vvEPA
United States
Environmental F^otecoon
Agency
Office of Water
Regulations and Standards
Criteria and Standards Division
Washington DC 20460
October 1980
Ambient
Water Quality
Criteria for
Chromium
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AMBIENT WATER QUALITY CRITERIA FOR
CHROMIUM
Prepared By
U.S. ENVIRONMENTAL PROTECTION AGENCY
Office of Water Regulations and Standards
Criteria and Standards Division
Washington, D.C.
Office of Research and Development
Environmental Criteria and Assessment Office
Cincinnati, Ohio
Carcinogen Assessment Group
Washington, D.C.
Environmental Research Laboratories
Corvalis, Oregon
Duluth, Minnesota
Gulf Breeze, Florida
Narragansett, Rhode Island
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DISCLAIMER
This report has been reviewed by the Environmental Criteria and
Assessment Office, U.S. Environmental Protection Agency, and approved
for publication. Mention of trade names or commercial products does not
constitute endorsement or recommendation for use.
AVAILABILITY NOTICE
This document is available to the public through the National
Technical Information Service, (NTIS), Springfield, Virginia 22161.
11
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FOREWORD
Section 304 (a)(l) of the Clean Water Act of 1977 (P.L. 95-217),
requires the Administrator of the Environmental Protection Agency to
publish criteria for water quality accurately reflecting the latest
scientific knowledge on the kind and extent of all identifiable effects
on health and welfare which may be expected from the presence of
pollutants in any body of water, including ground water. Proposed water
quality criteria for the 65 toxic pollutants listed under section 307
(a)(l) of the Clean Water Act were developed and a notice of their
availability was published for public comment on March 15, 1979 (44 FR
15926), July 25, 1979 (44 FR 43660), and October 1, 1979 (44 FR 56628).
This document is a revision of those proposed criteria based upon a
consideration of comments received from other Federal Agencies, State
agencies, special interest groups, and individual scientists. The
criteria contained in this document replace any previously published EPA
criteria for the 65 pollutants. This criterion document is also
published in satisifaction of paragraph 11 of the Settlement Agreement
in Natural Resources Defense Counci1, et. alI. vs. Train, 8 ERC 2120
(D.D.C. 1976), modified, 12 ERC 1833 (D.D.C. 1979).
The term "water quality criteria" is used in two sections of the
Clean Water Act, section 304 (a)(l) and section 303 (c)(2). The term has
a different program impact in each section. In section 304, the term
represents a non-regulatory, scientific assessment of ecological ef-
fects. The criteria presented in this publication are such scientific
assessments. Such water quality criteria associated with specific
stream uses when adopted as State water quality standards under section
303 become enforceable maximum acceptable levels of a pollutant in
ambient waters. The water quality criteria adopted in the State water
quality standards could have the same numerical limits as the criteria
developed under section 304. However, in many situations States may want
to adjust water quality criteria developed under section 304 to reflect
local environmental conditions and human exposure patterns before
incorporation into water quality standards. It is not until their
adoption as part of the State water quality standards that the criteria
become regulatory.
Guidelines to assist the States in the modification of criteria
presented in this document, in the development of water quality
standards, and in other water-related programs of this Agency, are being
developed by EPA.
STEVEN SCHATZOW
Deputy Assistant Administrator
Office of Water Regulations and Standards
111
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ACKNOWLEDGEMENTS
Aquatic Life Toxicology:
Charles E. Stephan, ERL-Duluth
U.S. Environmental Protection Agency
John H. Gentile, ERL-Narragansett
U.S. Environmental Protection Agency
Mammalian Toxicology and Human Health Effects:
Ernest Foulkes (author)
University of Cincinnati
Michael L. Dourson (doc. mgr.)
ECAO-Cin
U.S. Environmental Protection Agency
Bonnie Smith (doc. mgr.) ECAO-Cin
U.S. Environmental Protection Agency
Christopher T. DeRosa
University of Virginia
Alfred D. Garvin
University of Cincinnati
Charalingayya Hiremath, CAG
U.S. Environmental Protection Agency
Curt Klaassen
University of Kansas Medical Center
Steven D. Lutkenhoff, ECAO-Cin
U.S. Environmental Protection Agency
T.C. Siewicki
National Marine Fisheries Service
Jerry F. Stara, ECAO-Cin
U.S. Environmental Protection Agency
Anna M. Baetjer
Johns Hopkins School of Hygiene
J. Peter Bercz, HERL-Cin
U.S. Environmental Protection Agency
Kirk Biddle
U.S. Food and Drug Administration
Patrick Durkin
Syracuse Research Corp.
Warren S/ Ferguson
Allied Chemical Corp.
Carl L. Giannetta
U.S. Food and Drug Administration
Rolf Hartung
University of Michigan
S. Roy Koirtyohann
University of Missouri
Debdas Mukerjee, ECAO-Cin
U.S. Environmental Protection Agency
Wayne Wolf
U.S. Department of Agriculture
Roy E. Albert, CAG*
U.S. Environmental Protection Agency
Technical Support Services Staff: D.J. Reisman, M.A. Garlough B L Zwayer
P.A. Daunt, K.S. Edwards, T.A. Scandura, A.T. Pressley, C.A. Coooer '
M.M. Denessen. K '
Clerical Staff: C.A. Haynes, S.J. Faehr, L.A. Wade, D. Jones, B.J. Bordicks
B.J. Quesnell, P. Gray, B. Gardiner, R. Swantack.
*CAG Participating Members: Elizabeth L. Anderson, Larry Anderson, Ralph Arnicar,
Steven Bayard, David L. Bayliss, Chao W. Chen, John R. Fowle III, Bernard Haberman,
Charalingayya Hiremath, Chang S. Lao, Robert McGaughy, Jeffrey Rosenblatt,
Dharm V. Singh, and Todd W. Thorslund.
fv
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TABLE OF CONTENTS
Page
Criteria Summary
Introduction A-l
Aquatic Life Toxicology 8-1
Introduction B-l
Effects B-3
Acute Toxicity B-3
Chronic Toxicity B-7
Plant Effects B-9
Residues B-10
Miscellaneous B-I2
Summary B-13
Criteria B-14
References B-45
Mammalian Toxicology and Human Health Effects C-l
Introduction C-l
Exposure C-6
Ingestion from Water and Food C-6
Inhalation C-8
Dermal C-10
Pharmacokinetics C-ll
Absorption, Distribution, Metabolism and Excretion C-ll
Effects C-16
Acute, Subacute, and Chronic Toxicity C-16
Teratogenicity C-21
Mutagenicity C-21
Carcinogenicity C-23
Criterion Formulation C-29
Existing Guidelines and Standards C-29
Current Levels of Exposure C-29
Special Groups at Risk C-31
Basis and Derivation of Criterion C-31
References C-37
Appendix C-47
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CRITERIA DOCUMENT
CHROMIUM
CRITERIA
Aquatic Life
For total recoverable hexavalent chromium the criterion to
protect freshwater aquatic life as derived using the Guidelines is
0.29 ug/1 as a 24-hour average and the concentration should not
exceed 21 ug/1 at any time.
For freshwater aquatic life the concentration (in ug/1) of
total recoverable trivalent chromium should not exceed the numeri-
cal value given by ed-08 [In(hardness) ]+3.48) afc Qny t-me> FQr
example, at hardnesses of 50, 100, and 200 mg/1 as CaC03 the con-
centration of total recoverable trivalent chromium should not ex-
ceed 2,200, 4,700, and 9,900 ug/1, respectively, at any time. The
available data indicate that chronic toxicity to freshwater aquatic
life occurs at concentrations as low as 44 yg/1 and would occur at
lower concentrations among species that are more sensitive than
those tested.
For total recoverable hexavalent chromium the criterion to
protect saltwater aquatic life as derived using the Guidelines is
18 yg/1 as a 24-hour average and the concentration should not ex-
ceed 1,260 ug/1 at any time.
For total recoverable trivalent chromium, the available data
indicate that acute toxicity to saltwater aquatic life occurs at
concentrations as low as 10,300 ug/1, and would occur at lower con-
centrations among species that are more sensitive than those test-
ed. No data are available concerning the chronic toxicitv of tri-
valent chromium to sensitive saltwater aquatic life.
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Human Health
For the protection of human health from the toxic properties
of chromium (III) ingested through water and contaminated aquatic
organisms, the ambient water criterion is determined to be 3&&
mg/1.
For the protection of human health from the toxic properties
of chromium (III) ingested through contaminated aquatic organisms
/ 1.00
alone, the ambient water criterion is determined to be -^/43? mg/1.
The ambient water quality criterion for chromium (VI) is
recommended to be identical to the existing water standard for
total chromium which is 50 yg/1. Analysis of the toxic effects
data resulted in a calculated level which is protective of human
health against the ingestion of contaminated water and contaminated
aquatic organisms. The calculated value is comparable to the pres-
ent standard. For this reason a selective criterion based on expo-
sure solely from consumption of 6.5 grams of aquatic organisms was
not derived.
VII
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INTRODUCTION
Chromium is a metallic element which can exist in several
valence states. However, in the aquatic environment it virtually
is always found in valence states +3 or +6. Hexavalent chromium is
a strong oxidizing agent which reacts readily with reducing agents
such as sulfur dioxide to give trivalent chromium. Cr (III) oxi-
dizes slowly to Cr (VI), the rate increasing with temperature.
Oxidation progresses rapidly when Cr (III) adsorbs to MnO, but is
interfered with by Ca (II) and Mg (n) ions. Thus, accumulation
would probably occur in sediments where chemical equilibria favor
the formation of Cr (III), while Cr (VI), if favored, would presum-
ably dissipate in soluble forms. Hexavalent chromium exists in
solution as a component of an anion, rather than a cation, and
therefore, does not precipitate from alkaline solution. The three
important anions are: hydrochromate, chromate, and dichromate.
The proportion of hexavalent chromium present in each of these
forms depends on pH. In strongly basic and neutral solutions the
chromate form predominates. As pH is lowered, the hydrochromate
concentration increases. At very low pH the dichromate species
predominates. In the pH ranges encountered in natural waters the
proportion of dichromate ions is relatively low. In the acid por-
tion of the environmental range, the predominant form is hydrochro-
mate ion (63.6 percent at pH 6.0 to 6.2) (Trama and Benoit, 1960).
In the alkaline portion of the range, the predominant form is chro-
mate ion (95.7 percent at pH 8.5 to 7.8) (Trama and Benoit, 1960).
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Trivalent chromium in solution forms numerous types of hexa-
coordinate complexes (Cotton and Wilkinson, 1962). The best known
and one of the most stable of these is the amine class (complexes
include aquo- ions, acido- complexes (which are anionic), and poly-
nuclear complexes. Complex formation can prevent precipitation of
the hydrous oxide or other insoluble forms at pH values at which it
would otherwise occur.
Chromium salts are used extensively in the metal finishing
industry as electroplating,- cleaning agents, and as mordants in the
textile industry. They also are used in cooling waters, in the
leather tanning industry, in catalytic manufacture, in pigments and
primer paints, and in fungicides and wood preservatives. Kopp
(1969) reported a mean surface water concentration in the United
States of 9.7 ug/1, based on 1,577 samples. Trivalent chromium is
recognized as a essential trace element for humans. Hexavalent
chromium in the workplace is suspected of being carcinogenic.
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REFERENCES
Cotton, F.A. and G. Wilkinson. 1962. Advanced Inorganic Chemis-
try. Interscience Publishers, John Wiley and Sons, Inc., New York.
Kopp, J.F. 1969. The Occurrence of Trace Elements in Water. In;
D. Hemphill (ed.), Trace Substances in Environmental Health III.
University of Missouri, Columbia, p. 59.
Trama, F.B. and R.J. Benoit. 1960. Toxicity of hexavalent chromi-
um to bluegills. Jour. Water Pollut. Control Fed. 32: 868.
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Aquatic Life Toxicology*
INTRODUCTION
Chromium is a chemically complex metal which occurs in valence states
ranging from -2 to +6. The hexavalent and trivalent chromium compounds are
the biologically and environmentally significant forms of the element, but
they have very different chemical characteristics. Hexavalent chromium is
very soluble in natural water. Although it is a strong oxidizing agent in
acidic solutions, hexavalent chromium is relatively stable in most natural
waters. Trivalent chromium tends to form stable complexes with negatively
charged organic or inorganic species and thus its solubility and toxicity
vary with water quality characteristics such as hardness and alkalinity.
Most of the trivalent chromium species are either cationic or neutral and
the hexavalent species are anionic.
Information on the toxic effects of chromium on freshwater organisms is
relatively extensive, but the data base for hexavalent chromium is greater
than that for trivalent chromium. The data indicate that water hardness has
an insignificant influence on the toxicity of hexavalent chromium in fresh
water; thus, it is not necessary to develop a criterion as a function of
water quality. On the other hand, the freshwater data indicate that water
hardness has a significant influence on the acute toxicity of trivalent
chromium.
Most of the saltwater acute and chronic toxicity data are for hexavalent
chromium. Only a few studies have been conducted on the effects of triva
*The reader is referred to the Guidelines for Deriving Water Quality Crite-
ria for the Protection of Aquatic Life and Its Uses in order to better un-
derstand the following discussion and recommendation. The following tables
contain the appropriate data that were found in the literature, and at the
bottom of each table are calculations for deriving various measures of tox-
icity as described in the Guidelines.
B-l
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lent chromium on saltwater organisms, probably because of the low solubility
of trivalent chromium in saltwater. The kinetics of precipitation of tri-
valent chromium in saltwater systems are complex but regardless of its form,
trivalent chromium may still be ingested and bioconcentrated by filter or
deposit feeding bivalve mollusc and polychaete species.
Of the analytical measurements currently available, water quality crite-
ria for trivalent chromium and for hexavalent chromium are probably best
stated in terms of total recoverable trivalent chromium and total recover-
able hexavalent chromium, respectively, because of the variety of forms of
chromium that can exist in bodies of water and the various chemical and tox-
icological properties of these forms. The forms of chromium that are com-
monly found in bodies of water and are not measured by the total recoverable
procedure, such as the chromium that is a part of minerals, clays, and sand,
probably are forms that are less toxic to aquatic life and probably will not
be converted to the more toxic forms very readily under natural conditions.
On the other hand, forms of chromium that are commonly found in bodies of
water and are measured by the total recoverable procedure, such as the free
ion, and the hydroxide, carbonate, and sulfate salts, probably are forms
that are more toxic to aquatic life or can be converted to the more toxic
forms under natural conditions. Because the criterion is derived on the
basis of tests conducted on soluble inorganic salts of chromium, total chro-
mium and total recoverable chromium concentrations in the tests will prob-
ably be about the same and a variety of analytical procedures will produce
about the same results. Except as noted, all concentrations reported herein
are expected to be essentially equivalent to total recoverable trivalent or
hexavalent chromium concentrations. All concentrations are expressed as
chromium, not as the compound.
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EFFECTS
Acute Toxicity
Hexavalent Chromium
As shown in Table 1, the freshwater data base available for hexava-
lent chromium has numerous acute values for thirteen species from ten dif-
ferent families. Acute values have been reported for six freshwater inver-
tebrate species from five families. These acute values range from 67 ug/1
for a scud to 59,900 yg/1 for a midge. The scud Gammarus pseudolimnaeus was
by far the most sensitive species tested with an LC50 value about one-
fiftieth of the next lower acute value. Invertebrate species are generally
more sensitive to hexavalent chromium than fish species. As shown in Table
3, the species mean acute values for five of the six invertebrate species
are less than that of any fish species. The rotifer Philodina roseola was
about three times as sensitive to chromium at 35°C as at 5*C (Schaffer and
Pipes, 1973).
Table 1 also lists acute values for seven freshwater fish species,
of which more than 70 percent of the values are for the goldfish and fathead
minnow. The 96-hour LC5Q values range from 17,600 pg/1 for the fathead
minnow to 249,000 vg/l for the goldfish. Static tests with unmeasured con-
centrations and flow-through tests with measured concentrations gave similar
results (Pickering, 1980).
Wallen, et al. (1957) studied the toxicity of hexavalent chromium
to mosquitofish in turbid water using potassium and sodium salts of both di-
chromate and chromate (Table 6). Based on chromium, both dichromate salts
were more toxic than the chromate salts. The geometric means of the two
values were 95,000 pg/1 and 120,000 yg/1 for the dichromate and chromate,
respectively. Trama and Benoit (1960) studied the toxicity of chromium to
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the bluegill using potassium dichromate and potassium chromate. The 96-hour
LC5Q values were 110,000 yg/1 for the dichromate salt and 170,000 yg/1 for
the chromate salt. They attributed the lower LC^Q value of the dichromate
salt to its greater acidity, because chromium is slightly more toxic at
lower pH values.
The toxicity of hexavalent chromium to the bluegill in soft and
hard water was tested at 18°C and 30°C (Academy of Natural Sciences of Phil-
adelphia, I960). At 18*C the 96-hour LC5Q values were 113,000 yg/1 in
soft water and 135,000 yg/1 in hard water. Similar results were obtained at
3Q°C with the 96-hour LC50 values being 113,000 yg/1 in soft water and
130,000 yg/1 in hard water.
Pickering and Henderson (1966) tested the toxicity of potassium di-
chromate to the fathead minnow and bluegill in soft and hard water. The
96-hour LCcn values for the fathead minnow in soft and hard water were
17,600 and 27,300 ug/1, respectively. The corresponding values for the
bluegill were 118,000 yg/1 and 133,000 yg/1.
The data from Adelman and Smith (1976) shown in Tables 1 and 6 in-
dicate that the threshold lethal concentration for hexavalent chromium does
not occur within 96 hours. They found that for 16 tests, the average ratio
of 11-day to 96-hour values was 0.37 for the fathead minnow and 0.27 for the
goldfish.
The Freshwater Final Acute Value for hexavalent chromium, derived
from the species mean acute values listed in Table 3 using the calculation
procedures described in the Guidelines, is 21.2 yg/1.
Acute toxicity data for hexavalent chromium and twenty saltwater
fish and invertebrate species have been reported (Table 1). Acute toxicity
values ranged from 2,000 yg/1 for a polychaete worm and mysid shrimp to
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105,000 u9/1 for the mud snail. The I^Q values for fish species range
from 12,400 u9/l for the Atlantic silverside to 91,000 pg/1 for the mummi-
chog. The most sensitive species were the polychaete annelids (2,000-8,000
ug/l), the mysid shrimp (2,000-4,400 pg/1), and two copepods (3,650 and
6,600 pg/1). The LCen values for hexavalent chromium and bivalve molluscs
range from 57,000 ug/l for the soft shell clam to 14,000 u9/l for the brack-
ish water clam. The sensitivity of the latter was salinity dependent with
acute toxicity values of 35,000 ug/l and 14,000 yg/l at salinities of 22
g/kg and 5.5 g/kg, respectively. Adult starfish were insensitive with an
LC50 value of 32,000 ug/l. A Saltwater Final Acute Value of 1,260 u9/l
was obtained for hexavalent chromium using the species mean acute values in
Table 3 and the calculation procedures described in the Guidelines.
Trivalent Chromium
As shown in Table 1, the data base for acute toxicity of trivalent
chromium to freshwater organisms includes 28 values for 19 animal species
from 14 different families. Although the total number of values is smaller,
more species have been tested with trivalent chromium than with hexavalent
chromium.
Thirteen acute values for trivalent chromium have been reported for
eight invertebrate species (Table 1). These values range from 2,000 ug/l
for Daphnia magna and the mayfly to 64,000 u9/l for the caddisfly, all three
of which were determined in soft water. Chapman, et al. (Manuscript) stud-
ied the effects of three levels of water hardness on the toxicity of triva-
lent chromium to Daphnia magna. They reported 48-hour acute values that
ranged from 16,800 u9/l In soft water to 58,700 u9/1 in hard water.
Table 1 also includes data for the acute toxicity of trivalent
chromium to freshwater fish species. Fifteen 96-hour LC50 values have
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been reported for 11 fish species from eight families. These values ranged
from 3,330 pg/1 for the guppy in soft water to 71,900 yg/1 for the bluegill
in hard water. There are comparative data on the influence of water hard-
ness on toxicity for the fathead minnow and the bluegill. The 96-hour
LCc0 values for the fathead minnow tested in soft and hard water are 5,070
and 67,400 yg/1, respectively. The corresponding values for the bluegill
are 7,460 and 71,900 yg/1.
The comparative data from Pickering and Henderson (1966) indicate
that in soft water trivalent was more toxic than hexavalent chromium to four
fish species. In hard water trivalent chromium was less toxic to the fat-
head minnow and more toxic to the bluegill than hexavalent chromium.
An exponential equation was used to describe the observed relation-
ship of the acute toxicity of trivalent chromium to hardness in fresh water.
A least square regression of the natural logarithms of the acute values on
the natural logarithms of hardness produced slopes of 1.64, 0.83, and 0.78,
respectively, for Daphnia magna, fathead minnow, and bluegill (Table 1).
The first two slopes were significant, but the last could not be tested be-
cause only two values were available. The arithmetic mean slope (1.08) was
used with the geometric mean toxicity value and hardness for each species to
obtain a logarithmic intercept for each of the nineteen freshwater species
for which acute values are available for trivalent chromium. The species
mean acute intercept, calculated as the exponential of the logarithmic in-
tercept, was used to compare the relative acute sensitivities (Table 3).
Both the most sensitive and the least sensitive species are invertebrates.
A freshwater final acute intercept of 32.3 yg/1 was obtained for trivalent
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chromium using the species mean acute intercepts listed in Table 3 and the
calculation procedures described in the Guidelines. Thus, the Final Acute
Equation is e(l.<»[ln(hardness)]+3.48).
The few data that are available on the toxicity of trivalent chro-
mium to saltwater species (Table 1) indicate that, probably because of pre-
cipitation, a large amount of trivalent chromium must be added to saltwater
to kill aquatic organisms.
Chronic Toxicity
Hexavalent Chromium
The chronic data base for hexavalent chromium and freshwater spe-
cies (Table 2) contains data for three fish species. Benoit (1976) studied
the effects of hexavalent chromium in the chronic tests with brook trout and
rainbow trout. The limits of 200 and 350 yg/l, with a chronic value of 265
vg/1, were established on the basis of survival for both species. Growth in
weight during the first eight months was retarded at all test concentra-
tions. However, this was a temporary effect on growth and was not used to
establish the chronic limits.
Sauter, et al. (1976) also used the rainbow trout in a chronic
study. The limits for this early life stage exposure were 51 and 105 ug/l
with a chronic value of 73 ug/1. These values were established on the basis
of a reduction of growth after 60 days post-hatch exposure. This chronic
value of 73 ug/1 was about one-fourth of the chronic value of 265 vg/1 from
the chronic test reported by Benoit (1976).
The acute-chronic ratios for brook trout and rainbow trout, calcu-
lated from the data of Benoit (1976) are 220 and 260, respectively (Table
2). Sauter, et al. (1976) provided no acute data in their study with which
to ca?cufate acute-chronic ratios.
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The limits of 1,000 and 3,950 yg/1 in a life-cycle test with the
fathead minnow (Pickering, 1980) were based on survival. In this exposure
also an early retardation of growth was only temporary. The chronic value
of 1,990 u9/1 is much higher than that for the trout but the acute-chronic
ratio of 19 is much lower.
No chronic values are available for hexavalent chromium with any
freshwater invertebrate species.
Results of life-cycle studies with the saltwater polychaete, Nean-
thes arenaceodentata, and the mysid shrimp Mysidopsis bahia are reported in
Table 2. Other life cycle data on the polychaetes, Capitella capitata and
Ophryotrocha "diadema, (Table 6) were not included here because exposure con-
centrations were not adequately defined. Hexavalent chromium was chronical-
ly toxic to the polychaete at 25 ug/1 and to the mysid at 132 ug/1 and both
of these species were among the most acutely saensitive to hexavalent chro-
mium (Table 1). The acute-chronic ratios were 120 for the polychaete and 15
for the mysid. These ratios, while quite different, are consistent with
those for freshwater fish species.
The geometric mean of the five acute-chronic ratios for three
freshwater fish species and two saltwater invertebrate species is 72. The
Freshwater Final Acute Value of 21.2 yg/1 divided by the acute-chronic ratio
of 72 results in a Freshwater Final Chronic Value for hexavalent chromium of
0.29 yg/1. Similarly, the Saltwater Final Chronic Value for hexavalent
chromium is 17.5 vg/1.
Trivalent Chromium
The freshwater chronic data base for trivalent chromium (Table 2)
contains data for a life-cycle test with Daphnia magna in soft water and a
life-cycle test with the fathead minnow in hard water. In hard water the
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chronic value of 1,020 vg/1 for the fathead minnow is greater than the
chronic value of 66 yg/1 for Oaphnia magna. Trivalent chromium appeared to
be more toxic to Daphnia magna in hard water than in soft water. The
chronic value in soft water was 66 ug/1 (Table 2), but in hard water the
lowest tested concentration (44 ug/1) inhibited reproduction (Table 6).
Chapman, et al. (Manuscript) speculated that ingested precipitated chromium
contributed to the toxicity in hard water. Biesinger and Christensen (1972)
also conducted a life-cycle test with Daphnia magna but the test concentra-
tions were not measured; the data are included in Table 6. The acute-
chronic ratio is 27 for the fish and 250 for Daphnia magna.
No data on the chronic effects of trivalent chromium on saltwater
species are available.
Plant Effects
Hexavalent Chromium
The data for four species of freshwater algae and Eurasian water-
milfoil (Table 4) indicate that algae are sensitive to hexavalent chromium.
The effect concentrations of chromium range from 10 pg/1 for reduction in
growth of a green alga to 1,900 ug/1 for root weight inhibition of Eurasian
watermilfoil. Growth of the green alga, Chlamydomonas reinhardi, was re-
duced at a concentration of 10 ug/1 in BOLD's basal medium.
Toxicity of hexavalent chromium to the diatom, Navicula seminulum,
was tested at three temperatures in both soft and hard waters (Academy of
Natural Sciences of Philadelphia, 1960). The geometric mean of the concen-
trations causing a 50 percent reduction in growth was 245 yg/l in soft
waters and 335 wg/1 in hard water. The diatom was more sensitive to chromi-
um at 22°C than at 30*C.
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The data indicate that green algae are quite sensitive to hexava-
lent chromium. However, chromium concentrations were not measured in any of
the exposures listed in Table 4, so a Freshwater Final Plant Value is not
available for hexavalent chromium.
Toxicity studies were performed with the saltwater macroalga, Ma-
crocystis pyrifera, to investigate the effect of hexavalent chromium on pho-
tosynthesis (Table 4). The 96-hour EC^Q reported by Clendenning and North
(1959) was 5,000 ug/1, whereas 20 percent inhibition was noted after five
days at 1,000 ug/1 (Bernhard and Zattera, 1975). These data indicate that
the plants were among the most sensitive species to chromium. Again, be-
cause no chromium concentrations were measured, no Saltwater Final Plant
Value can be stated.
Trivalent Chromium
Toxicity data are available for only one freshwater plant species
(Table 4). Root weight was inhibited at a trivalent chromium concentration
of 9,900 u9/1 (Stanley, 1974). Exposure concentrations were not measured,
so a Freshwater Final Plant Value for trivalent chromium is not available.
No saltwater plant species have been tested with trivalent chromium.
Residues
Hexavalent Chromium
Data are available from two studies with the rainbow trout and hex-
avalent chromium, and the bioconcentration factor is about one (Table 5).
Data on bioconcentration of hexavalent chromium and saltwater species is
limited to one polychaete species and the oyster and blue mussel (Table 4).
The bioconcentration factors are in the range of 125 to 200.
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Trivalent Chromium
Data are not available concerning the bioconcentration of trivalent
chromium by freshwater organisms.
Uptake of trivalent chromium by the blue mussel, soft shell clam,
and oyster has been studied and the bioconcentration factors range from 86
to 153 (Table 5). These results are similar to those for hexavalent
chromium.
Miscellaneous
Hexavalent Chromium
Table 6 includes data for other effects on freshwater species that
were not included in the first five tables. The data base for hexavalent
chromium is more extensive than that for trivalent chromium.
The data in this table indicate that Daphnia magna is a very sensi-
tive species. Debalka (1975) reported 72-hour ECc0 values that ranged
from 31 to 81 ug/1. In addition, Trabalka and Gehrs (1977) studied the
chronic toxicity of hexavalent chromium to Daphnia magna. They found a sig-
nificant effect on both life span and fecundity at all test concentrations
including the lowest of 10 yg/1. Because a lower limit was not obtained,
this datum is included in Table 6 instead of Table 2. This value certainly
supports the Final Chronic Value.
Algae also appear to be sensitive to chromium. Zarafonetis and
Hampton (1974) reported inhibition of photosynthesis of a natural population
of river algae exposed to 20 ug/1.
Data in Table 6 also indicate that low concentrations of hexavalent
chromium have a deleterious effect on the growth of fishes. Olson and
Foster (1956) reported a statistically significant effect on growth of chi-
nook salmon at 16 ug/1 and on rainbow trout at 21 ug/1. At these concentra-
B-ll
-------�
tions, growth in weight was reduced about ten percent. As noted earlier,
Benoit (1976) and Pickering (1980) also reported effects on growth of fishes
exposed to low concentrations. However, in these life-cycle tests the ef-
fect was temporary and was not used to establish chronic limits.
Chronic mortality of the saltwater polychaete, Neanthes arenaceo-
dentata, resulted in 59-day EC^Q value for hexavalent chromium of 200 pg/1
compared to the 96-hour LC^g of 3,100 ug/1 and the chronic value of 25
ug/1. Sublethal effects reported for this species show inhibition of tube
building at 79 yg/1.
Holland, et al. (1960) reported toxicity to silver salmon at a con-
centration of 31,800 yg/1 which is similar to the species mean acute values
(Table 1) reported for the speckled sanddab (30,500) but twice as high as
that reported for the Atlantic silverside (15,000).
The effect of salinity and temperature on hexavalent chromium toxi-
city to grass shrimp is reported by Fales (1978). At fixed salinities of 10
and 20 g/kg toxicity increased with increasing temperature between 10 to
25*C. At fixed temperatures toxicity decreased with increasing salinity
from 10 to 20 g/kg.
Trivalent Chromium
Embryos of a freshwater snail are rather insensitive to trivalent
chromium (Table 6).
Mearns, et al. (1976) were able to kill a saltwater polychaete worm
with trivalent chromium by adding 50,400 ug/1, probably because the pH
dropped to 4.5 due to the extensive precipitation. When the pH was raised
to about 7.9 by adding sodium hydroxide, the worms not only survived for at
least 160 days, but also reproduced (Table 6).
B-12
-------�
Summary
Hexavalent Chromium
Acute data for hexavalent chromium are available for thirteen
freshwater animal species from ten different families which include a wide
variety of animals that perform a spectrum of ecological functions. Data
indicate that water hardness has an insignificant influence on toxicity.
Most invertebrate species are more sensitive than most fish, and a scud is
the most acutely sensitive species.
Long-term tests with brook trout and rainbow trout both gave
chronic values of 265 yg/1 which are much lower than the chronic value of
1,990 pg/1 for the fathead minnow. No chronic values are available for
freshwater invertebrate species.
The data for freshwater plants indicate that green algae are sensi-
tive to hexavalent chromium and the bioconcentration factor for rainbow
trout is about one.
Other data reveal more sensitive effects. The growth of chinook
salmon was reduced at a measured concentration of 16 yg/1. In chronic tests
with brook trout, rainbow trout, and fathead minnows a temporary adverse
affect on growth occurred at low concentrations. In a life-cycle test with
Daphnia magna the lowest test concentration of 10 yg/1 reduced life span and
fecundity.
The acute toxicity of hexavalent chromium to twenty saltwater ver-
tebrate and invertebrate species ranges from 2,000 ug/1 for polychaete an-
nelids and a mysid shrimp, to 105,000 yg/1 for the mud snail. Polychaetes
and microcrustaceans are the most acutely sensitive taxa. The chronic
values for polychaetes and a mysid shrimp are 25 and 132 yg/1, respectively,
and the acute-chronic ratios are 120 and 15, respectively. Toxicity to
macroalgae was reported at 1,000 and 5,000 yg/1.
B-13
-------�
Data for bioconcentration factors for hexavalent chromium range
from 125 to 200 for bivalves and polychaetes.
Trivalent Chromium
Acute data for trivalent chromium are available for 19 freshwater
animal species from 14 different families. The data indicate that water
hardness has a significant influence on toxicity, with trivalent chromium
being more toxic in soft water. In soft water the sensitivity of fish and
invertebrate species is comparable.
One life-cycle test with Daphnia magna in soft water gave a chronic
value of 66 vg/1, but another gave a chronic value of 445 u9/l. In a
chronic test in hard water the lowest test concentration of 44 yg/1 in-
hibited reproduction of Daphnia magna, but this effect may have been due to
ingested precipitated chromium. In a life-cycle test with the fathead
minnow in hard water the chronic value was 1,020 ug/1. Toxicity data are
available for only one freshwater plant species. A concentraton of 9,900
ug/1 inhibited growth of roots of Eurasian watermilfoil. No bioconcentra-
tion factors are available for trivalent chromium and freshwater organisms.
The available acute values for trivalent chromium in saltwater are
both above 10,000 yg/1, probably because trivalent chromium has a low solu-
bility in saltwater. Bioconcentration factors for saltwater organisms and
trivalent chromium range from 86 to 153. This is similar to the bioconcen-
tration factors for hexavalent chromium and saltwater species.
CRITERIA
For total recoverable hexavalent chromium the criterion to protect
freshwater aquatic life as derived using the Guidelines is 0.29 ug/1 as a
24-hour average and the concentration should not exceed 21 ug/1 at any time.
B-14
-------�
For freshwater aauatic life the concentration (in yg/1) of total re-
coverable trivalent chromium should not exceed the numerical value given by
e(1.08[ln(hardness)]+3.48) at any time< For examplej at hardnesses of 50,
100, and 200 mg/1 as CaCO^ the concentration of total recoverable triva-
lent chromium should not exceed 2,200, 4,700, and 9,900 ug/1, respectively,
at any time. The available data indicate that chronic toxicity to fresh-
water aquatic life occurs at concentrations as low as 44 yg/l and would
occur at lower concentrations among species that are more sensitive than
those tested.
For total recoverable hexavalent chromium the criterion to protect salt-
water aquatic life as derived using the Guidelines is 18 ug/1 as a 24-hour
average and the concentration should not exceed 1,260 pg/1 at any time.
For total recoverable trivalent chromium, the available data indicate
that acute toxicity to saltwater aquatic life occurs at concentrations as
low as 10,300 yg/1, and would occur at lower concentrations among species
that are more sensitive than those tested. No data are available concerning
the chronic toxicity of trivalent chromium to sensitive saltwater aquatic
life.
B-15
-------�
Tab Ia 1. Acute values for chromium
Species
Method*
Chemical
Hardness
(mg/l as LC50/EC50"
CaCO,) (ug/l)
Species Mean
Acute Value'*
(ug/l) Reference
Hexavalent Chromium
FRESHWATER SPECIES
Rotifer.
Ph Medina acutlcornls
Rotifer,
Phi 1 od i na acut 1 corn 1 s
Rotifer,
Phi lodlna roseola
Rotifer,
Ph i 1 od 1 na roseo 1 a
Rotifer,
Phi lodlna roseola
Rotifer,
Phi lodlna roseola
Rotifer,
Phi lodlna roseola
Snai 1,
Physa heterostropha
Snail,
Physa heterostropha
Snail,
Physa heterostropha
Snal 1,
Physa heterostropha
Cladoceran,
Daphnla magna
Scud,
Gammarus pseudol imnaeus
s.
s,
s,
s.
s.
s,
s,
s.
s.
s.
s.
s.
FT,
U
U
M
M
M
M
M
U
U
U
U
U
M
Potassium
d 1 chromate
Potassium
dl chromate
Sodium
chromate
Sod i Dm
chromate
Sodium
chromate
Sod 1 urn
chromate
Sod I um
chromate
Potassium
chromate
Potassium
chromate
Potassium
chromate
Potassium
chromate
Potassium
d 1 chromate
Potassium
chromate
25 3, 100
81 15,000
12,000
8,900
7,400
5,500
4,400
45 17,300
45 17,300
171 40,600
171 31,600
6,400
45 67
Bulkema,
6,800 Bulkema,
Schaffer
1973
Schaffer
1973
Schaf for
1973
Schaf f er
1973
7,200 Schaffer
1973
Academy
1960
Academy
1960
Academy
1960
25,000 Academy
1960
6,400 Oowden &
1965
67 U.S. EPA
et al. 1974
et al. 1974
& Pipes,
4 Pipes,
& Pipes,
& Pipes,
& Pipes,
of Sciences,
of Sciences,
of Sciences,
of Sciences,
Bennett,
, 1980 a
B-16
-------�
Table 1. (Continued)
Hardness
(mg/l as
Species Method* Chemical CaCOQ
Midge, FT, M Potassium 44
Tanytarsus dlsslml I Is chromate
Rainbow trout, FT, M Sodium 45
Sal mo galrdnerl d I chromate
Brook trout, FT, M Sodium 45
Salvellnus fontlnalls d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chr ornate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus dlchromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish, FT, M Potassium 220
Carasslus auratus d I chromate
Goldfish. FT, M Potassium 220
Carasslus auratus d I chr ornate
Goldfish. FT, M Potassium 220
Carasslus auratus dlchromate
Species Mean
LC50/EC50" Acute Value"
(ug/l) (yg/l) Reference
59,900
69,000
59,000
123.000
123,000
90,000
125,000
109,000
135,000
110.000
129,000
98,000
133,000
102,000
59,900 U.S. EPA, 1980a
69,000 Benolt, 1976
59,000 Benolt, 1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
Adelman
1976
& Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
4 Smith,
B-17
-------�
Table 1. (Continued)
Species
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Goldfish,
Carasslus auratus
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Piroephales promelas
Fathead minnow,
Piroephales promelas
Method*
FT,
FT,
FT,
FT,
FT,
FT,
s,
s.
FT,
FT,
FT,
FT,
FT,
FT,
M
M
M
M
H
M
U
U
H
M
M
M
M
M
Chew leal
Potassium
dlchromate
Potassium
dlchromate
Potassium
dlchromate
Potassium
dichromate
Potassium
dlchromate
Potass turn
dlchromate
Sodium
dlchromate
Potassium
dlchromate
Potassium
d 1 chromate
Potassium
dlchromate
Potassium
d 1 chroma te
Potassium
dlchromate
Potassium
dlchromate
Potass 1 urn
d I chromate
Hardness
(«g/l as
CoCO,)
220
220
220
220
220
220
100
20
220
220
220
220
220
220
LC50/EC50»»
(ug/l)
133,
126,
126,
133,
126.
124,
249,
37,
56,
51.
53,
49,
48,
60.
000
000
000
000
000
000
000
500
000
000
000
000
000
000
Species Mean
Acute Value**
(ug/l) Reference
Adelman & Smith,
1976
Adelman & Smith,
1976
Adelman & Smith,
1976
Adelman & Smith,
1976
Adelman & Smith,
1976
Adelman & Smith,
1976
Dowden & Bennett,
1965
120,000 Pickering 4
Henderson, 1966
Adelman & Smith,
1976
Ade (man
1976
Ade Iman
1976
Adelman
1976
Ade Iman
1976
Adelman
1976
&
&
&
&
4
Smith,
Smith,
Smith,
Smith,
Smith,
B-18
-------�
Table 1. (Continued)
Species
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Pimephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Pimephales promelas
Method*
FT,
FT,
FT,
FT,
FT,
FT,
FT,
FT,
FT,
FT,
FT,
FT,
s.
s.
M
M
M
M
M
M
M
M
M
M
M
M
U
U
Chemical
Potassium
di chroma te
Potassium
dichr ornate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Sodium
dichromate
Potassium
dichromate
Potassium
d 1 chroma te
Hardness
(mg/l as
CaC03)
220
220
220
220
220
220
220
220
220
220
220
235
209
208
Species Mean
LC50/EC50«» Acute Value"
(vg/l) (ug/D Reference
50,000
53.
49,
37.
66,
55,
38.
34.
29,
34,
26.
33.
39,
32.
000
000
000
000
000
000
000
000
000
000
200
700
700
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
Ade Iman
1976
&
&
&
&
&
&
&
&
&
&
&
Broderlus
1979
Pickering
Pickering
Smith,
Smith,
Smith,
Smith,
Smith,
Smith,
Smith,
Smith,
Sm.ith,
Smith,
Smith,
4 Smith,
, 1980
, 1980
B-19
-------�
Tab I* I. (Continued)
Spectat
•J— • • i
Fathead minnow.
Pliaephales promelas
Fathead minnow.
Plmephales promelas
Fathead Minnow,
Plmephales promelas
Fathead minnow.
Plmephales promelas
Fathead minnow.
Plmephales promelas
Fathead minnow.
Plmephales promelas
Fathead minnow.
Plmephales promelas
Fathead minnow.
Plmephales promelas
Guppy,
Poecllla retlculata
Striped bass.
Moron e saxatflls
Striped bass.
Morons saxatl 1 Is
Blueglll,
Lepomls macrochlrus
Blueglll,
Lepomls macrochlrus
Method*
FT.
FT,
FT,
s.
s.
s.
FT.
FT,
s.
s.
s.
s.
s.
M
M
M
U
U
U
M
M
U
U
U
U
U
Chemical
Potassium
dlchromate
Potassium
dl chroma te
Potassium
dlchr ornate
Potassium
dl chroma te
Potassium
dlchr ornate
Potassium
chromate
-
_
Potassium
dlchromate
Potassium
di chromate
Potassium
d 1 chromate
Potassium
dlchromate
Potassium
dlchromate
Hardness
(mg/l as
CaCOx)
209
209
209
20
360
20
-
_
20
35
35
20
360
IC50/EC50"
(liq/0
37,700
37,000
35,900
17,600
27,300
45,600
52,000
37,000
30,000
35,000
26,500
118,000
133,000
Species Mean
Acute Value"
(ug/l) Reference
Pickering, 1980
Pickering, I960
Pickering, I960
Pickering &
Henderson, 1966
Pickering &
Henderson, 1966
Pickering &
Henderson, 1966
Rues ink & Smith.
1975
43,100 Rues Ink A Smith,
1975
30,000 Pickering &
Henderson, 1966
Hughes, 1971
30,400 Hughes, 1971
Pickering &
Henderson, 1966
Pickering &
Henderson, 1966
B-20
-------�
Table 1. (Continued)
Species
Blueglll,
Lepomls macrochlrus
BIueg11 I,
Lepomls macrochlrus
Blueglll,
Lepomls macrochlrus
Blueglll.
Lepomls reacrochlrus
Blueglll,
Lepomls macrochlrus
Blueglll,
Lepomls macrochlrus
Blueglll,
Lepomls macrochlrus
Method*
S. U
s, u
s. a
s, u
s, u
s, u
s, u
Chemical
Potassium
bichromate
Potassium
chromate
Sodium
dIchromate
Potassium
dIchromate
Potassium
d I chromate
Potassium
dlchromate
Potassium
d Ichromate
Hardness
(mg/l as
CaCOj)
45
45
120
44
44
171
171
Species Mean
LC50/EC50" Acute Value"
(ug/l) (ug/l) Reference
110,000
170,000
213,000
113,000
113,000
135,000
130,000
134,000
Trama & Benolt, 1960
Trama & Benolt, 1960
TurnbuU, et al.
1954
Academy of Sciences,
I960
Academy of Sciences,
1960
Academy of Sciences,
1960
Academy of Sciences,
1960
SALTWATER SPECIES
Polychaete worm (larva), S, U
Capltella capltata
Polychaete worm (adult), S, U
Capltella capltata
Polychaete worm, S, U
CtenodrlI us serratus
Polychaete worm, S, M
Neanthes arenaceodentata
Polychaete worm, S, U
Nereis vlrens
Chromium
trloxlde
Chromium
tr I oxide
Chromium
trI ox Ide
Potassium
d Ichromate
Potassium
chromate
8,000
5,000
4,300
3,100
2,000
Relsh, et a I. 1976
6,300 Relsh, et al. 1976
4,300 Relsh & Carr, 1978
3,100 Mearns, et al. 1976
2,000 Elsler & Hennekey,
1977
B-21
-------�
Table I. (Continued)
Spec Us Method*
Polychaete worm, S, U
Ophryotrocha dladema
Soft shell clam, S, U
My a arenarfa
Brackish water clam, S, U
Rang la cuneata
Brackish water clam, S, U
Rang la cuneata
Mud snail, S, U
Nassarlus obsoletus
Copepod, S, U
Acartla clausl
Copepod, S, U
Pseudodiaptomus coronatus
Copepod, S, U
Tlqropus Japonlcus
Mysld shrimp, S, M
Mysldopsls bah la
Mysld shrimp, S, M
Mysldopsls blgelowl
Blue crab, S, U
Callinectes sapldus
Blue crab, S, U
Callinectes sapldus
Hermit crab, S, U
Pagurus long (carpus
Hardness
(•9/1 as
Chemical CaCOO
Chromium
tr 1 ox I de
Potassium
chr ornate
Potassium
dl chr ornate
Potassium
dl chroma te
Potassium
chr ornate
Potassium
dl chr ornate
Potassium -
dlchromate
Potassium
dlchromate
Potassium
dlchromate
Potassium
dl chr ornate
Potassium
dlchromate
Potass 1 urn
dl chroma te
Potassium
chr ornate
Species Mean
LC50/EC50" Acute Value"
(l»3/ 1 ) ("9/ 1 ) Reference
7,500 7,500 Relsh & Carr, 1978
57,000 57,000 Elsler & Hennekey,
1977
14,000 - Olson A Harrel, 1973
35,000 22,000 Olson & Harrel , 1973
105,000 105,000 Elsler & Hennekey,
1977
6,600 6,600 U.S. EPA, I980b
3,650 3,650 U.S. EPA, 1980b
17,200 17,200 U.S. EPA, 1980b
2,000 2,000 U.S. EPA, I980b
4,400 4,400 U.S. EPA, 1980b
89,000 - Frank 4 Robertson,
1979
98,000 93,000 Frank & Robertson,
1979
10,000 10,000 Elsler & Hennekey,
1977
B-22
-------�
Table 1. (Continued)
Species Method"
Starfish, S. U
Aster las forbesl
Mummichog, S, U
Fundulus heteroclltus
Atlantic si Iverslde S, U
(larva),
Menldla menidla
Atlantic si Iverslde S, U
( larva),
Menldla menldla
Atlantic si Iverslde S, U
(juvenl le),
Menldia menldla
Speckled sanddab, S, U
Cltharlchthys stlgmaeus
Speckled sanddab, S, U
Cltharlchthys stlgmaeus
Annel Id, S, M
Nals sp.
Snal 1, S, M
Amnfcola sp.
Cladoceran, S, U
Daphnla magna
Cladoceran, S, M
Daphnla magna
Hardness
(ng/l as
Chemical CaC03)
Potassium
chromate
Potassium
chromate
Potassium
dl chromate
Potassium
dl chromate
Potassium
dl chromate
Potassium
di chromate
Potassium
d 1 chromate
Trivalent Chromium
FRESHWATER SPECIES
50
50
Chromic 48
nitrate
Chromic 52
nitrate
LC50/EC50""
(ug/l)
32,000
91,000
12,400
14,300
20,100
31,000
30,000
9,300
8,400
2,000
16,800
Species Mean
Acute Value""
(uq/D Reference
32,000 Elsler & Hannekey,
1977
91,000 Elsler & Hannekey,
1977
U.S. EPA, 1980b
U.S. EPA, 1980b
15,000 U.S. EPA, 1980b
Sherwood, 1975
30,500 Mearns, et al. 1976
Rehwoldt, et al.
1973
Rehwoldt, et al.
1973
Bieslnger &
Chrlstensen, 1972
Chapman, et al.
Manuscript
B-23
-------�
Table 1. (Continued)
Species
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Scud,
Gammarus sp.
Mayfly,
Ephemerella subvarla
Damsel f ly,
Un 1 dent 1 f 1 ed
Caddlsf ly,
Hydropsyche bettenl
Caddlsf ly.
Unidentified
American eel,
Angui 1 la rostrata
Rainbow trout.
Sal mo galrdnerl
Rainbow trout.
Sal mo galrdnerl
Goldfish,
Carasslus auratus
Carp,
Cyprlnus carplo
Method*
s.
s.
s.
s.
s.
s,
s.
s,
s.
s.
s,
FT,
s.
s.
M
M
M
M
M
U
M
U
M
M
U
M
U
M
Hardness
(rog/l as
Chemical CaCO*)
Chromic 99
nitrate
Chromic 110
nitrate
Chromic 195
nitrate
Chromic 215
nitrate
50
Chromic 44
chloride
50
Chromic 44
chloride
50
55
Chromic
n 1 trate
Chromium 20
potassium sul fate
55
LC50/EC50**
(uq/l)
27,400
26,300
51,400
58,700
3,200
2,000
43, 100
64,000
50,000
16,900
11,200
24,100
4,100
14,300
Species Mean
Acute Value**
(ug/l) Reference
Chapman, et al.
Manuscript
Chapman, et al.
Manuscript
Chapman, et al.
Manuscript
Chapman, et al.
Manuscript
Rehwoldt, et al.
1973
Warnlck & Bel 1 ,
1969
Rehwoldt, et al.
1973
Warnlck & Bel 1 ,
1969
Rehwoldt, et al.
1973
Rehwoldt, et al.
1972
Bills, et al. 1977
Hale, 1977
Pickering &
Henderson, 1966
Rehwoldt, et al.
1972
B-24
-------�
Tab|e |. (Continued)
Species
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Fathead minnow,
Plmephales promelas
Banded killlflsh,
Fundulus dlaphanus
Guppy,
Poecllla retlculata
White perch,
Morone amerlcana
Striped bass,
Morone saxat Ills
Pumpkin seed,
Lepomls glbbosus
Bluegill,
Lepomis macrochirus
B 1 uog III,
Lepomls macrochirus
American oyster,
Crassostrea virgin lea
Crab (zoea),
Sesarma haematochelr
Hardness
(mg/l as
Method* Chemical CaCOxL
FT, M Chromium
potassium sultate
FT, M Chromium
potassium sulfate
S, U Chromium
potassium sulfate
S, U Chromium
potassium sulfate
S. M
S, U Chromium
potassium sutfate
S, M
S, M
S, M
S, U Chromium
potassium sulfate
S, U Chromium
potassium su (fate
SALTWATER
S, U Chromium
chloride
S, U Chromium
ch loride
203
203
20
360
55
20
55
55
55
20
360
SPECIES
-
LC50/EC50»«
-------�
Table 1. (Continued)
* S = static, FT = flow-through, U = unmeasured, M = measured
** Results are expressed as chromium, not as the compound.
Trlvalent chromium - freshwater
Acute toxic Ity vs. hardness
Daphnla magna: slope = 1.64, Intercept = 2.36, r » 0.84, p = 0.05, N = 6
Fathead minnow: slope = 0.83, Intercept = 5.98, r = 0.98, p = 0.05, N = 4
Blueglll: slope = 0.78, Intercept = 6.57, r = 1.0, N = 2
Arithmetic mean acute slope = 1.08
B-26
-------�
Table 2. Chronic values for chromium
Species Test*
Rainbow trout, ELS
Sal mo galrdneri
Rainbow trout, ELS
Sal mo galrdneri
Brook trout, LC
Salve) inus fontlnalls
Fathead minnow, LC
Plmephales promelas
Polychaete worm, LC
Neanthes arenaceodentata
Mysld shrimp, LC
Hysldopsls bah la
Cladoceran, LC
Daphnla maqna
Fathead minnow, LC
Plmephales promelas
Hardness Chronic
(mg/l as Limits Value
Chemical CaCO,)
-------�
Table 2. (Continued)
Acute-Chronic Ratio
Species
Acute
Value
(ug/l)
Chronic
Value
(ug/l)
Ratio
Hexavalent Chromium
Rainbow trout.
Sal mo galrdnerl
Brook trout.
Salvellnus fontlnalls
Fathead minnow,
Plmephales promelas
Polychaete worm.
69,000
59,000
37,000
3,100
265
265
1,990
25
260
220
19
120
Neanthes arenaceodentata
Mysld shrimp.
Mysldopsls bah la
2,033
132
15
Trlvalent Chromium
Cladoceran,
Daphnla tnaqna
Fathead minnow.
Plmephales promelas
16,800
28,000
66
1,020
250
27
B-28
-------�
Table 3. Species wean acute values and Intercepts and acute-chronic ratios for chroalu*
mk«
14
13
12
It
10
9
8
7
6
5
4
3
Species
Hexava 1 ent
FRESHWATER
Largemouth bass,
Mlcropterus sal mo Ides
Blueglll.
Lepomis macrochlrus
Goldfish.
Carasslus auratus
Rainbow trout,
Salao galrdneri
Midge,
Tany tarsus disslmllls
Brook trout,
Salvelinus fontlnalls
Fathead minnow,
Plmephales promelas
Striped bass,
Horone saxat Ills
Goppy,
Poecllia retlculata
Snail,
Physa heterostropha
Rotifer,
Phllodlna roseola
Cladoceran,
Dapttnla magna
Species Mean
Acute Value
(|>9/l>
Chromium
SPECIES
195,000
134,000
120.000
69,000
99,900
59,000
43,100
30,400
30,000
25,000
6.800
6,400
Species Mean
Acute-Chronic
Ratio
260
220
19
B-29
-------�
Table 3. (Continued)
Rank*
2
1
19
18
17
16
15
14
13
12
11
10
9
8
Species
Rotifer,
Phllodlna acutlcornls
Scud,
Gammarus pseudol Imnaeus
SALTWATER
Mud sna 1 1 ,
Nassarlus obsoletus
Blue crab,
Calllnectes sapldus
Munimlchog,
Fundu 1 us heteroc 1 1 tus
Soft she! 1 clam,
Mya arenarla
Starfish,
Aster las forbesl
Speck led sand dab,
Clthar ichthys stlgmaeus
Brackish water clam.
Rang I a cuneata
Copepod ,
Tlgrlopus japonlcus
Atlantic si Iverslde,
Men Id la menldla
Hermit crab,
Pagurus long 1 carpus
Polychaete worm,
Ophryotrocha diadema
Copepod,
Acartla clausl
Species Mean
Acute Value
ivo/n
3,100
67
SPECIES
J05.000
93,000
91,000
57,000
32,000
30,500
22,000
17,200
15,000
10,000
7,500
6,600
Species Mean
Acute-Chronic
Ratio
-
B-30
-------�
Table 3. (Continued)
Rank"
7
6
5
4
3
2
1
Rank*
18
17
16
15
Species
Polychaete worm.
Cap 1 te 1 1 a cap I tata
Mysld shrimp,
Mysldopsls blqelowl
Polychaete worm,
Ctenodrllus serratus
Copepod,
Pseudodlaptomus coranatus
Polychaete worm,
Neanthes arenaceodentata
Mysld shrimp,
Mysldopsls bah la
Polychaete worm.
Nereis vlrens
Species
Trlvalent C
FRESHWATER
Caddlsf ly,
Hydropsyche bettenl
Caddlsf ly.
Unidentified
Damsel fly.
Unidentified
Striped bass,
Morone saxat Ills
Species Mean
Acute Value
(lig/l)
6,300
4,400
4,300
3,650
3,100
2,000
2,000
Species Mean
Acute Intercept
-------�
Table 3. (Continued)
Rank"
14
13
12
11
10
9
8
7
6
5
4
3
2
Species
Pumpklnseed,
Lepomls gibbosus
American eel,
An^u Ilia rostrata
Banded kllllflsh,
Fundulus dlaphanus
Blueglll,
Lepomls macrochlrus
White perch,
Morone americana
Carp,
Cyprlnus carpio
Goldfish,
Carraslus auratus
Cladoceran,
Oaphnla magna
Annel Id,
Nals sp.
Guppy,
Poec Ilia ret 1 cu 1 ata
Snail,
Amnlcola sp.
Fathead minnow,
Pfmephales promelas
Scud,
Gammarus sp.
Species Mean Species Mean
Acute Intercept Acute-Chronic
(MO/I) Ratio
224
224
224
191
191
1B9
161
138
136
132
123
118
47
B-32
-------�
Table 3. (Continued)
Species Mean Species Mean
Acute Intercept Acute-Chronic
Rank* Species (ug/l) Ratio
1 Mayfly, 33.4
Ephemerela subvert a
* Ranked from least sensitive to most sensitive based on species mean
acute value or Intercept.
Hexavalent Chromium
Freshwater Final Acute Value =• 21.2 ug/l
Saltwater Final Acute Value » 1,260 ug/l
Final Acute-Chronic Ratio = 72 {see text)
Freshwater Final Chronic Value = {21.2 ug/D/72 = 0.29 ug/l
Saltwater Final Chronic Value = (1,260 ug/O/72 » 17.5 ug/l
Trlvalent Chromium - Freshwater
Final Acute Intercept = 32.3 ug/l
Natural logarithm of 32.3 = 3.48
Acute slope = 1.08 (see Table 1)
Final Acute Equation = e'1-081 '"(hardness) 1+3.48}
B-33
-------�
Table 4. Plant values for chromium
Species
Green alga,
Chlamydomonas relnhardl
Green alga,
Selenastrum capr Icornutum
Green alga,
Scenedesmus sp.
D 1 atom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navicula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Diatom,
Navlcula semlnulum
Chemical
Potassium
dichr ornate
Sodium
chromate
Potassium
dl chromate
Potassium
dl chromate
Potassium
dl chromate
Potassium
di chromate
Potassium
dl chromate
Potassium
dl chromate
Potassium
dl chromate
Potassium
dJ chromate
Potassium
dl chromate
Potassium
di chromate
Potassium
dl chromate
Hardness
Ong/l as
CaCO^)
Hexavalent
FRESHWATER
45
45
45
45
45
45
171
171
171
171
Effect
Chromium
SPECIES
Reduct Ion 1 n
growth
Inhibition In
growth
Inhibition In
growth
50* growth
reduction
50* growth
reduction
50* growth
reduct ion
50* growth
reduct ion
50* growth
reduction
50* growth
reduction
50* growth
reduction
50* growth
reduction
50* growth
reduction
50* growth
reduction
Result*
(uq/l)
10
45
500
187
230
251
272
308
237
254
254
343
343
Reference
Zarafonetis &
Hampton, 1974
Garton, 1972
Staub, et al. 1973
Academy of Sciences,
1960
Academy of Sciences,
I960
Academy of Sciences,
I960
Academy of Sciences,
1960
Academy of Sciences,
I960
Academy of Sciences,
I960
Academy of Sciences,
1960
Academy of Sciences,
1960
Academy of Sciences,
1960
Academy of Sciences,
1960
B-34
-------�
Table 4« (Continued)
Species
Diatom,
Navlcula semi nuturn
Diatom,
Navlcula semlnulum
Eurasian waterraIIfolI,
My rIophy11urn spI catum
Alga,
Macrocystls pyrlfera
Alga,
Macrocystls pyrlfera
Chemical
Potassium
dichromate
Potassium
dichr ornate
Dlchromate**
Potassium
dlchromate
Hardness
(mg/l as
CaCOy)
171
171
Effect
50% growth
reduction
50% growth
reduction
50% root weight
Inhibition
SALTWATER SPECIES
Result*
(ug/l)
424
442
1,900
50% Inhibition 5,000
of photosynthesis
In 4 days
10 - 20% Inhibi-
tion of photo-
synthesis In
5 days
1,000
Reference
Academy of Sciences,
I960
Academy of Sciences,
1960
Stanley, 1974
Clendenning & North,
1959
Bernhard 4 Zattera,
1975
Eurasian watermlIfolI,
MyrIophyI Ium spIcatum
Trlvalent Chromium
FRESHWATER SPECIES
50% root weight 9,900
inhibition
Stanley, 1974
* Results are expressed as chromium, not as the compound.
**Salt not given.
B-35
-------�
Species
TIssue
Table 5. Residues for chromium
Chemical
BIoconcentratIon
Factor
Duration
(days) Reference
Rainbow trout. Muscle
Sal mo gairdnerl
Rainbow trout. Whole body
Sal mo galrdneri
Polychaete worm,
Neanthes arenaceodentata
Oyster, Soft parts
Crassostrea virgin lea
Blue mussel. Soft parts
Mytl lus edul is
American oyster. Soft parts
Crassostrea virgin lea
Soft shell clam. Soft parts
My a arenarla
Blue missel. Soft parts
Mytl lus edul Is
Hexavalent Chromium
FRESHWATER SPECIES
Sodium
-------�
Table 6. Other data for chromium
Species
Algal community
Algal community
Algal community
Algal community
Protozoa,
Blepharlsma sp.
Snal 1,
Goniobasls llvescens
Snal 1,
Lymnaea emarqinata
Snail,
Physa Integra
C ladoceran,
Daphnla magna
C ladoceran,
Daphnla magna
C ladoceran,
Daplmia magna
C ladoceran,
Daphnla magna
Chemical
Potassium
dlchr ornate
Potassium
bichromate
Potassium
dlchr ornate
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dl chroma te
Potassium
dichromate
Potassium
dichromate
Potassium
dichromate
Potassium
dlchr ornate
Potassium
dichromate
Hardness
(ng/l as
CaCOO Duration
Hexavalent Chromium
FRESHWATER SPECIES
1 mo
1 mo
1 mo
25 hrs
3 hrs
154 48 hrs
154 48 hrs
154 48 hrs
163 72 hrs
163 72 hrs
163 72 hrs
163 72 hrs
Effect
Diatoms reduced
blue green
algae dominant
Diversity of
diatoms reduced
B ioconcentrat Ion
of chromium:
8,500
32* Inhibition
of photo-
synthesis
Some 1 1 v 1 ng
LC50
LC50
LC50
LC50
LC50
LC50
LC50
Result*
(yg/l)
400
100
400
20
32,000
2,400
34,800
660
64**
72**
73**
74**
Reference
Patrick, et al. 1975
Patrick, et al. 1975
Patrick, et al. 1975
Zarafonetls & Hampton,
1974
Ruthven & Cairns, 1973
Cairns, et al. 1976
Cairns, et al. 1976
Cairns, et al. 1976
Debelak, 1975
Debelak, 1975
Debelak, 1975
Debelak, 1975
B-37
-------�
Table 6. (Continued)
Species
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Cladoceran,
Daphnla magna
Coho salmon.
Oncorhynchus klsutch
Coho salmon.
Oncorhynchus klsutch
Chemical
Potassium
dichromate
Potassium
dichromate
Potassium
d 1 chromate
Potassium
dichromate
Potassium
d 1 chromate
Potassium
d 1 chromate
Potassium
d 1 chr ornate
Sodium
chromate
Potassium
dichromate
Potassium
dichromate
Potassium
chromate
Potassium
chromate
Sodium
dichromate
Hardness
(mg/l as
CaCO,)
163
86
86
86
86
86
too
100
_
-
44
-
60
Duration
72 hrs
72 hrs
72 hrs
72 hrs
72 hrs
72 hrs
100 hrs
100 hrs
96 hrs
Life span
<32 days
2 hrs
13 days
14 days
Effect
LC50
LC50
LC50
LC50
LC50
LC50
LC50
LC50
LC50
Life span and
fecundity
reduced
Lethal
LC50
Mortality aft<
transfer to 3<
Result*
(yg/l) Reference
Debelak, 1975
Debelak, 1975
38** Debelak, 1975
39*• Debelak, 1975
42** Debelak, 1975
44*« Debelak, 1975
140 Dowden & Bennett, 1965
130 Freeman & Fowler, 1953
50 Trabalka & Gehrs, 1977
10 Trabalka 4 Gehrs, 1977
100 Lee & Bulkema, 1979
25,000 Holland, et al. I960
g/kg seawater
B-38
-------�
Tab|Q 6. (Continued)
Species
Coho salmon,
Oncorhynchus klsutch
Coho salmon,
Oncorhynchus klsutch
Chinook salmon,
Oncorhynchus tshawytscha
Chinook salmon,
Oncorhynchus tshawytscha
Rainbow trout (embryo),
Sal mo galrdnerl
Rainbow trout,
Sal mo galrdnerl
Rainbow trout,
Sal (no qalrdnerl
Rainbow trout,
Salmo galrdnerl
Rainbow trout,
Sal mo galrdnerl
Rainbow trout,
Sal mo galrdnerl
Rainbow trout,
Salmp^ galrdnerl
Goldfish,
Carasslus auratus
Fathead minnow,
Piroephales promelas
Mosqultof Ish,
Gambusia aft In is
Chemical
Sodium
dlchromate
Sodium
dichromate
Sodium
dlchromate
Potassl urn
dlchromate
Chromic
oxide
Potassium
dichromate
Hexavalent
chromium
Sodium
dlchromate
Potassium
chr ornate
Potassium
chrornate
Potassium
dlchromate
Potassium
dichromate
Potassium
dichromate
Potassium
chr ornate
Hardness
(mg/l as
60
60
70
70
99
70
70
334
334
220
220
Duration
14 days
28 days
4 mos
12 wks
28 days
7 days
2 days
14 wks
24 hrs
24 hrs
15 days
II days
11 days
96 hrs
Effect
Result*
(yg/l)
Mortality after 480
transfer to 20
g/kg seawater
Mortality after
transfer to 20
g/kg seawater
Growth
Mortality and
growth
LC50
Plasma
"cortlsol"
Inhibition
Na/K-ATPase
Growth
16
Lethal
LC50
LC50
LC50
180
Reference
Sugatt, 1980
230 Sugatt, 1980
Olson A Foster, 1956
200 Olson, 1958
Blrge, et al. 1978
20 HI I I & Fromm, 1968
2,500 Kuhnert, et al. 1976
21 Olson 4 Foster, 1956
Hematocrits 2,000 Schiffman & Frornn, 1959
LC50 100,000 Schiffman 4 Fromm, 1959
10,000 Strlk, et al. 1975
30,400 Adelman & Smith, 1976
17,300 Adelman 4 Smith, 1976
107,000 Wailen, et al. 1957
B-39
-------�
Table 6. (Continued)
Species
Mosquito fish,
Gambusla afflnls
Mosquitoflsh,
Gambusla afflnls
Mosquitoflsh,
Gambusla afflnls
Bluegll 1,
Lepomls macrochirus
Largemouth bass (embryo),
Mlcropterus sal mo Ides
Largemouth bass,
Mlcropterus sal mo ides
Largemouth bass,
Mlcropterus sal mo Ides
Salamander (embryo),
Ambystoma opacum
Polychaete worm,
Ctenodrl lus serratus
Polychaete worm,
Ophryotrocha dladema
Polychaete worm,
Ophryotrocha dladema
Polychaete worm
( juvenl le),
Neanthes arenaceodentata
Polychaete worm (adult),
Neanthes arenaceodentata
Chemical
Potassium
dl chroma te
Sodium
chr ornate
Sodium
d 1 chromate
Potassium
dl chromate
Chromic
oxide
Potassium
chromate
Potassium
chromate
Chromic
oxide
Chromium
tr loxlde
Chromium
tr loxlde
Chromium
tr 1 ox I de
Chromium
tr (oxide
Chromium
trloxlde
Hardness
(wg/l as
CaCOO Duration
% hrs
96 hrs
96 hrs
105 2 wks
99 8 days
334 36 hrs
334 48 hrs
99 8 days
SALTWATER SPECIES
21 days
21 days
28 days
28 days
28 days
Effect
LC50
LC50
LC50
Increased loco-
motor activity
LC50
Pathology of
Intestine
LC50
LC50
100 % mortality
100% mortality
Brood size
decrease
50< mortality
50* mortal ity
Result*
(pg/1)
99,000
135,000
92,000
50
1,170
94,000
195,000
2,130
50,000
50,000
500-
1,000
700
550
Reference
Wai ten, et al. 1957
Wai len, et al. 1957
Wat ten, et al. 1957
El Igaard, et al. 1978
Blrge, et al. 1978
Fromm & Sen! ff man, 1958
Fromm 4 Schlffman, 1958
Blrge, et al. 1978
Relsh 4 Carr, 1978
Relsh 4 Carr, 1978
Relsh 4 Carr, 1978
Reish, et al. 1976
Relsh, et al. 1976
B-40
-------�
Tah|e 6. (Continued)
Species Chemical
Polychaete worm. Potassium
Neanthes arenaceodentata dI chromate
Pol/chaete worm. Potassium
Neanthes arenaceodentata dI chromate
Polychaete worm. Potassium
Neanthes arenaceodentata dI chromate
Polychaete worm. Potassium
Neanthes arenaceodentata dI chromate
Polychaete worm. Potassium
Neanthes arenaceodentata dIchromate
Polychaete worm. Potassium
Neanthes arenaceodentata dlchromate
Polychaete worm (adult). Chromium
Capltella capltata trI ox Ide
Polychaete worm (adult). Potassium
Capltella capltata dlchromate
Polychaete worm. Sodium
Nereis vIrons chromate
Polychaete worm. Potassium
Nereis vIrons chromate
Soft shell clam. Potassium
Mya arenarla chromate
Mudsnall, Potassium
NassarI us obsoletus chromate
Hermit crab. Potassium
Pagurus long I carpus chromate
Shore crab, Sodium
Carctnus maenas chromate
Hardness
(mg/l as
CaCO,)
Duration
7 days
56 days
14 days
59 days
7 days
350 days
28 days
5 mos
21 days
7 days
7 days
7 days
7 days
12 days
Effect
50* mortality
50* mortality
Result*
(ug/l)
1,440-
1,890
Reference
Oshlda, et al. 1976
200 Oshlda & Relsh, 1975
Inhibition-tube 79 Oshlda 4 Reish, 1975
bu11dIng
50* mortality 200 Mearns. et al. 1976
50* mortality 1,630 Mearns, et al. 1976
Brood size
decrease
12.5 Mearns, et al. 1976
50* mortality 280 Reish, et al. 1976
Brood size 50- Relsh, 1977
decrease 100
50* mortality 1,000 Raymont & Shields, 1963
50* mortality 700 Elsler & Hennekey, 1977
50* mortality 8,000 Elsler & Hennekey, 1977
50* mortality 10,000 Elsler & Hennekey, 1977
50* mortal Ity 2,700 Elsler & Hennekey, 1977
50* mortality 60,000 Raymont & Shields, 1963
B-41
-------�
Table 6. (Continued)
Species
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Grass shrimp,
Palaemonetes puglo
Prawn (juvenlle),
Leander squl I la
Prawn (adult),
Leander squl I la
Brittle star,
Ophlothrlx splculata
Starfish,
Aster i as forties I
Chemical
Potassium
chromate
Potassium
chromate
Potassium
chromate
Potassium
chromate
Potassium
chromate
Potass luro
chromate
Potass I urn
chromate
Potassium
chromate
Sodium
chromate
Sodium
chromate
Potassl urn
chromate
Hardness
(mg/l as
CaCOx) Duration
48 hrs 10
C, 10 g/kg
salinity
48 hrs 15
C, 10 g/kg
sal Inlty
48 hrs 20
C, 10 g/kg
salinity
48 hrs 25
C, 10 g/kg
salinity
48 hrs 10
C, 20 g/kg
salinity
48 hrs 15
C, 20 g/kg
salinity
48 hrs 20
C, 20 g/kg
sal Inlty
48 hrs 25
C, 20 g/kg
salinity
7 days
7 days
7 days
7 days
Result*
Effect (ug/l)
50* mortality 61,000
50< mortality 39,000
50 % mortality 37,000
50? mortality 21,000
50* mortality 147,000
50* mortality 107,000
50? mortality 78,000
50* mortality 77,000
Tox/c 5,000
threshold
Toxic 10,000
threshold
50* mortality 1,700
50% mortality 10,000
Reference
Fates,
Fales,
Fales,
Fales,
Fales,
Fales,
Fales,
Fales,
Raymont
Raymont
Oshlda
Elsler
1978
1978
1978
1978
1978
1978
1978
1978
& SI
a, si
4 Wr
& Hei
B-42
-------�
Table 6. (Continued)
Species
Mummichog,
Fundulus heteroclitus
Speckled sanddab,
Cltharlchthys stlqmaeus
Speckled sanddab,
Cltharlchthys stlqmaeus
Speckled sanddab,
Cltharlchthys stlqmaeus
Si Iver salmon,
Oncorhynchus ktsutch
Si Iver salmon,
Oncorhynchus klsutch
Snail (embryo),
Amnlcola sp.
Cladoceran,
Daphn la magna
Cladoceran,
Daphn la magna
Cladoceran,
Daphn la magna
Cladoceran,
Daphn la magna
Cladoceran,
Daphn i a magna
Chemical
Potassium
chromate
Potassium
d i chromate
Potassium
dl chromate
Potassium
d 1 chromate
Potassium
chromate
Potassium
chromate
Chromic
chloride
Chromic
n 1 trate
Chromic
su 1 fate
Chromium
chloride
Chromium
chloride
Hardness
(mg/l as
CaCOO Duration
7 days
21 days
21 days
21 days
5 days
1 1 days
Trlvalent Chromium
FRESHWATER SPECIES
50 96 hrs
64 hrs
206 21 days
48 hrs
45 3 wks
45 3 wks
Effect
50* mortality
50* morta 1 1 ty
EC50- feed ing
response
50* mortality
33* mortality
100* mortality
LC50
LC50
Reproduction
1 nh 1 bi ted
LC50
LC50
Chronic value
Result*
(M9/D
44 ,000
5,400
2,200
5,000
31,800
31,800
12,400
1,200
44
4-8
2,000
445
Reference
Elsler & Hennekey, 19'
Sherwood, 1975
Sherwood, 1975
Mearns, et al. 1976
Hoi land, et al. 1960
Hoi land, et al. I960
Rehwoldt, et al. 1973
Anderson, 1948
Chapman, et al.
Manuscript
Dowden & Bennet, 1965
Blesinger &
Chrlstensen, 1972
Bieslnger &
Chrlstensen, 1972
B-43
-------�
TabI* 6. (Continued)
Species
Chemical
Hardness
(MS/I as
CaCO,)
Duration
Effect
SALTWATER SPECIES
Polychaete worm,
Neanthes arenaceodentata
Polychaete worm,
Neanthes arenaceodentata
Chromium
chloride
Chromium
chloride
-
<24 hrs
160 days
100| mortality
Reproduction
occurred
Result*
(ug/l)
50.400
(pH=4.5)
50,400
(pH=7.9)
Reference
Mearns, et at. 1976
Mearns, et al. 1976
* Results are expressed as chromium, not as the compound.
••Animals were fed during test
8-44
-------�
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B-45
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B-47
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B-49
-------�
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B-53
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Mammalian Toxicology and Human Health Effects
INTRODUCTION
Chromium (Cr) is a common element, present in low concentra-
tions throughout nature. Its toxicity has long been recognized,
but detailed analysis of toxic effects is complicated by the occur-
rence of many different compounds of the metal; these may contain
Cr in different valence states and are distinguished by their chem-
ical, physical, and toxicological properties.
This document considers relevant chemical and ohysical proper-
ties of Cr compounds to which man may be exposed, and attempts to
evaluate possible health hazards associated with such exposures.
The general area of environmental effects of chromium compounds was
recently reviewed by the U.S. Environmental Protection Agency (U.S.
EPA, 1978); a valuable discussion of the medical and biological
effects of Cr in the environment is found also in a volume pub-
lished by the National Academy of Sciences (NAS, 1974). Occupa-
tional hazards of chromium were assessed in a Criteria Document
prepared in 1975 [National Institute for Occupational Safety and
Health (NIOSH), 1975]. Mertz (1969) provided a valuable survey of
the biochemical properties of Cr compounds. A general review of
the occurrence, metabolism, and effects of chromium has been pre-
sented by the NAS (1977).
To avoid unnecessary duplication, previously reviewed materi-
al will not be considered at great length except when it imoinges
directly on present critical considerations. Detailed documenta-
tion for most of the available information can be found in the ear-
lier reviews.
C-l
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There is little need to discuss here the detailed chemistry of
chromium, as this subject has been adequately reviewed in the re-
cent past (U.S. EPA, 1978). Wowever, an evaluation of the signifi-
cance of various routes of exposure to compounds containing Cr, and
of the factors determining rates of uptake and toxicity of such
compounds, requires an understanding of their physical properties
and of their chemical and biochemical reactions.
The metallic element Cr belongs to the first series of transi-
tion elements, and occurs in nature primarily as compounds of its
trivalent [Cr (III)] form. Generally speaking, the hexavalent com-
pounds are relatively water-soluble and readily reduced to the more
insoluble and stable forms of Cr (III) by reaction with organic re-
ducing matter. Because large amounts of Cr (VI) are produced and
utilized in industry (primarily as chromates and dichromates), and
because of their ready solubility, traces of such compounds are
frequently found in natural waters.
As pointed out, Cr (VI) is rapidly reduced when in contact with
biological material. The reverse reaction is not known to occur in
the human body. Trivalent Cr forms stable hexacoordinate complexes
with many molecules of biochemical interest. Interaction of Cr (III)
with such compounds may involve binding to carboxy- groups of pro-
teins or smaller metabolites, coordination with certain amino
acids, and binding to nucleic acids and nucleoproteins. This last
reaction is of special significance in the consideration of the
carcinogenic potential of Cr compounds. The field was reviewed by
Mertz (1969) and it suffices here to emphasize the stability of
these Cr complexes, and the fact that the element is found combined
C-2
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with both RNA and DNA. An effect of Cr on the tertiary structure of
nucleic acids is clearly indicated. In general, it may be conclud-
ed that reduction of Cr (VI) to Cr (III) and its subsequent coordi-
nation to organic molecules of biochemical interest explain in
large measure the biological reactivity of Cr compounds. Thus, the
well-known reaction of Cr with skin proteins (i.e., the tanning
process) involves coordination sites of Cr (III) . For reasons of
solubility, however, uptake of compounds of Cr (VI) by the living
organism generally exceeds that of Cr (III) compounds (see Acute,
Subacute, and Chronic Toxicity section).
A good illustration of the behavior of Cr compounds in biolog-
ical systems is furnished by the reaction of Cr with erythrocytes
(Gray and Sterling, 1950). These cells do not react to any signif-
icant extent with Cr (III); in contrast, they rapidly take up ani-
ons of hexavalent Cr compounds, presumably utilizing the broadly
specific anion transport facilitation in erythrocytes reviewed by
Fortes (1977). Thus, we may invoke as a likely explanation for the
greater toxicity of Cr (VI) than of Cr (III) compounds their more
rapid uptake by tissues due to their solubilitv and to the facili-
tation of their translocation across biological membranes. Once
within cells, the Cr (VI) is likely to be reduced to the trivalent
state before reacting with cell constituents such as proteins and
nucleic acids. In the case of red cells, it is such an intracellu-
lar reaction of Cr (III) with hemoglobin which explains the essen-
tially irreversible uptake of the metal and permits use of chro-
mium-51 as red cell marker.
C-3
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Stable and soluble compounds of Cr (III) are found in many
biological systems. Among these is the so-called glucose toler-
ance factor (GTF) (Mertz, 1969), a compound of unknown structure
whose absence is believed responsible for symptoms of chromium
deficiency. In the form of GTF and perhaps of other similar com-
plexes Cr (III) can also cross biological membranes with relative
ease; thus it is readily absorbed from the intestine in this form
(Doisy, et al. 1971) . One may recall in this connection the gener-
al importance of metal ligands in determining movement of heavy
metals within the body (Collins, et al. 1961? Foulkes, 1974) . It
is not surprising therefore that distribution of Cr in the body
also critically depends on the presence of specific ligands (Mertz,
1969) .
Chromium plays a role in human nutrition. Because of this
fact, lowering of ambient Cr levels to a value where total uptake
might lead to overt Cr deficiency must be avoided. Indeed, effects
of Cr deficiency in man and experimental animals have been de-
scribed (Mertz, 1969). Levels of Cr compounds required for optimal
nutrition fall greatly below those which have been reported to
cause toxic effects (see Acute, Subacute, and Chronic Toxicity sec-
tion) ; therefore normal nutritional levels need not be considered
further here. It must be pointed out, however, that the American
diet may be potentially deficient in Cr so that some increased Cr
uptake might be beneficial.
Sources of chromium in the environment have been recently
reviewed (U.S. EPA, 1978). Although Cr is widely distributed, with
an average concentration in the continental crust of 125 mg/kg, it
is rarely found in significant concentrations in natural waters.
C-4
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Air levels in nonurban areas usually fall below detection limits
and may be as low as 5 pg/m . Much of the detectable Cr in air and
water is presumably derived from industrial processes, which in
1972 utilized 320,000 metric tons of the metal in the United States
alone. A significant fraction of this amount entered the environ-
ment; additional amounts are contributed by combustion of coal and
other industrial processes (U.S. EPA, 1974) . As a result, levels
of Cr in air exceeding 0.010 yg/m have been reported from 59 of 186
urban areas examined (U.S. EPA, 1973). Mean concentrations of Cr
in 1,577 samples of surface water were reported as 9.7 ug/1 (Kopp,
1969). The significance of 9.7 uq/1 as a mean value is question-
able because only 25 percent of the samples tested contained any
detectable Cr. Occasional values of total Cr fCr (Til) and Cr
(VI)] exceeded 50 yg/1, a fact which must be noted in relation to
the recommended standard for domestic water supplies (see Existing
Guidelines and Standards section).
It is important to reemphasize at this time the analytical
difficulties attending estimation of low concentrations of Cr,
especially in biological materials. Additionally, the different
chemical species of Cr which may be present often cannot be clearly
separated. Considerable uncertainty attaches to the significance
of some results, particularly those obtained with some of the older
techniques. This topic was considered in detail recently (U.S.
EPA, 1978).
C-5
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EXPOSURE
Ingestion from Water and Food
At an average concentration of approximately 10 ug Cr/1 drink-
ing water (Kopp, 1969) , and a daily water consumption of 2 1, about
20 yg Cr would be ingested in water per day compared to about 50 to
100 ug/day in the American diet (Tipton, 1960). Dietary Cr intake
on a hospital diet averaged about 100 ug/day, while an estimate for
self-selected diets is 280 ug/day (NAS, 1974) . Fractional absorp-
tion of such an oral load from the intestine depends on the chemi-
cal form in which the element is presented (see Introduction sec-
tion) . In addition, even though mechanisms involved in the move-
ment of Cr compounds across intestinal epithelial barriers are not
understood, it is likely that the extent of this absorption will be
greatly influenced by the presence of other dietary constituents in
the intestinal lumen (^acKenzie, et al. 1958) , as has frequently
been observed in the case of other ingested metals.
For a variety of reasons, therefore, net fractional absorption
of Cr from the intestine is low and may amount to only a few percent
or even less (Mertz, 1969), depending especially on the chemical
form in which the element is ingested. Intake of Cr from the air
normally amounts to less than 1 ug/day (see Inhalation section),
and thus does not contribute significantly to normal Cr balance.
Average urinary excretion of Cr has been reported as 5 to 10 ug Der
day (Volkl, 1971); recent work suggests that because of analytical
difficulties, actual values may be somewhat lower (Guthrie, et al.
1979). In any case, it follows that the American diet may become
marginally deficient in this element, unable to provide the optimum
C-6
-------�
level required for normal function (see Introduction section).
This conclusion is supported by the finding that Cr levels in tis-
sues generally decrease with age (Mertz, 1969). The situation is
not greatly altered by application of Cr-containing fertilizers or
sewage sludges to agricultural land. Indeed, uptake of Cr by
plants from soil is generally low.
A bioconcentration factor (BCF) relates the concentration of a
chemical in aquatic animals to the concentration in the water in
which they live. An appropriate BCF can be used with data concern-
ing food intake to calculate the amount of chromium which might be
ingested from the consumption of fish and shellfish. Residue data
for a variety of inorganic compounds indicate that bioconcentration
factors for the edible portion of most aquatic animals is similar,
except that for some compounds bivalve molluscs (clams, oysters,
scallops, and mussels) should be considered a separate group. An
analysis (U.S. EPA, 1980a) of data from a food survey was used to
estimate that the per capita consumption of freshwater and estua-
rine fish and shellfish is 6.5 g/day (Stephan, 1980) . The per
capita consumption of bivalve molluscs is 0.8 g/day and that of all
other freshwater and estuarine fish and shellfish is 5.7 g/day.
The BCF for hexavalent chromium in fish muscle appears to be
less than 1.0 (Buhler, et al. 1977; Fromm and Stokes, 1962) but
values of 125 and 192 were obtained for oyster and blue mussel,
(U.S. EPA, 1980b), respectively. For trivalent chromium BCF values
of 116, 153, and 86 were obtained with the American oyster (Shuster
and Pringle, 1969) and soft shell clam and blue mussel (Cappuzzo
and Sasner, 1977), respectively. It appears that the two valence
C-7
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states of chromium have about the same BCF values and that the geo-
metric mean of 130 can be used for bivalve molluscs. If the values
of 0.5 and 130 are used with the consumption data, the weighted
average bioconcentration factor for chromium and the edible portion
of all freshwater and estuarine aquatic organisms consumed by Amer-
icans is calculated to be 16.
Inhalation
Levels of Cr in air have been carefully monitored. In the
United States in 1964, an average value of 0.015 ug/m was reported,
with a maximum of 0.35 ug/m . More recent values show levels below
detection limits in most nonurban and some urban areas (U.S. EPA,
1973); yearly averages exceeded 0.01 ug/m in only 59 of 186 urban
areas.
The chemical form of Cr in air will vary, depending primarily
on its source. There is little information on the size distribu-
tion of the particles, but it is safe to assume that a significant
portion will be in the respirable range. Uptake, of course, de-
pends on the aerodynamic diameter of the particles. Assuming both
an average alveolar ventilation of 20 m /day, and an alveolar re-
tention of 50 percent of Cr present at a level of 0.015 ug/ra , alve-
olar uptake would only amount to approximately 0.2 ug/day. Addi-
tional Cr could also be deposited in the upoer respiratory passages
and contribute ultimately to the intestinal load of Cr. In any
case, inhalation under normal conditions does not contribute sig-
nificantly to total Cr uptake.
Even in the nonoccupational environment the concentration of
Cr in air may rise significantly above normal background levels.
C-8
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Thus, increased ambient concentrations of Cr have been reported in
the vicinity of industrial sites (U.S. EPA, 1978) . In the proximi-
ty of water cooling towers, for instance, where Cr was employed as
a corrosion inhibitor, air levels of Cr as high as 0.05 ug/m have
been reported. However, even such a relatively high level is not
likely to greatly alter total Cr uptake. The possibility that
smoking might contribute to the pulmonary load of Cr has not been
fully evaluated.
Of course, if the lungs represent a target organ for Cr, addi-
tional pulmonary loads may assume significance even though total
body Cr may not have been materially increased by the inhalation
exposure. Although such exposure can lead to a significant in-
crease in urinary excretion of Cr, it is not clear to what extent
the Cr added to systemic pools originated in the lungs or was
alternatively absorbed from the intestines following pulmonary
clearance of the Cr-containing particles. In any case, pulmonary
Cr does not appear to be in full equilibrium with other Cr pools in
the body. This conclusion is based on the fact that the Cr content
of the lungs, unlike that of the rest of the body, may actually
increase with age (Mertz, 1969). Prolonged pulmonary retention of
inhaled Cr is also reflected by the fact that the pulmonary concen-
tration of the element usually exceeds that of other organs. The
relatively slow clearance of Cr from the lungs was also noted by
Baetjer, et al. (1959a), who found that 60 days after intratracheal
instillation into guinea pigs, 20 percent of a dose of CrCl-, re-
mained in this tissue.
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Dermal
Compounds of Cr permeate the skin fairly readily when applied
in the hexavalent form; trivalent Cr compounds react directly with
epithelial and dermal tissue. Cutaneous exposure is primarily a
problem of the workplace; many lesions have been described under
these conditions, including ulceration and sensitization. There is
little evidence, however, to suggest that cutaneous absorption sig-
nificantly contributes to the total body load of Cr in the normal
environment.
Evaluation of Relative Contribution of Different Exposure Routes
to Body Burden
The three previous sections review briefly the uptake of Cr by
ingestion, inhalation, and cutaneous absorption. None of the three
routes of entry will lead to harmful levels of Cr in the body when
exposure involves only the low levels of the element normally found
in food, water, and air. Indeed, it may be recalled (see Ingestion
section) that the average American may actually suffer from mild Cr
deficiency. The major fraction of body Cr originating in the gen-
eral environment is contributed by ingestion. In industrial sur-
roundings, by contrast, other routes of exposure may become more
significant. Uptake of Cr by inhalation may pose special risks
here. This conclusion follows from the fact that the lungs tend to
retain Cr more than do other tissues (see Inhalation section). The
Carcinogenicity section deals further with pulmonary effects of
exposure to Cr in air.
Under normal conditions of exposure, considerable variability
has been observed in the Cr concentrations of different tissues.
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It is difficult to assess, however, to what extent the wide range
of values reported reflects analytical problems rather than true
individual variations. As a first approximation, an average level
of around 2 yg Cr/g ash may be derived from the work of Tipton and
Cook (1963) and of Imbus, et al. (1963) for most soft tissues and
for whole blood of nonexposed humans. Levels of Cr in the lungs may
be ten times higher; there is no evidence to suggest that Cr is a
bone-seeking element. If we further assume that the average ash
content of soft tissues approximates 1 percent of fresh weight, a
total body burden in the adult of the order of 2 mg may be calculat-
ed. Results of Schroeder, et al. (1962) showed values of Cr in
human tissues of the order of 0.05 ug/g fresh weight, which would
correspond to a total adult body burden of around 3 to 4 mg; Schroe-
der (1965) suggested an upper limit of 6 mg Cr in a 70 kg man.
These values are presented here to indicate the net result of Cr
uptake by ingestion, inhalation, and cutaneous absorption under
normal conditions. As pointed out, this body burden may actually
represent a marginally deficient state.
PHARMACOKINETICS
Absorption, Distribution, Metabolism, and Excretion
Analysis of the movement of Cr through various body pools, and
determination of the size and turnover rates of these pools, are
complicated by several facts. In the first place it is likely that
different Cr compounds will exhibit different kinetic characteris-
tics in the body; this is well illustrated by the wider body dis-
tribution of Cr injected in the form of the glucose tolerance fac-
tor than when administered as CrCl^ (Mertz, 1969). Second, the
C-ll
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chemical methods employed for the estimation of biological Cr con-
centrations do not adequately distinguish between different forms
of Cr present in the original sample. For instance, the results of
Schroeder, et al. (1962) suggest that both hexavalent and trivalent
Cr may occur in the ash of biological materials. However, precise
conclusions on this point are difficult because the chemical forms
of Cr may be changed during the ashing. Third, difficulties of
interpretation arise from the fact that one chemical species of Cr
may be transformed into another in the body, for instance as by
reduction of Cr (VI) to Cr (III) .
The complexity of the pharmacokinetics of Cr to be predicted
from such considerations is observed both in man and in experiment-
al animals. This situation may be illustrated by reference to the
urinary excretion of Cr under normal conditions. In man, the kid-
neys account for 80 percent or more of Cr excretion by nonexposed
individuals (NAS, 1974); urinary excretion amounts on the average
to 5 to 10 uig/day or less (see Ingestion from Water and Food sec-
tion) . Such a value corresponds to less than 1 percent of the total
body burden as estimated in the Evaluation of Relative Contribution
of Different Exposure Routes to Body Burden section; it also ap-
proximately equals the average daily dietary retention of Cr (see
Ingestion from Water and Food section) . The body thus appears
roughly to be in steady state with regard to Cr. It would not be
correct to infer, however, that the turnover rates of the various
Cr pools in the body all fall below 1 percent/day; this would be
true only if Cr taken in by one of the routes of entry discussed in
the Exposure section always equilibrated evenly with different body
pools.
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Although little information is available on changes in specif-
ic radioactivities of Cr in different body compartments following
administration of Cr, there is strong evidence to show that dif-
ferent compartments exhibit distinctly different turnover kinet-
ics. Lim (1978) reports the kinetics of radiochromium (III) dis-
tribution in humans. Three major accumulation and clearance compo-
nents were found for liver, spleen, and thigh; liver and spleen
contained the higher concentrations. Normally in man, the highest
concentration of Cr is found in the lungs, and pulmonary levels
tend to rise with age while the Cr content of other tissues falls.
Apparently the lung obtains most of its Cr from the air, not from
oral loads, and pulmonary Cr does not come into equilibrium with
other body pools of Cr (see Inhalation section).
Similar conclusions on nonequilibration of body pools can be
drawn from measurements on the excretion kinetics of Cr (III) in-
jected into rats. At least three kinetic compartments were ob-
served in this case (Mertz, et al. 1965), with half-lives respec-
tively of 0.5, 5.9, and 83.4 days. The Cr in a slowly equilibrat-
ing compartment in man was estimated to possess a half-life of 616
days (U.S. EPA, 1978). Injection of 1 mg of unlabeled Cr into
rats, a very large dose compared to the presumptive body burden as
calculated in the Evaluation of Relative Contributions of Different
Exposure Routes to Body Burdens section, exerted little effect on
the rate of tracer excretion from the slow compartment. The find-
ing that even a very large excess of Cr does not affect this com-
partment further indicates that ingested or injected Cr does not
C-13
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necessarily pass through every body compartment on its way to
excretion. Finally, this conclusion is supported by the observa-
tion that the pool from which Cr (at least in some systems) enters
plasma following administration of glucose is not readily labeled
by injected 51Cr (administered as CrCl-j) (Mertz, 1969).
As is the case with other metals/ chromium normally circulates
in plasma primarily in a bound, nondiffusible form (Mertz, 1969).
At low levels of Cr (III) the iron-binding protein siderophilin
complexes most of the Cr present, but at higher levels of Cr other
plasma proteins also become involved. The high affinity of Cr
(III) for siderophilin presumably reflects the fact that this pro-
tein provides the normal mechanism of transport for Cr to the tis-
sues. A small fraction of plasma Cr is also present in a more dif-
fusible form, complexed to various small organic molecules which
are filtered at the glomerulus and partially reabsorbed in the
renal tubule. The suggestion that this reabsorption may involve an
active transport process (Davidson, et al. 1974) is not supported
by the evidence presented. Chromium very tightly bound in low-
molecular weight complexes such as Cr-EDTA may serve as a glomeru-
lar indicator, being freely filtered but not reabsorbed (Stacy and
Thorburn, 1966).
The half-life of plasma Cr is relatively short, and cells tend
to accumulate the element to levels higher than that present in
plasma. Presumably this accumulation results from intracellular
trapping of Cr compounds which penetrate cells in the hexavalent
form and then react with cell constituents, such as hemoglobin in
the case of the erythrocyte. within the cells, Cr (VI) will be re-
C-14
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duced to Cr (III) and remain trapped in this form. In any case, the
lack of equilibration of Cr between plasma and cells renders inval-
id the use of plasma levels as indicators of total exposure.
Another reason for the limited usefulness of plasma Cr levels
as a measure of body burden is the likelihood that plasma Cr can be
identified with one of the rapidly excreted Cr compartments dis-
cussed above. This is suggested by the finding that even though the
rise in plasma Cr reported by some authors to occur after adminis-
tration of a glucose load is not derived from a rapidly labeled
pool, it is followed by increased urinary excretion of Cr (Mertz,
1969). In summary, little can be concluded at this time about the
nature, size, or location of the various body pools of Cr whose
existence was inferred from tracer equilibration and excretion
studies.
The importance of the chemical form of Cr in determining dis-
tribution of various compounds between pools is further illustrated
by the observation that while inorganic Cr (III) does not appreci-
ably cross the placental barrier, Cr (III) injected into pregnant
rats in the form of natural complexes obtained from yeast can read-
ily be recovered from the fetuses (see Mutagenicity section).
As further considered in the Effects section, compounds of Cr
(VI) may act as acute irritants whereas those of Cr (III) exert
little acute toxic action. Presumably, this fact reflects primari-
ly the poor intestinal absorption of the trivalent compounds, and
the strong oxidizing power of Cr (VT). The lungs, however, may
accumulate and retain relatively insoluble Cr (III) from respired
air, although even in this case Cr (VT) appears to be much more
C-15
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toxic than Cr (III) . Here again toxicity is determined as much by
the chemical form of Cr as by its concentration. The additional
factor of length of exposure to Cr is apparent in the need to im-
plant the test compound or to inject it intramuscularly before sar-
comas are produced at those sites (see Carcinogenicity section).
In terms of human exposure, such routes of administration possess
little relevance except to emphasize the importance of long-term Or
concentrations in specific body compartments as major determinants
of toxicity.
EFFECTS
Acute, Subacute, and Chronic Toxicitv
Because Cr is generally accepted to be an essential element,
the effects of exposure to low levels may be beneficial in defi-
ciency states; such an action of Cr would of course have to be sepa-
rated from the harmful consequences of exposure to higher concen-
trations. This can be readily achieved because the amounts of Cr
required to produce toxic effects are very much higher than those
involved in the correction of possible deficiencies. Thus, the
LD5Q for Cr (III) following its intravenous administration (10
mg/kg weight) exceeds by at least four orders of magnitude the dose
needed to relieve impairment of glucose tolerance in Cr-deficient
rats (U.S. EPA, 1978) . Still higher levels of Cr (III) must be fed
by mouth before toxic symptoms appear, a fact related to the rela-
tive insolubility and poor intestinal absorption of most compounds
of trivalent chromium.
Unlike compounds of Cr (III) , those of Cr (VI) tend to cross bio-
logical membranes fairly easily and are somewhat more readily ab-
C-16
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sorbed from the gut or through the skin. The strona oxidizing
power of hexavalent Cr explains much of its irritating and toxic
properties.
That the concentrations of chromium normally encountered in
nature barely meet the requirements for this element in the Ameri-
can diet /underlines the fact that natural levels do not constitute
a human health hazard. However, acute and chronic toxicity prob-
lems associated with exposure to Cr are of concern in the industri-
al environment or in areas potentially polluted by industrial
sources. Such toxic effects are reviewed in detail by NIOSH
(1975); they include systemic actions of Cr compounds, in addition
to primary lesions at the level of the skin, the respiratory pas-
sages, and the lungs. It must be emphasized again that the find-
ings of lesions following exposure to high concentrations of Cr
compounds under experimental conditions, or as a result of acci-
dental or deliberate human exposure, may bear little relevance to
the probability of Cr exerting similar actions at more normally
encountered levels.
Exposure to relatively high levels of Cr has been studied in
some detail. Thus, when Cr in the form of ^CrO, was administered
to dogs over a period of four years at a level of 0.45 mq/1 in
drinking water, increases in the Cr concentration of liver and
spleen were reported; at exposure levels 25 times higher, accumula-
tion in the kidneys also became apparent (Anwar, et al. 1961).
However, there were no significant pathological changes associated
with such exposures. Similarly, a concentration of 0.45 mg Cr/1
did not lead to any overt effects in four cases of prolonged human
C-17
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exposure (Davids, et al. 1951). Rats tolerated 25 mg/1 of Cr (III)
or several concentrations of Cr (VI), the highest of which was also
25 mg/1, in the drinking water for one year (MacKenzie, et al.
1958). Exposure to the highest concentration of Cr (VI), however,
led to a nine times higher amount of Cr in tissues than the same
concentration of Cr (III), a fact reflecting that intestinal ab-
sorption of the hexavalent form occurs more readily. An early
study by Gross and Heller (1946) mentioned specific symptoms such
as rough and dirty coat and tail, sterility, and general sub-normal
conditions in young albino rats fed 1,250 pm of ZnCrO. in the diet
for approximately two months. Higher concentrations yielded more
severe symptoms. Similar concentrations of Cr given as K2CrO4,
however, induced less severe symptoms. Either K2CrO^ or ZnCrO. in
drinking water or feed for an unspecified time had no observable
adverse effects in mature white mice or albino rats in concentra-
tions of the diet of up to 10,000 ppm (1 percent). Ivankovic and
Preussmann (1975) fed Cr203 at 0, 2, or 5 percent of the diet to BD
rats of both sexes for 90 days. Dose dependent reductions in organ
weights of the liver and spleen were observed, but pathological
changes, either macroscopic or histological, were not found in
these or other organs. No other effects were noted.
These findings support the conclusion that few systemic
changes would be expected to result from even moderately elevated
oral exposure to Cr. On that basis the standard of Cr established
for drinking water (see Existing Guidelines and Standards section)
should provide adequate protection against general systemic ef-
fects. The question of the safety of such a level in terms of pos-
C-18
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sible carcinogenic effects is considered in the Carcinogenicity
section.
On the other hand, evidence for systemic lesions following
more massive exposure, is well documented (U.S. EPA, 1978; NAS,
1974).
High concentrations of Cr causes renal damage. Thus, intra-
arterial injection of dichromate has been used for the experimental
production of lesions restricted to the first portion of the proxi-
mal tubule (Nicholson and Shepherd, 1959). Similarly, tubular
necrosis has repeatedly been observed following massive accidental
or deliberate exposure (suicide attempts) to Cr (NAS, 1974). These
cases, however, represent acute effects of very high doses and
their significance to environmental considerations is small.
In only one instance was an association between occupational
chromium exposure and hepatic lesions reported. A small number of
workers were excreting large amounts of Cr in their urine. Hepatic
changes were observed in biopsies although no overt clinical symp-
toms were seen. Among other systems shown to respond to high doses
of Cr is the dog intestine (U.S. EPA, 1976) . Although the possi-
bility of more subtle and long range systemic effects of high Cr
exposure cannot be excluded, there is no evidence to support its
likelihood.
The effects of Cr compounds on the skin were recognized over
150 years ago. Since that time they have been studied in depth by
many investigators, and reviewed in considerable detail (NAS,
1974). Earlier cases described in this review were ulcerative
changes developing from contact with various compounds of Cr
C-19
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Later studies emphasized that workers exposed to Cr (VI) could
develop allergic contact dermatitis; sensitivity also appeared to
develop to higher levels of Cr (III). No evidence could be found
for an association between chromium exposure and skin cancers.
In general, these reports concern relatively massive expo-
sures, unlikely to occur outside the occupational environment, and
made even less likely at the present time because of generally im-
proved industrial hygiene practices (NIOSH, 1975) . It is worth
noting that the standard set for permissible levels of Cr in drink-
ing water (see Existing Guidelines and Standards section) is much
lower than those reported to affect the skin. Mo evidence was
found to suggest that presently permissible concentrations of Cr in
domestic water supplies possess much significance in terms of skin
disease.
Subtle changes in pulmonary dynamics have been observed among
workers employed in the chromium electroplating industry (Bovett,
et al. 1977). The major effect of Cr on respiratory passages con-
sists of ulceration of the nasal septum, with subsequent perfora-
tion, and of chronic rhinitis and pharyngitis. The incidence of
such effects may become remarkably high at elevated Cr levels in
air. Thus, Mancuso (1951) observed nasal septal perforations in 43
to 85 percent of workers exposed in a chromate plant to both tri-
and hexavalent Cr in concentrations as high as 1 mg/m . The re-
ported incidence of rhinitis and pharingitis was even higher. In
another survey [U.S. Public Health Service (PHS), 1953], 509 of 897
chromate workers were found with nasal septal perforations. Bloom-
field and Blum (1928) had concluded that daily exposure to chronic
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acid concentrations exceeding 0.1 mg/m causes injury to nasal tis-
sue. Effects of lower concentrations have not been carefully stud-
ied, so no accurate conclusions on dose-effect relationships can be
drawn.
An additional difficulty in interpreting these results arises
from the fact that the exposure of the workers discussed here may
not have been associated primarily with airborne Cr: poor work
practices leading to local contact almost certainly caused a high
proportion of the nasal lesions (NIOSH, 1975). All nasal effects,
however, presumably reflect the irritating action of soluble com-
pounds of Cr (VI). There is no evidence to suggest that the ulcera-
tive lesions can give rise to cancers.
In an average concentration of 68 yg/m , Cr (VI) caused some
irritation to eyes and throat in a chromate-producing plant (U.S.
PHS, 1953). Information available does not permit derivation of
meaningful dose-effect relationships. Nevertheless, current evi-
dence indicates that the limit recommended by NIOSH (1975) for the
concentration of noncarcinogenic compounds of Cr (VI) in air will
protect most workers against irritation of the respiratory passages
(see Table 2) . This recommended standard permits a time-weighted
average exposure to 25 yg Cr/m of ambient air for a 40-hour week,
with a ceiling exposure to 50 yg/m of air for any 15-minute
period.
Teratogenicity
Although the mutagenic properties of certain compounds of Cr
are well established, little evidence could be found for fetal dam-
age directly attributable to such compounds. This is somewhat
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unexpected in light of placental permeability to at least some
forms of Cr (Mertz, 1969). Embryonic abnormalities were produced
in the chick when NajCCjO-j or CrtNO^)^ were injected into the yolk
sac or onto the chorioallantoic membrane (Ridgway and Karnofsky,
1952). The significance of these data in relation to ingestion of
chromium compounds is questionable.
Mutagenicity
Because of the close correlation emerging between carcinoge-
nicity of chemicals and their mutagenic properties in suitable test
systems, it is of interest to refer to the work of Venitt and Levy
(1974), who reported that soluble chromates of Na, K, and Ca stimu-
lated mutagenesis in E. coli. Negative results were obtained with
soluble salts of the two metals below Cr in the periodic table
(tungsten and molybdenum), as well as with a soluble compound of Cr
(III). Earlier reports (Hueper, 1971) classifying Cr salts under
the heading of carcinogenic chemicals without mutagenic properties
appear to have been in error.
In recent years much evidence has accumulated to show that
compounds of Cr possess the ability to cause transformation and
mutation. Both Cr (III) (as CrCl3) and Cr (VI) (as K2Cr207) in con-
centrations equitoxic to mice produced similar morphologic changes
in tertiary cultures of mouse fetal cells (Rafetto, et al. 1977) ;
it is interesting to note that Cr (VI) caused more extensive chro-
mosomal aberrations than did Cr (III) . Wild (1978) reported that
potassium chromate produces a dose-dependent cytogenetic effect on
bone marrow cells in mice. Bigalief, et al. (1976) observed a sig-
nificant increase in the frequency of bone marrow cells with chro-
C-22
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mosome aberrations in rats acutely or chronically poisoned with
potassium dichromate. In concentrations as low as 10 M, potas-
sium dichromate also significantly increased gene conversion in a
strain of yeast (Bonatti, et al. 1976). The transformation fre-
quency of simian adenovirus in Syrian hamster cells was raised by
calcium chromate (Casto, et al. 1977) . Hexavalent Cr has been sus-
pected of being responsible for the mutagenic effects of welding
fumes (Hedenstedt, et al. 1977). Further, aerosols of Cr (VI) have
been held responsible for mutagenic effects found in a group of
workers engaged in the production of chromium (Bigalief, et al.
1977). The full significance of these results, however, could not
be evaluated in the absence of the detailed publication.
There is little question about the mutagenic and cell trans-
forming capability of chromates. However, in the presence of liver
enzymes or gastric juice but not lung enzymes, chromates lose this
mutagenic activity (Petrilli and DeFlora, 1977, 1978). These ob-
servations were later confirmed by Gruber and Jinnette (1978) who
clearly demonstrated that Cr (VI) is reduced to Cr (III).
Carcinogenicity
In addition to the many acute and chronic effects discussed in
preceeding sections, carcinogenicity of various Cr compounds has
been well documented, at least in man. A series of Cr compounds was
listed by the National Institute for Occupational Safety and Health
(1977) under the heading of suspected or identified carcinogens in
humans. Inclusion in this list was largely based on results of
animal experimentation. If, however, one excludes sarcoma produc-
tion at the site of implantation or injection of the suspected car-
C-23
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cinogen, the evidence for cancer production in experimental animals
is not convincing.
In spite of the demonstration that Cr compounds can cause
tumors at various sites in experimental animals, the only well-
documented evidence for cancers associated with Cr exposure of
humans involves the lungs. The relatively high incidence of lung
cancer in the chromate industry has been well documented (NAS,
1974) . Industrial exposure, as discussed below, greatly exceeds
that attributable to food, water, and air under normal conditions.
In considering the risks of pulmonary carcinogenesis in man, the
low systemic levels of Cr originating from the diet or from drink-
ing water can be ignored; unlike the pulmonary load of Cr, which
does not appear to be in equilibrium with other body stores of the
element (see Pharmacokinetic section), ingested Cr is poorly ab-
sorbed and presents no risks at normal ambient levels.
The primary emphasis in this field must be placed on the prob-
lems associated with pulmonary exposure; no evidence has been ad-
duced for an association in humans between Cr and initiation of
cancer at sites other than the lungs. The literature on respira-
tory cancer in humans up to 1950 has been reviewed by Baetjer
(1950): 109 cases had been reported up to that date in the chro-
mate-producing industry, and an additional 11 cases were reported
from chromate pigment plants. It seems likely that in all in-
stances Cr (VI) was involved in the effect. In any case, the inci-
dence of respiratory cancer among these work populations signifi-
cantly exceeded expected values.
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Further work on this subject after 1950 is considered in the
review prepared by the National Academy of Sciences (1974). Of
particular interest is the study of Taylor (1966) on a large group
of chromate workers who were followed over a period of 24 years on
the basis of records from the U.S. Social Security Administration.
Death rate from lung cancer in this group exceeded expected values
by a factor of 8.5. Excess incidence of all other cancers amounted
only to a factor of 1.3, in agreement with the conclusion stated
above that respiratory cancers constitute the major cancer risk
associated with Cr exposure in humans. Taylor further reported
that the age-adjusted death rate from respiratory cancer increased
with the period of exposure, a finding suggesting the existence of
a definite dose-response relationship. Little predictive use can
be made of this fact as no information on the concentration of
potential carcinogens in these studies was available.
An additional difficulty arises in attempts to interpret this
information because the specific carcinogen (or carcinogens) re-
sponsible for the increased incidence of cancer found in the chro-
mate industry has not been fully identified. Several compounds of
Cr are likely to be present in industrial surroundings. Further, a
significant portion of workers investigated must have been exposed
to other potential or actual carcinogens used in the chemical in-
dustry. Finally, the lung cancers observed in industry generally
resulted from prolonged exposure. Initial exposure levels are
often not known and the only information available refers to Cr
levels in air at the time of the final survey. All these factors
make it difficult to extract, from data on human subjects, conclu-
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sions concerning any significant relationship between degree of Cr
exposure and the incidence of lung cancer.
This problem may be illustrated in the work of Mancuso and
Hueper (1951). In this study an incidence of cancer of the respi-
ratory system of 66.7 percent of all cancers was observed, compared
with a figure of 11.4 percent in a control group. Details of the
six Cr workers concernedr with the addition of one worker who died
of respiratory cancer outside of the county and who was not includ-
ed in the above calculation, are shown in Table 1. As clearly
emerges from these data, lung cancer arises only after a prolonged
exposure and latency period (Bidstrup and Case, 1956). A second
point apparent from the table is that the reported levels of Cr in
air (average 0.74 mg Cr03/m ) were very high. These exposure
levels were calculated for each individual with adjustments for the
occupational history, and show that in each case the major exposure
involved water-insoluble Cr. However, the failure to separate
hexavalent and trivalent chromium leads to potentially serious
underestimations of the actual exposure values. The suggestion
that carcinogenicity in these cases could be attributed to Cr (III)
is probably not justified (U.S. PHS, 1953); this is further borne
out by more recent work with Cr (VI).
Thus, Davies (1978) reported that among workers exoosed to Zn
chromate in three British factories, an increased mortality due to
lung cancer was seen after an induction time as short as one year.
Concentrations of Cr, however, were not given. Similarly, Langard
and Norseth (1975) observed an increased cancer rate among workers
in a Zn chromate plant where no trivalent Cr was utilized. Pulmo-
C-26
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TABLE 1
Deaths Due to Lung Cancer in Chromate Workers*
Exposure Levels
(mg CrO3/m )
Subject
CB
TG
FJ
JK
EL
ESM
WDS
Mean
Years of
Exposure
9.0
14.5
12.5
7.5
9.2
2.0
7.2
8.8
Latent
Period
(years)
10.0
14.3
12.5
9.0
14.0
7.2
7.2
10.6
Water
Insoluble
0.37
0.37
0.19
0.92
1.12
0.19
1.12
0.61
Water
Soluble
0.17
0.08
0.02
0.29
0.15
0.02
0.15
0.13
Total
0.54
0.45
0.21
1.21
1.27
0.21
1.27
0.74
The exposure levels were calculated for each individual on the basis of his occupa-
tional history, and are expressed in terms of CrO-..
*Source: Mancuso and Hueper, 1951
027
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nary cancer was identified in three workers who had been exposed to
levels of 0.5 to 0.9 mg Cr/m for 6 to 9 years. In addition, a
single case of adenocystic carcinoma of the nasal cavity was also
reported. Attention must again be drawn to the fact that such
exposures involve Cr concentrations which are relatively massive
when compared to recommended standards (see Existing Guidelines and
Standards section). The standard for occupational exposure in air
mandates levels of poorly soluble mono- or dichromates not exceed-
ing 1 ug/m .
Attempts to produce lung cancers in experimental animals by
feeding or inhalation exposure to Cr compounds have not been suc-
cessful. For example, Ivankovic and Preussman (1975) fed Cr^O, at
0, 1, 2, and 5 percent of the diet to BD rats of both sexes for two
years. No carcinogenic effects were noted at any dose. Inhalation
did cause, however, a variety of pulmonary symptoms (Steffee and
Baetjer, 1965). Permitting animals to breathe air from a chromate
factory, 1 to 3 mg Cr/m , produced no bronchogenic carcinomas
(Baetjer, et al. 1959b). Nettesheim, et al. (1970) exposed mice to
Cr203 dust (25 mg/m ) for 5.5 hours per day, five times each week,
for as long as 18 months with similarly negative results. Distri-
bution and elimination of Cr from the lungs were affected by simul-
taneous infection of the animals with influenza virus. This under-
scores the importance of factors other than Cr itself in determin-
ing possible effects. In any case, not even the relatively oro-
longed retention of inhaled Cr in the lungs (see Inhalation sec-
tion) suffices to assure an inhalation exposure adequate for the
production of lung cancer under experimental conditions. Experi-
C-28
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mental lung tumors could only be observed following implantation of
pellets prepared from Cr (VI) compounds dispersed in an equal quan-
tity of cholesterol carrier (Laskin, et al. 1970) . As was already
stated above in reference to the data gathered in epidemiological
surveys of lung cancer in humans, such results do not lend them-
selves to the derivation of dose-effect relationships, nor to
extrapolation down to acceptable levels by a linear or any other
model.
In the very high concentrations employed for the experimental
production of cancer, compounds of Cr may also possess some cocar-
cinogenic properties. As illustrated by the observation of Lane
and Mass (1977), 2.5 mg of chromium carbonyl acted mildly synergis-
tically with 2.5 mg benzo(a)pyrene to produce carcinomas in trache-
al grafts in rats. No further reports on the possible cocarcinoge-
nicity of Cr compounds were found. It is conceivable, however,
that in the very high concentrations employed experimentally, other
Cr compounds might also possess cocarcinogenic properties. Espe-
cially likely in view of the recognized risks associated with smok-
ing is the probability that smoking increases the incidence of lung
cancer following pulmonary exposure to Cr.
C-29
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CRITERION FORMULATION
Existing Guidelines and Standards
A variety of standards have been recommended for permissible
Cr (VI) levels in water and air. Table 2 provides information on
standards presently established in the United States, as formulated
by various agencies. The high acceptable level of Cr in livestock
water is based on the poor absorption of Cr compounds in general
from the gut (see Ingestion section) . Because of this low frac-
tional absorption, and in view of the fact that the sensitivity of
the lungs to Cr appears to exceed that of other tissues, as dis-
cussed in the Carcinogenicity section, standards for Cr in air are
much lower than those for water.
Current Levels of Exposure
Although lower Cr limits have been prescribed for air than for
water, the standard for noncarcinogenic Cr (VI) in air permits sig-
nificantly greater uptake of Cr than does that for Cr (VI) in
drinking water designed for human consumption. Thus, if we assume
both a daily consumption of 2 liters and a fractional gastrointes-
tinal absorption of 5 percent, total uptake from that source would
amount to 5 yg/day. In contrast, the criteria discussed in the
Inhalation section, i.e., an alveolar ventilation of 20 m3/24 hours
with 50 percent alveolar retention of inhaled Cr, would lead to Cr
uptake through the lungs of around 80 yg during an 8-hour exposure
to levels of 25 yg/m . The upper limit for carcinogenic Cr (VI)
would similarly cause retention of 3 to 4 yg Cr under these condi-
tions .
C-30
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TABLE 2
Recommended or Established Standards for Cr in the United States
Medium
Drinking Water
Total
Domestic Water
Supply
Fresh Water
(aquatic life)
Livestock Water
Chemical
Species
Cr (VI)
total
chromium
total
chromium
Cr (VI)
Reference
U.S.
Rerv.
U.S.
U.S.
Natl.
Pub. Health
(1962)
EPA (1976)
EPA (1976)
Acad. Sci./
Standard
50 jjg/1
50 ug/1
100 ug/1
1 mg/1
Work Place
Air
carcinogenic
Cr (VT)a
noncarcino-
genic Cr (VI)
chromic and
chromous salts
metal and in-
soluble salts
Natl. Acad. Eng.
(1972)
Natl. Inst. Occup.
Safety and Health
(1975)c
Natl. Inst. Occup.
Safety and Health
(1975)c
40 CFR 1910.1000
40 CFR 1910.000
1 ug/m"
25 yg/nu TWAb
50 yg/m ceiling
0.5 mg/cu"
1.0 mg/cu"
Carcinogenic compounds are here taken to include all forms of Cr (VI) other than CrO-.
and mono- or dichromates of H, Li, Na, K, Rb, Cs/ and NH>
» *t
Time-weighted average
CNIOSH has recommended these criteria for Cr
C-31
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No minimum daily requirement for Cr has so far been agreed
upon. It is clear, however, that diet rather than water provides
the major fraction of daily Cr intake. As a consequence, small
absolute changes in water Cr levels should have little bearing on
Cr deficiency states.
For criterion derivation purposes, the distinction between Cr
(III) and Cr (VI) is justifiable. However, it should be understood
that analytical methods are not currently available to distinguish
between Cr (III) and Cr (VI) in dilute solutions in natural
matrices.
Special Groups at Risk
No such groups have been identified outside the occupational
environment.
Basis and Derivation of Criterion
Evidence suggests that inhaled hexavalent chromium [Cr (VI)]
is a human lung carcinogen. However, evidence for cancer produc-
tion in experimental animals from Cr (VI) is not convincing if one
excludes sarcoma production at the site of implantation or injec-
tion. Furthermore, the oral carcinogenicity of Cr (VI) or Cr (III)
has never been demonstrated. For example, two intermediate-length
oral feeding studies of Cr (VI), one in dogs for four years (Anwar,
et al. 1961) , the other in rats for one year (MacKenzie, et al.
1958) gave no evidence of carcinogenicity. Although these latter
studies did not specifically test for carcinogenicity and their
sample sizes were small, they are consistent with recent human epi-
demiological data that show no evidence of intestinal cancer after
inhalation exposure of Cr (VI) (Hayes, et al. 1980). Furthermore,
C-32
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existing oral carcinogenicity data for Cr (III) is negative (Ivan-
kovic and Preussmann, 1975), and recent data indicate that in the
presence of gastric juice, Cr (VI) is reduced to Cr (III) (Petrilli
and DeFlora, 1977, 1978; Gruber and Jinnette, 1978). Accordingly,
a protective limit for chromium based on carcinogenesis via inhala-
tion data is difficult to justify (see Appendix).
An alternative approach in establishing protective levels for
Cr (VI) and Cr (III) would be the derivation of criteria from tox-
icity data. A review of the toxicity data in the Effects section of
this document indicates that the MacKenzie, et al. (1958) study, in
which rats were fed various concentrations of Cr (VI) in their
drinking water for one year, is the most suitable study for this
calculation for Cr (VI). Although Gross and Heller (1946) utilized
higher levels of Cr (VI) in drinking water for several experimental
groups, the length of exposure was inadequate (i.e., less than 90
days) at levels producing no toxic effects. The Acceptable Daily
Intake (ADI) for rats in the MacKenzie, et al. (1958) study can be
found by:
(25.0 mg/1 x 0.035 l/d)/0.350 kg/rat = 2.50 mg/d/kg/rat,
where 25 mg/1 is a well defined no-observable-adverse-effeet level
(NOAEL), 0.035 1 represents the assumed average daily water intake
per rat, and 0.350 kg is the assumed average rat weight.
Dividing this ADI for rats by a safety factor of 1,000 accord-
ing to the methods previously described in the Federal Register
(Vol. 44, No. 52, March 15, 1979, P. 15980)* and then multiplying
*Note: This safety factor of 1,000 was chosen considering only
oral exposure data. Thus, evidence for carcinogenicity of Cr (VI)
or Cr (III) does not exist after oral exposure. Likewise, the
animal toxicity data after oral exposure to these valence states
are scanty.
C-33
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this by 70 kg (the average body weight of man) yields the "safe" ADI
for man:
(2.50 mg/d/kg/rat/1,000) x 70 kg/man = 0.175 mg/d/man.
The ambient water concentration of Cr (VI) cann be calculated
from this ADI for man by the following equation:
ADI mg/d/raan
C =
2 1/d/man + (0.0065 kg/d/man x BCF)
where BCF is the average bioconcentration factor for total chromium
of 16.0 in units of liters per kilograms, 2 1 represents the aver-
age daily water intake, and 0.0065 kg is the average amount of fish
consumed per day. Thus,
0.175 mg/d/man
C =
2 1/d/man + (0.0065 kg/d/man x 16.0 I/kg)
= 0.083 mg/1, or 83 yg/1.
A similar toxicity approach can be used to establish a protec-
tive level for Cr (III). Several studies are available that give
dose levels with no evidence of toxicity (NOAELs) : cats fed Cr
(III) at 50 to 1,000 mg/day (approximately 10 to 200 mg/kg/day) for
80 days (Akatsuka and Fairhall, 1934) ; rats fed 5 ppm of Cr (III) in
the diet for a lifetime (NAS, 1974); rats fed Cr (III) at 25 ppm via
drinking water for one year (MacKenzie, et al. 1958); or rats fed
Cr (III) five days a week at 2 or 5 percent of the diet for 90 days
or 1, 2, or 5 percent of the diet for two years (Ivankovic and
Preussmann, 1975). The latter study seems the most reasonable of
the four in terms of establishing a criterion; the Akatsuka and
Fairhall (1934) study is too short, while the dose levels of the
other two studies (NAS, 1974; MacKenzie, et al. 1958) are too low.
C-34
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The highest NOAEL in the Ivankovic and Preussmann (1975) study
is 5 percent of the diet or 50,000 ppm for Cr (III). The ADI for
rats in this study can be found by:
50fOOO ppm x 0.05 x (5/7) m 5flQ2 mg/d/kg,
0.350 £g
3
where 0.05 is assumed to be the daily feed consumption as a frac-
tion of body weight for a rat, 5/7 is an adjustment factor to derive
the average daily Cr (III) intake for a 7 rather than a 5-day week,
and 0.350 is the assumed average body weight of the rats.
Dividing this ADI for rats by a safety factor of 1,000 and
multiplying by 70 kg (the averge body weight of man) yields the ADI
for man:
(5,102 mg/d/kg/1,000) x 70 kg/man = 357 mg/d/man.
The ambient water concentration of Cr (III) that results in this
ADI for man can be found by:
_ _ 357 mg/d/man
2 1/d/man + (0.0065 kg/d/man x 16.0 I/kg)
= 170 mg/1.
The protective level based on animal toxicity data for Cr (VI)
agrees well with the present standard for total chromium permitted
in the domestic water supply: 50 yg/1 (U.S. EPA, 1976). This stan-
dard appears, through past experience, to be satisfactorily protec-
tive against Cr (VI) toxicity in humans, and has been approved by
several expert committees. Furthermore, a review of present ambi-
ent water chromium concentrations indicates that most waterways
contain this metal at concentrations below the present standard.
Therefore, the recommended ambient water quality criterion for Cr
(VI) is 50 pg/1.
C-35
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The protective level based on animal toxicity data for Cr
(III) and an uncertainty factor of 1,000, corresponding to an ADI
of 357 mg/d, is recommended as the ambient water quality criterion
for Cr (III): 170 mg/1. Drinking water contributes 95 percent of
the assumed exposure while eating contaminated fish products ac-
counts for 5 percent. This criterion can similarly be expressed as
3,433 mg/1 if exposure is assumed to be from the consumption of
fish and shellfish products alone. The amount of trivalent chromi-
um that can be expected to be present in ambient waters is extreme-
ly low because 1) Cr (III) is rapidly hydrolyzed and precipitated
as CrfOHK, and 2) sorption processes remove the remaining Cr (III)
from solution. It should be noted that the criterion value of 170
mg/1 far exceeds the Cr (III) concentration that can be expected in
ambient waters based upon known solubilities for Cr (III) and its
salts.
-------�
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C-46
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APPENDIX
Relationship Between Carcinogenicity Information and
Water Criterion for Chromium (VI)
Six epidemiological studies, five of which were at different
locations (Taylor, 1966; Enterline, 1974; Davies, 1978; Langord and
Horseth, 1975; Mancuso and Hueper, 1951; Baetjer, 1950), of up to
1,200 chromate workers strongly indicate that inhalation of Cr (VI)
produces lung cancer. These studies, supported by the production
of local carcinogenic responses in rats and hamsters at the site of
implantation or injection (Laskin, 1970) and the positive mutage-
nicity of Cr (VI) leave little doubt that Cr (VI) is a human carcin-
ogen. The extent to which ingested Cr (VI) induces cancer is not
clear, since it has not been well tested experimentally by the oral
route and since there is evidence, albeit uncertain, that Cr (VI)
is reduced to Cr (III) in the stomach. Because of these uncertain-
ties, no dose data for Cr (VI) exist on which to base a quantitative
risk estimmate of oral carcinogenicity. Therefore, the criterion
concentration for Cr (VI) of 50 yg/1, based on its toxicity, should
be regarded as a strict upper limit; it does not include any con-
sideration of the carcinogenicity of Cr (VI).
* U. S. GOVERNMENT PRINTING OFFICE : 19BO 720-016/4360
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