red blood cell(s)
RCRA
Resource Conservation and Recovery Act
RDDR
Regional deposited dose ratio (for the indicated lung region)
REL
relative exposure level
RfC
inhalation reference concentration
RfD
oral reference dose
RGDR
Regional gas dose ratio (for the indicated lung region)
s.c.
subcutaneous
SCE
sister chromatid exchange
SDWA
Safe Drinking Water Act
sq.cm.
square centimeters
TSCA
Toxic Substances Control Act
UF
uncertainty factor
Hg
microgram
|iinol
micromoles
voc
volatile organic compound
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PROVISIONAL PEER REVIEWED TOXICITY VALUES FOR THIOCYANATES
(MULTIPLE CASRNs)
Derivation of Subchronic and Chronic Oral RfDs
Background
On December 5, 2003, the U.S. Environmental Protection Agency's (EPA's) Office of
Superfund Remediation and Technology Innovation (OSRTI) revised its hierarchy of human
health toxicity values for Superfund risk assessments, establishing the following three tiers as the
new hierarchy:
1. EPA's Integrated Risk Information System (IRIS).
2. Provisional Peer-Reviewed Toxicity Values (PPRTV) used in EPA's Superfund
Program.
3. Other (peer-reviewed) toxicity values, including:
~ Minimal Risk Levels produced by the Agency for Toxic Substances and Disease
Registry (ATSDR),
~ California Environmental Protection Agency (CalEPA) values, and
~ EPA Health Effects Assessment Summary Table (HEAST) values.
A PPRTV is defined as a toxicity value derived for use in the Superfund Program when
such a value is not available in EPA's Integrated Risk Information System (IRIS). PPRTVs are
developed according to a Standard Operating Procedure (SOP) and are derived after a review of
the relevant scientific literature using the same methods, sources of data, and Agency guidance
for value derivation generally used by the EPA IRIS Program. All provisional toxicity values
receive internal review by two EPA scientists and external peer review by three independently
selected scientific experts. PPRTVs differ from IRIS values in that PPRTVs do not receive the
multi-program consensus review provided for IRIS values. This is because IRIS values are
generally intended to be used in all EPA programs, while PPRTVs are developed specifically for
the Superfund Program.
Because science and available information evolve, PPRTVs are initially derived with a
three-year life-cycle. However, EPA Regions or the EPA Headquarters Superfund Program
sometimes request that a frequently used PPRTV be reassessed. Once an IRIS value for a
specific chemical becomes available for Agency review, the analogous PPRTV for that same
chemical is retired. It should also be noted that some PPRTV manuscripts conclude that a
PPRTV cannot be derived based on inadequate data.
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Disclaimers
Users of this document should first check to see if any IRIS values exist for the chemical
of concern before proceeding to use a PPRTV. If no IRIS value is available, staff in the regional
Superfund and RCRA program offices are advised to carefully review the information provided
in this document to ensure that the PPRTVs used are appropriate for the types of exposures and
circumstances at the Superfund site or RCRA facility in question. PPRTVs are periodically
updated; therefore, users should ensure that the values contained in the PPRTV are current at the
time of use.
It is important to remember that a provisional value alone tells very little about the
adverse effects of a chemical or the quality of evidence on which the value is based. Therefore,
users are strongly encouraged to read the entire PPRTV manuscript and understand the strengths
and limitations of the derived provisional values. PPRTVs are developed by the EPA Office of
Research and Development's National Center for Environmental Assessment, Superfund Health
Risk Technical Support Center for OSRTI. Other EPA programs or external parties who may
choose of their own initiative to use these PPRTVs are advised that Superfund resources will not
generally be used to respond to challenges of PPRTVs used in a context outside of the Superfund
Program.
Questions Regarding PPRTVs
Questions regarding the contents of the PPRTVs and their appropriate use (e.g., on
chemicals not covered, or whether chemicals have pending IRIS toxicity values) may be directed
to the EPA Office of Research and Development's National Center for Environmental
Assessment, Superfund Health Risk Technical Support Center (513-569-7300), or OSRTI.
INTRODUCTION
Neither a subchronic nor a chronic reference dose (RfD) for thiocyanates is listed on the
Integrated Risk Information System (IRIS) (U.S. EPA, 2006), in the Health Effects Assessment
Summary Tables (HEAST) (U.S. EPA, 1997), or in the Drinking Water Standards and Health
Advisories list (U.S. EPA, 2004). The Chemical Assessments and Related Activities (CARA)
list (U.S. EPA, 1991, 1994) does not report any relevant documents for thiocyanates. The
Agency for Toxic Substances and Disease Registry (ATSDR) (2005), International Agency for
Research on Cancer (IARC) (2005), National Toxicology Program (NTP) (2005) and the World
Health Organization (WHO) (2005) have not published documents for thiocyanates. Literature
searches were conducted from 1965 to September, 2002 in TOXLINE, MEDLINE,
CANCERLIT, CCRIS, TSCATS, HSDB, RTECS, GENETOX, DART/ETICBACK and
EMIC/EMICBACK. Update literature searches were conducted from September, 2002 to
August, 2005 in MEDLINE, TOXLINE (NTIS), TOXCENTER (BIOSIS), TSCATS, CCRIS,
DART/ETIC, GENETOX, HSDB, RTECS and Current Contents. Searches were conducted for
the following thiocyanates: sodium thiocyanate (CASRN 540-72-7), potassium thiocyanate
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(CASRN 333-20-0), calcium thiocyanate (CASRN 2092-16-2), ammonium thiocyanate (CASRN
1762-95-4) and thiocyanic acid (CASRN 463-56-9).
REVIEW OF THE PERTINENT LITERATURE
Human Studies
In the past, thiocyanate was used therapeutically to treat severe hypertension. A number
of early reports describe the efficacy of thiocyanate therapy, with 45-78% of treated patients
responding favorably to the treatment (Barker, 1936; Barker et al., 1941; Palmer et al., 1929).
Dose levels ranged from 0.09-0.3 g/day (1.3-4.3 mg/kg-day, assuming a 70 kg reference body
weight) with a general lowering of blood pressure of 20-40 mm Hg. However, the results of
thiocyanate therapy were inconsistent from clinic to clinic, and even within a single study two
patients rarely responded similarly to equivalent treatment regimens (Barker, 1936). Numerous
adverse effects were noted in treated patients, including weakness, swollen face, somnolence,
enlarged thyroid, and death (Barker, 1936; Barker et al., 1941; Palmer et al., 1929; Russel and
Stahl, 1942). These effects were unpredictable in occurrence, even when blood thiocyanate
levels were monitored to control the dose. The mechanism of the antihypertensive effects of
thiocyanate is not presently known.
Of particular note were the reports of effects of thiocyanate exposure on the thyroid.
While the reported incidence of thyroid-related effects was generally less than 10% (Barker et
al., 1941; Taylor, 1945), the studies typically noted only gross changes, with no discussion of
possible alterations in functional status. Thiocyanate has since been shown to produce a marked,
reversible depression of thyroid iodine uptake, which is exacerbated by iodine deficiency and
can be reduced or eliminated by co-exposure to iodide (Beamish et al., 1954; Thilly et al., 1980).
Later studies (Banerjee et al., 1997; Dahlberg et al., 1984, 1985; Delange et al., 1980a; Thilly et
al., 1980) have reported that elevated thiocyanate levels in serum can have effects on the
histologic structure and function of the thyroid.
Thiocyanate is believed to play a role in an endogenous antibacterial system
(lactoperoxidase/ thiocyanate/ hydrogen peroxide system) present in milk. It has been added
commercially to some milk preparations as an antibacterial agent. Dahlberg et al. (1984)
exposed 37 volunteers (9 males and 28 females) affiliated with University departments in
Uppsala (Sweden), ages 16-54, to milk containing 20 mg SCN (thiocyanate)/L as sodium
thiocyanate. The human subjects research ethics of this study were reviewed and approved by
the Human Subjects Committee of the University of Upsala, Sweden. Of the subjects, 32 were
nonsmokers and 5 were smokers; smokers and nonsmokers were analyzed separately. All
subjects had normal dietary habits, were of normal health status and had no early incidence of
goiter or thyroid dysfunction. Each subject consumed 200 mL of milk twice daily, for a total
intake of 8 mg SCN/day, for 12 weeks; assuming a reference body weight of 70 kg, the average
daily dose was 0.11 mg SCN/kg-day. Serum thiocyanate levels were significantly increased at 4,
8 and 12 weeks of exposure in nonsmokers and at 4 weeks in smokers. No changes were seen in
urinary iodine levels in either group at any evaluated time point. No significant changes were
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reported in serum concentrations of thyroxine (T4), triiodothyronine (T3) or thyroid-stimulating
hormone (TSH) in either the smokers or the nonsmokers. Effects on other endpoints were not
evaluated.
Dahlberg et al. (1985) examined the effect of 4 weeks of exposure to thiocyanate on 55
iodine-deficient subjects (31 males, 24 females) between 13 and 17 years of age. The subjects
were volunteers from four different secondary schools in western Sudan, where goiter is
endemic, reportedly as a consequence of dietary iodine deficiency. The human subjects research
ethics of this study were reviewed and approved by the Human Subjects Committee of the
University of Upsala, Sweden and by the University of Kartoum, Sudan. All subjects were
goiterous in stage I and II based on the size of the thyroid gland, but otherwise had a normal
health status and were clinically euthyroid. Subjects consumed 250 mL of milk containing either
3.6 mg SCN/L (n=19) or 19 mg SCN/L (n=18) per day; an additional group received milk
containing 19 mg SCN/L together with an iodine supplement. Using an estimated mean body
weight of 50 kg for the Sudanese teenagers (which appears reasonable based on average body
weights of 53 to 65 kg for U.S. teenagers of the same ages [U.S. EPA, 2002]), average daily
doses were 0.018 mg/kg-day and 0.095 mg/kg-day for the 3.6 mg/L and 19 mg/L groups,
respectively. Day 0 readings for each group served as reference values for statistical analysis.
Serum thiocyanate levels were significantly elevated in both groups receiving 19 mg SCN/L, but
not in the 3.6 mg SCN/L group. In all groups, an increase in urinary iodine was seen following
thiocyanate exposure; the magnitude of the change was greatest in the iodine-supplemented
subjects and lowest in the unsupplemented 19 mg/L group. Thiocyanate exposure resulted in
significantly decreased serum TSH in all groups (14%, 17% and 25% decreases in the 3.6 mg/L,
19 mg/L and 19 mg/L+iodine groups, respectively), as well as decreased T3 (12.5% and 15%
decrease in the 3.6 and 19 mg/L groups, respectively) and T4 (13% and 11% decrease in the 3.6
and 19 mg/L groups, respectively) in groups without iodine supplementation. Iodine
supplementation reversed the decrease in serum T3 and T4 levels seen in the 19 mg/L group.
Other endpoints were not evaluated in this study.
Banerjee et al. (1997) evaluated the chronic effects of oral thiocyanate on women in
Calcutta. Thirty five women who had consumed -250 mL/day of a commercially-available
cow's milk containing 30-50 mg SCN/L (average level of 45 mg SCN/L) for the previous 5
years were selected as the exposed group, while an equal number of women matched for age and
dietary habits, aside from consumption of thiocyanate-treated milk, were designated as the
control group. Review of the publication does not provide information on the human subjects
research ethics procedures undertaken in this study, but there is no evidence that the conduct of
the research was fundamentally unethical or significantly deficient. Women from both groups
had similar dietary patterns, did not use tobacco products and had no prior history of thyroid
disease. Blood was taken from each subject and analyzed for serum levels of SCN, TSH, T3, and
T4, and a urine sample was taken for iodine determination. Other endpoints were not evaluated.
Based on the average milk concentration of 45 mg SCN/L, an estimated milk consumption of
0.25 L/day, and a reference body weight for women of 60 kg, average daily consumption of
thiocyanate was 0.19 mg/kg-day. No differences in urinary iodine elimination were noted
between groups. The results of the thyroid hormone evaluations are presented in Table 1, below.
Women who consumed SCN-containing milk had significantly lower levels of serum T4 and
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significantly greater levels of serum TSH than controls; serum T3 levels were elevated, but not
significantly. The decrease in serum T4 went below normal levels, as described by the assay
manufacturer. Significant correlations were found between serum thiocyanate concentrations
and serum T4 (negative correlation) and TSH levels (positive correlation) in the exposed group;
similar correlations were not found in the control group. Although the data in Table 1 suggest
that levels of serum thiocyanate in controls were above normal, the researchers noted that a
previous analysis conducted on non-smokers from the same geographic region as the current
study found serum thiocyanate levels in non-smokers for this region in the range of 80-100
|imol/L, which is consistent with results of this study.
Table 1 - Results of Banerjee et al. (1997) Evaluations of Thyroid Endpoints

Control Subjects
Thiocyanate Subjects
Normal Range

Mean
SE
Mean
SE
SCN (umol/L)
90.8
9.0
230.0a
10.0
34-69b
T4 (nmol/L)
125.4
11.5
87.8a
6.6
110-270c
T3 (nmol/L)
1.71
0.16
2.39
0.32
0.93-3.12c
TSH (|iU/mL)
1.09
0.28
2.49a
0.20
0.2-4.0c
11 significantly different (p<0.01) from the control group
b Pechacek et al., 1985


0 reported by the assay manufacturer




Studies of humans who consume heavy amounts of cassava, consisting of up to 80% of
the total diet in some cases (Dorea et al., 2004), have provided suggestive evidence of effects of
thiocyanate on the thyroid of both adults and the developing child. Cassava contains high levels
of cyanide, which, when consumed orally, is metabolized to thiocyanate; considerable increases
(up to 5-fold or more) in blood thiocyanate levels have been reported following exposure to
cyanide-rich cassava (Cliff et al., 1986; Delange et al., 1980b).
Delange et al. (1980b) reported that pregnant women in Zaire who regularly consumed
cassava had statistically significantly elevated blood thiocyanate levels relative to a control
group of pregnant Belgian women (0.68 mg SCN/dL in the Zairian women, relative to 0.21 mg
SCN/dL in the Belgian women), as well as significantly elevated TSH (14.0 |iU/mL in the
Zairian women and 3.9 |iU/mL in the Belgian women) and significantly decreased serum
concentrations of T4 (8.6 |ig/dL in the Zairian women and 15.3 |ig/dL in the Belgian women) and
T3 (191 ng/dL in the Zairian women and 220 ng/dL in the Belgian women). In newborns of
these women, significantly greater serum SCN levels were noted (0.62 mg/dL in the Zairian
newborns and 0.19 mg/dL in the Belgian newborns), as well as significantly increased serum
TSH (50.9 |iU/mL in the Zairian newborns and 6.8 |iU/mL in the Belgian newborns) and T3 (106
ng/dL in the Zairian newborns and 60 ng/dL in the Belgian newborns) and significantly
decreased serum T4 (7.5 |ig/dL in the Zairian newborns and 12.0 |ig/dL in the Belgian
newborns). Similar results were seen in infants (aged 2 weeks to 15 months), with significantly
increased serum SCN (0.55 mg/dL in the Zairian infants and 0.38 mg/dL in the Belgian infants)
and TSH (52.6 |iU/mL in the Zairian infants and 3.5 |iU/mL in the Belgian infants) and
significantly decreased T4 (6.9 |ig/dL in the Zairian infants and 8.7 |ig/dL in the Belgian infants);
serum levels of T3 were not affected in infants. Maternal serum concentrations of thiocyanate at
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delivery were linearly correlated with those in the umbilical cord blood. Concentrations of
thiocyanate in the milk were not significantly different between Zairian and Belgian mothers.
Animal Studies
In an early study of the subchronic toxicity of thiocyanate, Anderson and Chen (1940)
exposed groups of 10 female rats (strain unspecified) by gavage to 100 mg sodium
thiocyanate/kg-day (-71.6 mg SCN/kg-day), 100 mg potassium thiocyanate/kg-day (-59.8 mg
SCN/kg-day) or vehicle 5 days/week for 12 weeks. Prior to study termination, four control rats,
four sodium thiocyanate rats and two potassium thiocyanate rats died due to gavage errors.
Neither thiocyanate compound resulted in growth inhibition; effects on other endpoints were not
reported. A follow-up experiment was conducted, exposing groups of 10 rats to 200 mg of
sodium or potassium thiocyanate (143 or 120 mg SCN/kg-day, respectively) 5 days/week for 8
weeks. As with the previous experiment, no changes in growth were seen as a result of
thiocyanate treatment and other endpoints were not evaluated. In the third portion of the study,
groups of dogs (n=4-5) were exposed to approximately 100 mg/kg-day of sodium (-71.6 mg
SCN/kg-day) or potassium (-59.8 mg SCN/kg-day) thiocyanate, as enterically-coated capsules, 5
days/week for up to 3 months. Repeated ingestion of 100 mg/kg-day of sodium or potassium
thiocyanate resulted in severe clinical effects, including progressive weight loss, apathy, head-
droop and ataxia; all animals but one at this exposure level died, despite discontinuation of
exposure (cause of death could not be determined). Another group of three animals, one of
which had been previously exposed to higher levels of thiocyanate, was exposed to 20-25
mg/kg-day; these animals showed no evidence of toxicity (further details not reported). A single
dog exposed to 31 mg sodium thiocyanate/kg-day died following 7 weeks of treatment during
which the dog showed progressive body weight decrease; a precise cause of death was not
determined.
Lindberg et al. (1941) exposed 12 dogs to 300 mg potassium thiocyanate/day (75 mg
SCN/kg-day, assuming a reference body weight [U.S. EPA, 1988] of 2.4 kilograms) for 3
months. Body weight and clinical signs were not evaluated. Thiocyanate exposure resulted in
an abrupt fall in blood cholesterol, followed by a slow decline over time. There was a rough
parallel between elevation of blood thiocyanate levels and decreased cholesterol level once the
initial decrease had stabilized. A similar effect was noted for total plasma protein levels.
Thiocyanate exposure resulted in a fall in erythrocyte numbers, as well as decreased hematocrit
and hemoglobin; no changes were seen in white cell numbers. Histologic sections of bone
marrow revealed an essentially acellular bone marrow in treated animals, and examination of the
livers of treated animals revealed a diffuse intracellular vacuolization with no evidence of
hyperplasia or regeneration; no changes were seen in the adrenal glands of treated animals.
Nagasawa et al. (1980) exposed groups of 18 weanling SHN female mice (a strain with a
high background mammary tumor incidence) to 0, 0.1 or 0.3% potassium thiocyanate in the
drinking water for 12 weeks. Using the allometric equations and mean body weights presented
in U.S. EPA (1988), mean thiocyanate doses were estimated at 0, 153 and 457 mg SCN/kg-day
for the 0, 0.1 and 0.3% groups, respectively. No differences between groups were noted in body
weight or body weight gain, estrous cycle pattern, pituitary or adrenal weight or ovarian
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histology. Dose-related decreases in serum T3 (significant in the 0.3% group) and T4 (significant
in the 0.1 and 0.3% groups) were reported. Development of the lobulo-alveolar system of the
mammary gland was significantly inhibited in the 0.3% group. Dose-related decreases in
preneoplastic mammary hyperplastic alveolar nodules and mammary tumor incidence were
reported; these decreases attained statistical significance in the 0.3% animals.
In a second experiment, Nagasawa et al. (1980) exposed groups of 19-22 female GR/A
mice to 0, 0.1 or 0.3% potassium thiocyanate in the drinking water for 5 weeks prior to and for
10 weeks following mating; exposure was discontinued for the 3 days during which mating
occurred. Using the allometric equations and mean body weights presented in U.S. EPA (1988),
mean thiocyanate doses were estimated at 0, 155 and 470 mg SCN/kg-day for the 0, 0.1 and
0.3% groups, respectively. At the end of exposure, the animals were sacrificed and examined for
changes in reproductive parameters (number of pregnancies, litter size, pup weight, percent
stillborn pups) and the presence of pregnancy-dependent mammary tumors (PDMT). On day 4
of lactation, plasma prolactin levels were evaluated in the dams. No changes in maternal body
weight, evaluated reproductive parameters or plasma prolactin levels were noted following
thiocyanate treatment. Treatment with thiocyanate resulted in a significantly decreased number
of PDMT (16/22, 7/20, 5/19 PDMT in the 0, 0.1 and 0.3% groups, respectively). No other
endpoints were evaluated in the study.
Ermans et al. (1980) exposed groups of rats (n=9-25) to 0.1-10 mg thiocyanate/day (-0.6-
56 mg/kg-day, based on a reference body weight of 180 g) in the diet for 2-5 weeks; the diet was
intentionally iodine-deficient. Treated rats showed a dose-related depletion of thyroid iodine
content, reaching 40-50% of the control value. Exposure to 10 mg/day resulted in a significant
decrease in T4 levels, while T3 levels were not altered. Effects on organs other than the thyroid
were not reported.
Philbrick et al. (1979) exposed groups (n=10) of male rats to 0 or 2240 ppm potassium
thiocyanate (KSCN) in the diet for 11.5 months. Both iodine-supplemented and iodine-deficient
diets were provided, with appropriate controls. Using a reference body weight of 380 grams and
reference food consumption of 30 g/day (U.S. EPA, 1988), an average daily dose of 106 mg
SCN/kg-day can be estimated. At 4 and 11 months, five animals per group were evaluated for
plasma T4, T4 secretion rates and urinary thiocyanate concentrations. At terminal sacrifice,
weights of whole brain, heart, liver and thyroid were obtained. Brain, optic nerves, spinal cord
and thyroid glands were fixed for light microscopy and sections of spinal cord were prepared for
electron microscopic evaluation. No changes in body weight gain were seen as a result of KSCN
treatment and no adverse clinical effects were reported. Treatment with thiocyanate resulted in
significant decreases in plasma T4 and T4 secretion rate at 4 months and decreased thyroid
weight and plasma T4 at 11 months; T4 secretion rate was not different from controls after 11
months of thiocyanate exposure. No definitive histological changes in the thyroid gland, optic or
sciatic nerves or neural tissues were seen in animals receiving iodine supplementation along with
KSCN treatment. However, it appeared that KSCN treatment resulted in an alteration of the
vacuolization in spinal cord tissues that was seen in control animals fed an iodine-deficient diet.
This vacuolization, which was accompanied by a mild-to-moderate astrogliosis (no
quantification was provided), was seen at both the light and electron microscopic level.
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Bala et al. (1996) exposed groups of 8-week old female Wistar/NIN rats to 0 or -15 mg
SCN/kg-day, as potassium thiocyanate, for varying times throughout conception and lactation.
After 8 weeks of exposure, the animals were mated with control males and monitored throughout
gestation, parturition and lactation. In one group, the effect of exposure of the offspring was also
examined, using the same dietary exposure level, with a parallel group that was exposed during
gestation and weaning but not post-weaning. Exposure to KSCN did not affect the body weight
or the ratio of brain-to-body weight of any group of dams. Animals exposed to KSCN from the
beginning of the experiment through weaning showed a significantly increased urinary excretion
of iodine, as well as increased thyroid weight and decreased levels of serum T4. In the pups of
animals exposed to SCN, a significant decrease in serum T4 levels was noted; this decrease was
present whether the dams had been exposed from the beginning of the study, were exposed from
conception through weaning or were exposed only after giving birth. Pup body weights at
weaning were decreased in animals exposed beginning at conception through weaning, but not in
those exposed throughout the experiment or those only exposed postpartum. Exposure to SCN
did not result in a significant change in the uptake of sucrose, leucine, tyrosine or 2-deoxy-D-
glucose, regardless of time of exposure. Offspring not exposed during gestation, but exposed in
the diet post-weaning showed significant decreases in serum T4 and significant increases in brain
weight, as did offspring exposed during gestation and lactation, but not exposed post-weaning.
The paper did not report on the presence or lack of malformations in the offspring of treated
dams.
In a subsequent report, Raghunath and Bala (1998) examined the offspring of Wistar/NIN
rat dams exposed either prior to mating throughout weaning, from conception through weaning
or from parturition through weaning (offspring of the dams from Bala et al., 1996) to -15 mg
SCN/kg-day in the diet, as potassium thiocyanate, for 8 weeks. At weaning (the start of the
follow-up study), the offspring in all three treated groups already had lower serum T4 levels,
relative to untreated controls. Further treatment with SCN did not result in an additional
lowering of serum T4 levels. Offspring of animals exposed continuously from weaning, through
pregnancy and lactation, showed a decreased brain uptake of 2-deoxy-D-glucose relative to
controls; this change was not noted in the offspring of animals treated from conception onward
or in those whose dams were only exposed during weaning.
In a second portion of the manuscript (Raghunath and Bala, 1998), the authors describe a
continuous 2-generation exposure to -15 mg SCN/kg-day, as potassium thiocyanate, in
Wistar/NIN rats. F0 animals were exposed from weaning (8 weeks of age) throughout gestation
and lactation. At weaning, the Fi pups were exposed to an identical diet for 8 weeks, then mated
and exposed throughout gestation, parturition and weaning. F2 pups showed no changes in body
weight at birth or weaning and brain weight was not affected. Serum levels of T4 were
significantly decreased in F2 pups; this decrease was greater than the decrease seen in their Fi
counterparts. Treated F2 rats showed a significant decrease in the brain uptake of 2-deoxy-D-
glucose, leucine and tyrosine; brain uptake of sucrose was not affected. Effects on other
endpoints were not evaluated.
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Delange et al. (1980a) exposed pregnant Wistar rats to 0 or 10 mg thiocyanate/day from
the second day of pregnancy through weaning (postnatal day 16). Based on body weights
provided in the manuscript, the average daily dose was calculated to be 45-56 mg/kg-day.
Additional groups received 25 or 100 |ig of potassium iodide by intraperitoneal injection 2 days
prior to delivery. Exposure to SCN had no effect on body weights of the dams at birth or at the
end of exposure. Maternal thyroid weights were increased, but not significantly. At both
delivery and weaning, hyperplasia of the thyroid was noted in SCN-exposed dams; treatment
with iodide resulted in a dose-related reduction in the severity of the hyperplastic effect. A
significant decrease in T4 was noted only at delivery and a decrease in T3 was noted only at
weaning; treatment with iodide completely reversed these effects. Weights of the pups were not
affected by exposure with the exception of the group that received 25 |ig of iodide prior to
delivery (pup weights in 100 |ig iodide group were not different from controls). Effects in pups
at weaning, relative to controls, were significantly increased thyroid weights, hyperplasia of the
thyroid and decreased levels of serum T4; administration of iodide prior to birth did not
ameliorate these effects.
DERIVATION OF PROVISIONAL SUBCHRONIC AND CHRONIC RfDs
FOR THIOCYANATES
The available human data clearly identify both decreased blood pressure and changes in
thyroid function as sensitive effects of oral exposure to thiocyanates. However, the effects on
blood pressure were reported at doses generally ranging from 1.3-4.3 mg/kg-day (Barker, 1936;
Barker et al., 1941; Palmer et al., 1929), while effects on the thyroid occurred at exposure levels
of 0.19 mg/kg-day in healthy subjects (Banerjee et al., 1997). Animal studies likewise indicate
that the thyroid is the most sensitive target of thiocyanate toxicity, although the effect levels are
considerably greater in animal studies (on the order of 15-100 mg/kg-day) than in the available
human studies.
The Dahlberg et al. (1985) study was considered for use as the principal study in p-RfD
derivation because it identified the lowest LOAEL in exposed humans, 0.018 mg/kg-day for
decreased serum TSH, T3 and T4 in iodine-deficient subjects exposed to thiocyanate for 4 weeks.
However, concerns over the design of this study, including the age of the study group (13-17
years), the comparatively short duration (4 weeks) and the fact that the subjects were goiterous in
stage I or II (and therefore already had an existing thyroid condition) prior to the start of the
study, preclude its selection as the principal study for derivation of the subchronic or chronic p-
RfD. Another study by the same investigators (Dahlberg et al., 1984) identified a NOAEL of
0.11 mg/kg-day for effects on thyroid function in healthy volunteers exposed for 12 weeks, but
concerns regarding the ages of the study population, the comparatively short study duration and
the lack of identification of a LOAEL preclude its selection as the principal study for p-RfD
derivation.
The study of Banerjee et al. (1997) evaluated a group of women exposed to an average of
0.19 mg thiocyanate/kg-day for 5 years, relative to a matched control group. In addition to
elevated serum thiocyanate levels, a significant increase in serum TSH and a significant decrease
9

-------
3-15-2006
in serum T4 were observed in thiocyanate-exposed women. While the change in TSH was
statistically significant (p<0.01) from the controls, the mean value of the treated group (2.49
|iU/mL) was within the normal range of the assay (0.2-4.0 |iU/mL). Serum T4 was both
statistically different from controls and altered to a level outside of the normal assay range. The
0.19 mg/kg-day exposure level is therefore identified as a LOAEL for changes in thyroid
endpoints. The LOAEL is supported by the LOAEL of 0.018 mg/kg-day in sensitive subjects
reported by Dahlberg et al. (1985), which is approximately an order of magnitude lower than that
of healthy subjects, as would be expected from a standard uncertainty factor (UF) approach. The
Banerjee et al. (1997) study was therefore selected as the principal study for p-RfD derivation.
To derive the subchronic p-RfD, the LOAEL of 0.19 mg/kg-day is divided by an UF of
300 (10 to protect sensitive individuals, 10 for use of a LOAEL and 3 for deficiencies in the
database, specifically the limited evaluations of dose-response available for humans, since
effects in animals appear to occur at considerably higher doses). The subchronic p-RfD of 6E-4
mg/kg-day is derived as follows:
Subchronic p-RfD = LOAEL + UF
= 0.19 mg/kg-day ^-300
= 0.0006 or 6E-4 mg/kg-day
To derive the chronic p-RfD, an additional UF of 3 was applied for extrapolation from
subchronic to chronic duration. A full factor of 10 was not applied because while the Banerjee et
al. (1997) study ran for less than 10% of the total expected lifespan, the study duration of 5 years
was likely sufficient to establish an equilibrium of thiocyanate levels within the body, based on
an estimated serum half-life of approximately 3 days (Schulz, 1984). The total UF for the
chronic p-RfD is therefore 1000 (3 for extrapolation from subchronic to chronic duration, 10 to
protect sensitive individuals, 10 for use of a LOAEL and 3 for deficiencies in the database,
specifically the limited evaluations of dose-response available for humans, since effects in
animals appear to occur at considerably higher doses). The chronic p-RfD of 2E-4 mg/kg-day
is derived as follows:
p-RfD = LOAEL - UF
= 0.19 mg/kg-day + 1000
= 0.0002 or 2E-4 mg/kg-day
Confidence in the principal study is low. While the study evaluated the most sensitive
known endpoints for thiocyanate exposure, it did so at only one time point, non-thyroid
endpoints were not evaluated and a NOAEL was not identified. Confidence in the database is
medium. The available human data support the choice of critical effect and considerable animal
data exist supporting thyroid effects as a sensitive endpoint of thiocyanate; however, only limited
dose-response data on the effects of oral thiocyanate in humans are available and the effects seen
in animal studies appear to occur at considerably greater levels (-100-1000-fold) than those in
humans. Low confidence in the provisional subchronic and chronic RfD values results.
10

-------
3-15-2006
REFERENCES
Anderson, R.C. and K.K. Chen. 1940. Absorption and toxicity of sodium and potassium
thiocyanates. J. Am. Pharm. Assoc. 6:152-161.
ATSDR (Agency for Toxic Substances and Disease Registry). 2005. Internet HazDat
Toxicological Profile Query. U.S. Department of Health and Human Services, Public Health
Service. Atlanta, GA. Available at http://www.atsdr.cdc.gov/gsql/toxprof.script.
Bala, T.S., M.K. Janardanasarma and M. Raghunath. 1996. Dietary goitrogen-induced changes
in the transport of 2-deoxy-D-glucose and amino acids across the rat blood-brain barrier. Int. J.
Dev. Neurosci. 14(5):575-583.
Banerjee, K.K., P. Marimuthu, P. Bhattacharyya and M. Chatterjee. 1997. Effect of thiocyanate
ingestion through milk on thyroid hormone homeostasis in women. Brit. J. Nutr. 78(5):679-681.
Barker, M.H. 1936. The blood cyanates in the treatment of hypertension. J. Am. Med. Assoc.
106:762-767.
Barker, M.H., H.A. Lindberg and M.H. Wald. 1941. Further experiences with thiocyanates. J.
Am. Med. Assoc. 117:1591-1594.
Beamish, R.E., W.F. Perry and V.M. Storrie. 1954. Observations on thyroid function in
hypertensive patients treated with potassium thiocyanate. Am. Heart. J. 48:433-438.
Cliff, J., P. Lundquist, H. Rosling, B. Sorbo and L. Wide. 1986. Thyroid function in a cassava-
eating population affected by epidemic spastic paraparesis. Acta Endocrin. 113:523-528.
Dahlberg, P.A., A. Bergmark, L. Bjorck et al. 1984. Intake of thiocyanate by way of milk and
its possible effect on thyroid function. Am. J. Clin. Nutr. 39(3):416-420.
Dahlberg, P.A., A. Bergmark, M. Eltom et al. 1985. Effect of thiocyanate levels in milk on
thyroid function in iodine deficient subjects. Am. J. Clin. Nutr. 41(5): 1010-1014.
Delange, F., N. Van Minh, L. Vanderlinden et al. 1980a. Influence of goitrogens in pregnant
and lactating rats on thyroid function in the pups. In: Role of cassava in the etiology of endemic
goitre and cretinism. A.M. Ermans, N.M. Mbulamoko, F. Delange and A. Ahluwalia, Eds. pp.
127-134.
Delange, F., P. Bourdoux, R. Lagasse et al. 1980b. Effects of thiocyanate during pregnancy and
lactation on thyroid function in infants. In: Role of assava in the etiology of endemic goitre and
cretinism. A.M. Ermans, N.M. Mbulamoko, F. Delange and A. Ahluwalia, Eds. pp. 121-126.
Dorea, J.D. 2004. Maternal thiocyanate and thyroid status during breast-feeding. J. Am. Col.
Nutr. 23(2):97-101.
11

-------
3-15-2006
Ermans, A.M., J. Kinthaert, M. van der Velden and P. Bourdoux. 1980. Studies of the
antithyroid effects of cassava and of thiocyanate in rats. In: Role of cassava in the etiology of
endemic goitre and cretinism. A.M. Ermans, N.M. Mbulamoko, F. Delange and A. Ahluwalia,
Eds. pp. 93-110.
IARC (International Agency for Research on Cancer). 2005. IARC Agents and Summary
Evaluations. Available at http://www-cie.iarc.fr/htdig/search.html.
Lindberg, H.A., M.H. Wald and M.H. Barker. 1941. Observations on the pathologic effects of
thiocyanate: An experimental study. Am. Heart. J. 21:605-616.
Nagasawa, H., R. Yanai, Y. Nakajima et al. 1980. Inhibitory effects of potassium thiocyanate
on normal and neoplastic mammary development in female mice. Eur. J. Cancer. 16:473-480.
NTP (National Toxicology Program). 2005. Management Status Report. Available at
http://ntp-server.niehs.nih.gov/cgi/iH Indexes/Res Stat/iH Res Stat Frames.html.
Palmer, R.S., L.S. Silver and P.D. White. 1929. Clinical use of potassium sulfocyanate in
hypertension: A preliminary report of 59 cases. New Engl. J. Med. 201:709-714.
Pechacek, T.F., A.R. Folsom, R. de Gaudermaris et al. 1985. Smoke exposure in pipe and cigar
smokers: Serum thiocyanate measures. JAMA. 254:3330-3332.
Philbrick, D.J., J.B. Hopkins, D.C. Hill et al. 1979. Effects of prolonged cyanide and
thiocyanate feeding in rats. J. Toxicol. Environ. Health. 5:579-592.
Raghunath, M. and T.S. Bala. 1998. Diverse effects of mild and potent goitrogens on blood-
brain barrier nutrient transport. Neurochem. Int. 33:173-177.
Russel, W.O. and W.C. Stahl. 1942. Fatal poisoning from potassium thiocyanate treatment of
hypertension. J. Am. Med. Assoc. 119:1177-1181.
Schulz, V. 1984. Clinical Pharmacokinetics of Nitroprusside, Cyanide, Thiosulphate and
Thiocyanate. Clin. Pharmacokinet. 9:239-251.
Taylor, R.D. 1945. Experience with potassium thiocyanate as a therapeutic agent in arterial
hypertention. Proc. Am. Federation. Clin. Res. 2:10 (Cited in Beamish et al., 1954)
Thilly, C.H., G. Roger, R. Lagasse et al. 1980. Fetomaternal relationship, fetal hypothyroidism,
and psychomotor retardation. In: Role of cassava in the etiology of endemic goitre and
cretinism. A.M. Ermans, N.M. Mbulamoko, F. Delange and A. Ahluwalia, Eds. pp. 111-120.
12

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3-15-2006
U.S. EPA. 1988. Recommendations for and Documentation of Biological Values for Use in
Risk Assessment. Environmental Criteria and Assessment Office, Office of Health and
Environmental Assessment, Office of Research and Development, U.S. Environmental
Protection Agency, Cincinnati, OH. EPA/600/6-87/008. NTIS PB 88-17874.
U.S. EPA. 1991. Chemical Assessments and Related Activities (CARA). Office of Health and
Environmental Assessment, Washington, DC. April.
U.S. EPA. 1994. Chemical Assessments and Related Activities (CARA). Office of Health and
Environmental Assessment, Washington, DC. December.
U.S. EPA. 1997. Health Effects Assessment Summary Tables. FY-1997 Update. Prepared by
the Office of Research and Development, National Center for Environmental Assessment,
Cincinnati, OH for the Office of Emergency and Remedial Response, Washington, DC. July.
EPA/540/R-97/036. NTIS PB 97-921199.
U.S. EPA. 2002. Child-Specific Exposure Factors Handbook. Interim Report. Office of
Research and Development, Washington, DC. EPA/600/P-00/002B.
U.S. EPA. 2004. 2004 Edition of the Drinking Water Standards and Health Advisories. Office
of Water, Washington, DC. EPA/822/R-02/038. Available at
http://www.epa.gov/waterscience/drinking/standards/dwstandards.pdf.
U.S. EPA. 2006. Integrated Risk Information System (IRIS). Online. Office of Research and
Development, National Center for Environmental Assessment, Washington, DC.
www.epa.gov/iris
WHO (World Health Organization). 2005. Online Catalogs for the Environmental Criteria
Series. Available at http://www.inchem.org/pages/ehc.html.
13

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01-26-05
Provisional Peer Reviewed Toxicity Values for
Thiocyanates
(Multiple CASRNs)
Derivation of Subchronic and Chronic Inhalation RfCs
Superfund Health Risk Technical Support Center
National Center for Environmental Assessment
Office of Research and Development
U.S. Environmental Protection Agency
Cincinnati, OH 45268

-------
Acronyms
bw - body weight
cc - cubic centimeters
CD - Caesarean Delivered
CERCLA - Comprehensive Environmental Response, Compensation, and Liability Act of 1980
CNS - central nervous system
cu.m - cubic meter
DWEL - Drinking Water Equivalent Level
FEL - frank-effect level
FIFRA - Federal Insecticide, Fungicide, and Rodenticide Act
g - grams
GI - gastrointestinal
HEC - human equivalent concentration
Hgb - hemoglobin
i.m. - intramuscular
i.p. - intraperitoneal
i.v. - intravenous
IRIS - Integrated Risk Information System
IUR - Inhalation Unit Risk
kg - kilogram
L - liter
LEL - lowest-effect level
LOAEL - lowest-observed-adverse-effect level
LOAEL(ADJ) - LOAEL adjusted to continuous exposure duration
LOAEL(HEC) - LOAEL adjusted for dosimetric differences across species to a human
m - meter
MCL - maximum contaminant level
MCLG - maximum contaminant level goal
MF - modifying factor
mg - milligram
mg/kg - milligrams per kilogram
mg/L - milligrams per liter
MRL - minimal risk level
MTD - maximum tolerated dose
MTL - median threshold limit
1

-------
NAAQS - National Ambient Air Quality Standards
NOAEL - no-observed-adverse-effect level
NOAEL(ADJ) - NOAEL adjusted to continuous exposure duration
NOAEL(HEC) - NOAEL adjusted for dosimetric differences across species to a human
NOEL - no-observed-effect level
OSF - Oral Slope Factor
p-RfD - provisional Oral Reference Dose
p-RfC - provisional Inhalation Reference Concentration
p-OSF - provisional Oral Slope Factor
p-IUR - provisional Inhalation Unit Risk
PBPK - physiologically based pharmacokinetic
ppb - parts per billion
ppm - parts per million
PPRTV - Provisional Peer Reviewed Toxicity Value
RBC - red blood cell(s)
RCRA - Resource Conservation and Recovery Act
RGDR - Regional deposited dose ratio (for the indicated lung region)
REL - relative exposure level
RGDR - Regional gas dose ratio (for the indicated lung region)
RfD - Oral Reference Dose
RfC - Inhalation Reference Concentration
s.c. - subcutaneous
SCE - sister chromatid exchange
SDWA - Safe Drinking Water Act
sq.cm. - square centimeters
TSCA - Toxic Substances Control Act
UF - uncertainty factor
ug - microgram
umol - micromoles
VOC - volatile organic compound
11

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01-26-05
PROVISIONAL PEER REVIEWED TOXICITY VALUES FOR
THIOCYANATES (Multiple CASRNs)
Derivation of Subchronic and Chronic Inhalation RfCs
Background
On December 5, 2003, the U.S. Environmental Protection Agency's (EPA's) Office of
Superfund Remediation and Technology Innovation (OSRTI) revised its hierarchy of human
health toxicity values for Superfund risk assessments, establishing the following three tiers as the
new hierarchy:
1. EPA's Integrated Risk Information System (IRIS).
2. Provisional Peer-Reviewed Toxicity Values (PPRTV) used in EPA's Superfund
Program.
3. Other (peer-reviewed) toxicity values, including:
~ Minimal Risk Levels produced by the Agency for Toxic Substances and Disease
Registry (ATSDR),
~ California Environmental Protection Agency (CalEPA) values, and
~ EPA Health Effects Assessment Summary Table (HEAST) values.
A PPRTV is defined as a toxicity value derived for use in the Superfund Program when
such a value is not available in EPA's Integrated Risk Information System (IRIS). PPRTVs are
developed according to a Standard Operating Procedure (SOP) and are derived after a review of
the relevant scientific literature using the same methods, sources of data, and Agency guidance
for value derivation generally used by the EPA IRIS Program. All provisional toxicity values
receive internal review by two EPA scientists and external peer review by three independently
selected scientific experts. PPRTVs differ from IRIS values in that PPRTVs do not receive the
multi-program consensus review provided for IRIS values. This is because IRIS values are
generally intended to be used in all EPA programs, while PPRTVs are developed specifically for
the Superfund Program.
Because science and available information evolve, PPRTVs are initially derived with a
three-year life-cycle. However, EPA Regions or the EPA Headquarters Superfund Program
sometimes request that a frequently used PPRTV be reassessed. Once an IRIS value for a
specific chemical becomes available for Agency review, the analogous PPRTV for that same
chemical is retired. It should also be noted that some PPRTV manuscripts conclude that a
PPRTV cannot be derived based on inadequate data.
1

-------
01-26-05
Disclaimers
Users of this document should first check to see if any IRIS values exist for the chemical
of concern before proceeding to use a PPRTV. If no IRIS value is available, staff in the regional
Superfund and RCRA program offices are advised to carefully review the information provided
in this document to ensure that the PPRTVs used are appropriate for the types of exposures and
circumstances at the Superfund site or RCRA facility in question. PPRTVs are periodically
updated; therefore, users should ensure that the values contained in the PPRTV are current at the
time of use.
It is important to remember that a provisional value alone tells very little about the
adverse effects of a chemical or the quality of evidence on which the value is based. Therefore,
users are strongly encouraged to read the entire PPRTV manuscript and understand the strengths
and limitations of the derived provisional values. PPRTVs are developed by the EPA Office of
Research and Development's National Center for Environmental Assessment, Superfund Health
Risk Technical Support Center for OSRTI. Other EPA programs or external parties who may
choose of their own initiative to use these PPRTVs are advised that Superfund resources will not
generally be used to respond to challenges of PPRTVs used in a context outside of the Superfund
Program.
Questions Regarding PPRTVs
Questions regarding the contents of the PPRTVs and their appropriate use (e.g., on
chemicals not covered, or whether chemicals have pending IRIS toxicity values) may be directed
to the EPA Office of Research and Development's National Center for Environmental
Assessment, Superfund Health Risk Technical Support Center (513-569-7300), or OSRTI.
INTRODUCTION
Neither a subchronic nor chronic RfC for thiocyanates is listed on IRIS (U.S. EPA, 2003)
or in the HE AST (U.S. EPA, 1997). The CARA list (U.S. EPA, 1991, 1994) does not report any
relevant documents for thiocyanates. ATSDR (2002), IARC (2002) and WHO (2002) have not
published review documents for thiocyanates. Occupational exposure limits for thiocyanates
have not been established by ACGIH (2002), NIOSH (2002), or OSHA (2002a,b). Literature
searches were conducted from 1965 to September, 2002 for the following thiocyanates: sodium
thiocyanate (CASRN 540-72-7), potassium thiocyanate (CASRN 333-20-0), calcium thiocyanate
(2092-16-2), ammonia thiocyanate (CASRN 1762-95-4), and thiocyanic acid (CASRN 463-56-
9). The databases searched were TOXLINE, MEDLINE, CANCERLIT, CCRIS, TSCATS,
HSDB, RTECS, GENETOX, DART/ETICBACK, and EMIC/EMICBACK. The NTP (2002)
2

-------
01-26-05
status report was also searched for relevant information. An updated literature search was
conducted through April 2004 and no relevant information was found.
REVIEW OF THE PERTINENT LITERATURE
Human Studies
No studies were located regarding inhalation exposure of humans to thiocyanates.
Animal Studies
No studies were located regarding inhalation exposure of animals to thiocyanates.
FEASIBILITY OF DERIVING PROVISIONAL SUBCHRONIC AND CHRONIC
RfCs FOR THIOCYANATES
In the absence of subchronic or chronic inhalation data on the toxicity of thiocyanates,
derivation of a provisional subchronic or chronic RfC is precluded.
REFERENCES
ACGIH (American Conference of Governmental Industrial Hygienists). 2002. 2002 Threshold
Limit Values for Chemical Substances and Physical Agents and Biological Exposure Indices.
ACGIH, Cincinnati, OH.
ATSDR (Agency for Toxic Substances and Disease Registry). 2002. Internet HazDat
Toxicological Profile Query. U.S. Department of Health and Human Services, Public Health
Service. Atlanta, GA. Online. http://www.atsdr.cdc.gOv//qsql/toxprof.script
IARC (International Agency for Research on Cancer). 2002. IARC Agents and Summary
Evaluations. Online. http://193.51.164.il/cgi/iHound/Chem/iH Chem Frames.html
NIOSH (National Institute for Occupational Safety and Health). 2002. Online NIOSH Pocket
Guide to Chemical Hazards. Index of Chemical Abstract Numbers (CAS No.). Online.
http://www.cdc.gov/niosh/npg/npgdcas.html
NTP (National Toxicology Program). 2002. Management Status Report. Online.
http://ntp-server.niehs.nih.gov/cgi/iH Indexes/Res Stat/iH Res Stat Frames.html
3

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01-26-05
OSHA (Occupational Safety and Health Administration). 2002a. OSHA Standard 1910.1000
Table Z-2. Part Z, Toxic and Hazardous Substances. Online.
http://www.osha-slc.gov/OsliStd data/1910 1000 TABLE Z-2.html
OSHA (Occupational Safety and Health Administration). 2002b. OSHA Standard 1915.1000
for Air Contaminants. Part Z, Toxic and Hazardous Substances. Online.
http://www.osha-slc.gov/OshStd data/1915 1000.html
U.S. EPA. 1991. Chemical Assessments and Related Activities (CARA). Office of Health and
Environmental Assessment, Washington, DC. April.
U.S. EPA. 1994. Chemical Assessments and Related Activities (CARA). Office of Health and
Environmental Assessment, Washington, DC. December.
U.S. EPA. 1997. Health Effects Assessment Summary Tables. FY-1997 Update. Prepared by
the Office of Research and Development, National Center for Environmental Assessment,
Cincinnati, OH for the Office of Emergency and Remedial Response, Washington, DC. July.
EPA/540/R-97/036. NTIS PB97-921199.
U.S. EPA. 2003. Integrated Risk Information System (IRIS). Office of Research and
Development, National Center for Environmental Assessment, Washington, DC. Online.
http://www.epa.gov/iris
WHO (World Health Organization). 2002. Online Catalogs for the Environmental Criteria
Series. Online, http://www.who.int/dsa/cat98/zehc.htm
4

-------
01-26-05
Provisional Peer Reviewed Toxicity Values for
Thiocyanates
(Multiple CASRNs)
Derivation of a Carcinogenicity Assessment
Superfund Health Risk Technical Support Center
National Center for Environmental Assessment
Office of Research and Development
U.S. Environmental Protection Agency
Cincinnati, OH 45268

-------
Acronyms
bw - body weight
cc - cubic centimeters
CD - Caesarean Delivered
CERCLA - Comprehensive Environmental Response, Compensation, and Liability Act of 1980
CNS - central nervous system
cu.m - cubic meter
DWEL - Drinking Water Equivalent Level
FEL - frank-effect level
FIFRA - Federal Insecticide, Fungicide, and Rodenticide Act
g - grams
GI - gastrointestinal
HEC - human equivalent concentration
Hgb - hemoglobin
i.m. - intramuscular
i.p. - intraperitoneal
i.v. - intravenous
IRIS - Integrated Risk Information System
IUR - Inhalation Unit Risk
kg - kilogram
L - liter
LEL - lowest-effect level
LOAEL - lowest-observed-adverse-effect level
LOAEL(ADJ) - LOAEL adjusted to continuous exposure duration
LOAEL(HEC) - LOAEL adjusted for dosimetric differences across species to a human
m - meter
MCL - maximum contaminant level
MCLG - maximum contaminant level goal
MF - modifying factor
mg - milligram
mg/kg - milligrams per kilogram
mg/L - milligrams per liter
MRL - minimal risk level
MTD - maximum tolerated dose
MTL - median threshold limit
1

-------
NAAQS - National Ambient Air Quality Standards
NOAEL - no-observed-adverse-effect level
NOAEL(ADJ) - NOAEL adjusted to continuous exposure duration
NOAEL(HEC) - NOAEL adjusted for dosimetric differences across species to a human
NOEL - no-observed-effect level
OSF - Oral Slope Factor
p-RfD - provisional Oral Reference Dose
p-RfC - provisional Inhalation Reference Concentration
p-OSF - provisional Oral Slope Factor
p-IUR - provisional Inhalation Unit Risk
PBPK - physiologically based pharmacokinetic
ppb - parts per billion
ppm - parts per million
PPRTV - Provisional Peer Reviewed Toxicity Value
RBC - red blood cell(s)
RCRA - Resource Conservation and Recovery Act
RGDR - Regional deposited dose ratio (for the indicated lung region)
REL - relative exposure level
RGDR - Regional gas dose ratio (for the indicated lung region)
RfD - Oral Reference Dose
RfC - Inhalation Reference Concentration
s.c. - subcutaneous
SCE - sister chromatid exchange
SDWA - Safe Drinking Water Act
sq.cm. - square centimeters
TSCA - Toxic Substances Control Act
UF - uncertainty factor
ug - microgram
umol - micromoles
VOC - volatile organic compound
SRC TR-03-026/ 05-21-04
11

-------
01-26-05
PROVISIONAL PEER REVIEWED TOXICITY VALUES FOR
THIOCYANATES (Multiple CASRNs)
Derivation of a Carcinogenicity Assessment
Background
On December 5, 2003, the U.S. Environmental Protection Agency's (EPA's) Office of
Superfund Remediation and Technology Innovation (OSRTI) revised its hierarchy of human
health toxicity values for Superfund risk assessments, establishing the following three tiers as the
new hierarchy:
1. EPA's Integrated Risk Information System (IRIS).
2. Provisional Peer-Reviewed Toxicity Values (PPRTV) used in EPA's Superfund
Program.
3. Other (peer-reviewed) toxicity values, including:
~ Minimal Risk Levels produced by the Agency for Toxic Substances and Disease
Registry (ATSDR),
~ California Environmental Protection Agency (CalEPA) values, and
~ EPA Health Effects Assessment Summary Table (HEAST) values.
A PPRTV is defined as a toxicity value derived for use in the Superfund Program when
such a value is not available in EPA's Integrated Risk Information System (IRIS). PPRTVs are
developed according to a Standard Operating Procedure (SOP) and are derived after a review of
the relevant scientific literature using the same methods, sources of data, and Agency guidance
for value derivation generally used by the EPA IRIS Program. All provisional toxicity values
receive internal review by two EPA scientists and external peer review by three independently
selected scientific experts. PPRTVs differ from IRIS values in that PPRTVs do not receive the
multi-program consensus review provided for IRIS values. This is because IRIS values are
generally intended to be used in all EPA programs, while PPRTVs are developed specifically for
the Superfund Program.
Because science and available information evolve, PPRTVs are initially derived with a
three-year life-cycle. However, EPA Regions or the EPA Headquarters Superfund Program
sometimes request that a frequently used PPRTV be reassessed. Once an IRIS value for a
specific chemical becomes available for Agency review, the analogous PPRTV for that same
chemical is retired. It should also be noted that some PPRTV manuscripts conclude that a
PPRTV cannot be derived based on inadequate data.
1

-------
01-26-05
Disclaimers
Users of this document should first check to see if any IRIS values exist for the chemical
of concern before proceeding to use a PPRTV. If no IRIS value is available, staff in the regional
Superfund and RCRA program offices are advised to carefully review the information provided
in this document to ensure that the PPRTVs used are appropriate for the types of exposures and
circumstances at the Superfund site or RCRA facility in question. PPRTVs are periodically
updated; therefore, users should ensure that the values contained in the PPRTV are current at the
time of use.
It is important to remember that a provisional value alone tells very little about the
adverse effects of a chemical or the quality of evidence on which the value is based. Therefore,
users are strongly encouraged to read the entire PPRTV manuscript and understand the strengths
and limitations of the derived provisional values. PPRTVs are developed by the EPA Office of
Research and Development's National Center for Environmental Assessment, Superfund Health
Risk Technical Support Center for OSRTI. Other EPA programs or external parties who may
choose of their own initiative to use these PPRTVs are advised that Superfund resources will not
generally be used to respond to challenges of PPRTVs used in a context outside of the Superfund
Program.
Questions Regarding PPRTVs
Questions regarding the contents of the PPRTVs and their appropriate use (e.g., on
chemicals not covered, or whether chemicals have pending IRIS toxicity values) may be directed
to the EPA Office of Research and Development's National Center for Environmental
Assessment, Superfund Health Risk Technical Support Center (513-569-7300), or OSRTI.
INTRODUCTION
A carcinogenicity assessment for thiocyanates is not available on IRIS (U.S. EPA, 2003),
in the HEAST (U.S. EPA, 1997), or in the Drinking Water Standards and Health Advisories List
(U.S. EPA, 2002). The CARA list (U.S. EPA, 1991, 1994) does not report any relevant
documents for thiocyanates. IARC (2002), ACGIH (2002), and NTP (2002) have not assessed
the carcinogenicity of thiocyanates. ATSDR (2002) and WHO (2002) have not published review
documents for thiocyanates. Literature searches were conducted from 1965 to September, 2002
for the following thiocyanates: sodium thiocyanate (CASRN 540-72-7), potassium thiocyanate
(CASRN 333-20-0), calcium thiocyanate (2092-16-2), ammonia thiocyanate (CASRN 1762-95-
4), and thiocyanic acid (CASRN 463-56-9). The databases searched were TOXLINE,
MEDLINE, CANCERLIT, CCRIS, TSCATS, HSDB, RTECS, GENETOX, DART/ETICBACK,
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and EMIC/EMICBACK. An updated literature search was conducted through April 2004 and no
relevant information was found.
REVIEW OF THE PERTINENT LITERATURE
Human Studies
No studies examining the potential carcinogenic effects of thiocyanates in humans were
located.
Animal Studies
Nagasawa et al. (1980) exposed groups of 18 weanling SHN female mice (a strain with a
high background mammary tumor incidence) to 0, 0.1, or 0.3% potassium thiocyanate in the
drinking water for 12 weeks. Using the allometric equations presented in U.S. EPA (1988) and
mean body weights presented in the manuscript, mean thiocyanate doses were estimated at 0,
153, and 457 mg SCN/kg-day for the 0, 0.1, and 0.3% groups, respectively. No differences
between groups were noted in body weight or body weight gain, estrous cycle pattern, pituitary
or adrenal weight, or ovarian histology. Dose-related decreases in serum T3 (significant in the
0.3% group) and T4 (significant in the 0.1 and 0.3% groups) were reported. Mammary rating as
an index of development was significantly reduced in the 0.3% group. Dose-related decreases in
preneoplastic mammary hyperplastic alveolar nodules and mammary tumor incidence were
reported; these decreases attained statistical significance in the 0.3% animals.
In a second experiment, Nagasawa et al. (1980) exposed groups of 19-22 female GR/A
mice to 0, 0.1, or 0.3% potassium thiocyanate in the drinking water for 5 weeks prior to and for
10 weeks following mating; exposure was discontinued for the 3 days during which mating
occurred. Using the allometric equations presented in U.S. EPA (1988) and mean body weights
presented in the manuscript, mean thiocyanate doses were estimated at 0, 155, and 470 mg
SCN/kg-day for the 0, 0.1, and 0.3% groups, respectively. At the end of exposure, the animals
were sacrificed and examined for the presence of pregnancy-dependent mammary tumors
(PDMT). Treatment with thiocyanate resulted in a significantly decreased number of PDMT
(16/22, 7/20, 5/19 PDMT in the 0, 0.1, and 0.3% groups, respectively). No other examinations
of neoplastic endpoints were reported in the study. No other examinations of the carcinogenic
effects of thiocyantes were located.
Other Studies
Only limited evaluations of the genotoxicity of thiocyanates are available. Yamaguchi
(1980) reported that methyl, ethyl, phenyl, and ammonium thiocyanates were not mutagenic in S.
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typhimurium strain TA100. Kihlman (1957) reported that exposure to thiocyanate did not result
in chromosomal aberrations in the root tip of Vicia faba. Exposure of Tetrahymenapyriformis to
sodium thiocyanate resulted in an increased synthesis of both DNA and RNA (Volm et al.,
1970).
A mechanism that may be related to possible carcinogenesis by the oral route involves
the production of nitrosoamines within the stomach. Thiocyanate, which occurs endogenously in
the stomach (Ruddell et al., 1977), is a potent catalyst of the reaction of nitrite and naturally-
occurring amines to nitrosoamines, which are carcinogenic. However, whether this mechanism
might influence a possible carcinogenic response to exogenous thiocyanate is questionable, as
Mirvish et al. (1975) found that co-exposure of sodium thiocyanate and the combination of
morpholine (a cyclic amine) and sodium nitrite did not result in a significant increase in the
formation of pulmonary adenomas.
PROVISIONAL WEIGHT-OF-EVIDENCE CLASSIFICATION
No carcinogenicity data for thiocyanates are available in humans. Animal data were
limited to one study that found no evidence of a neoplastic or preneoplastic effect of short-term
drinking water exposure to potassium thiocyanate (up to 470 mg SCN/kg-day) in mice
(Nagasawa et al., 1980). Limited genotoxicity data were negative for mutagenicity in bacteria
(Yamaguchi, 1980) and clastogenicity in the root tip of Vicia faba (Kihlman, 1957). Under the
proposed guidelines (U.S. EPA, 1999), data are inadequate for an assessment of the human
carcinogenic potential of thiocyanates.
QUANTITATIVE ESTIMATES OF CARCINOGENIC RISK
Derivation of quantitative estimates of cancer risk for thiocyanates is precluded by the
lack of data demonstrating carcinogenicity associated with thiocyanate exposure.
REFERENCES
ACGIH (American Conference of Governmental Industrial Hygienists). 2002. 2002 Threshold
Limit Values for Chemical Substances and Physical Agents and Biological Exposure Indices.
ACGIH, Cincinnati, OH.
ATSDR (Agency for Toxic Substances and Disease Registry). 2002. Internet HazDat
Toxicological Profile Query. U.S. Department of Health and Human Services, Public Health
Service. Atlanta, GA. Online. http://www.atsdr.cdc.gOv//qsql/toxprof.script
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IARC (International Agency for Research on Cancer). 2002. IARC Agents and Summary
Evaluations. Online. http://193.51.164.il/cgi/iHound/Cheni/iH Chem Frames.html
Kihlman, B.A. 1957. Experimentally induced chromosome aberrations in plants. l.The
production of chromosome aberrations by cyanide and other heavy metal complexing agents. J.
Biophys. Biochem. Cytol. 3: 363-380.
Mirvish, S.S., A. Cardesa, L. Wallcave and P. Schubik. 1975. Induction of mouse lung
adenomas by amines or ureas plus nitrite and by n-nitroso compounds: effect of ascorbate, gallic
acid, thiocyanate, and caffeine. J. Natl. Cancer Inst. 55(3): 633-636.
Nagasawa, H., R. Yanai, Y. Nakajima et al. 1980. Inhibitory effects of potassium thiocyanate
on normal and neoplastic mammary development in female mice. Eur. J. Cancer. 16: 473-480.
NTP (National Toxicology Program). 2002. Management Status Report. Online.
http://ntp-server.niehs.nih.gov/cgi/iH Indexes/Res Stat/iH Res Stat Frames.html
Ruddell, W.S.J., L.M. Blendis and C.L. Walters. 1977. Nitrite and thiocyanate in the fasting
and secreting stomach and in saliva. Gut. 18(1): 73-77.
U.S. EPA. 1988. Recommendations for and Documentation of Biological Values for Use in
Risk Assessment. Environmental Criteria and Assessment Office, Office of Health and
Environmental Assessment. Cincinnati, OH. PB88-17874. EPA/600/6-87/008.
U.S. EPA. 1991. Chemical Assessments and Related Activities (CARA). Office of Health and
Environmental Assessment, Washington, DC. April.
U.S. EPA. 1994. Chemical Assessments and Related Activities (CARA). Office of Health and
Environmental Assessment, Washington, DC. December.
U.S. EPA. 1997. Health Effects Assessment Summary Tables. FY-1997 Update. Prepared by
the Office of Research and Development, National Center for Environmental Assessment,
Cincinnati, OH for the Office of Emergency and Remedial Response, Washington, DC. July.
EPA/540/R-97/036. NTIS PB97-921199.
U.S. EPA. 1999. Guidelines for Carcinogen Risk Assessment. Review Draft. Risk Assessment
Forum, Office of Research and Development, National Center for Environmental Assessment,
Washington, DC. July.
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U.S. EPA. 2002. 2002 Edition of the Drinking Water Standards and Health Advisories. Office
of Water, Washington, DC. EPA 822-R-02-038. Online.
http://www.epa. gov/waterscience/drinking/standards/dwstandards.pdf
U.S. EPA. 2003. Integrated Risk Information System (IRIS). Office of Research and
Development, National Center for Environmental Assessment, Washington, DC. Online.
http://www.epa.gov/iris
Volm, M., K. Wayss and V. Schwartz. 1970. Effect of lithium and thiocyanate ions on the
synthesis of nucleic acids and proteins in Tetrahymena pyriformis GL. Wilhelm Roux' Archie
165:121-131. (Ger.; Eng. abstract)
WHO (World Health Organization). 2002. Online Catalogs for the Environmental Criteria
Series. Online, http://www.who.int/dsa/cat98/zehc.htm
Yamaguchi, T. 1980. Mutagenicity of isothiocyanates, isocyanates, and thioureas on
Salmonella typhimurium. Agric. Biol. Chem. 44(12): 3107-3018.
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