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Notice of Filing of Pesticide Petitions
Note: EPA no longer updates this information, but it may be useful as a reference or resource.
[Federal Register: March 10, 1999 (Volume 64, Number 46)]
[Notices]
[Page 11874-11879]
From the Federal Register Online via GPO Access [wais.access.gpo.gov]
[DOCID:fr10mr99-80]
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ENVIRONMENTAL PROTECTION AGENCY
[PF-862; FRL-6063-3]
Notice of Filing of Pesticide Petitions
AGENCY: Environmental Protection Agency (EPA).
ACTION: Notice.
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SUMMARY: This notice announces the initial filing of pesticide
petitions proposing the establishment of regulations for residues of
certain pesticide chemicals in or on various food commodities.
DATES: Comments, identified by the docket control number PF-862, must
be received on or before April 9, 1999.
ADDRESSES: By mail submit written comments to: Information and Records
Integrity Branch, Public Information and Services Divison (7502C),
Office of Pesticides Programs, Environmental Protection Agency, 401 M
St., SW., Washington, DC 20460. In person bring comments to: Rm. 119,
CM #2, 1921 Jefferson Davis Highway, Arlington, VA.
Comments and data may also be submitted electronically by following
the instructions under ``SUPPLEMENTARY INFORMATION.'' No confidential
business information should be submitted through e-mail.
Information submitted as a comment concerning this document may be
claimed confidential by marking any part or all of that information as
``Confidential Business Information'' (CBI). CBI should not be
submitted through e-mail. Information marked as CBI will not be
disclosed except in accordance with procedures set forth in 40 CFR part
2. A copy of the comment that does not contain CBI must be submitted
for inclusion in the public record. Information not marked confidential
may be disclosed publicly by EPA without prior notice. All written
comments will be available for public inspection in Rm. 119 at the
address
[[Page 11875]]
given above, from 8:30 a.m. to 4 p.m., Monday through Friday, excluding
legal holidays.
FOR FURTHER INFORMATION CONTACT: Mary L. Waller, Fungicide Branch,
Registration Division (7505C), Office of Pesticide Programs,
Environmental Protection Agency, 401 M St., SW, Washington, DC 20460.
Office location, telephone number, and e-mail address: Rm. 249, Crystal
Mall #2, 1921 Jefferson Davis Highway, Arlington, VA 22202, (703) 305-
6117; e-mail:waller. mary@epamail.epa.gov.
SUPPLEMENTARY INFORMATION: EPA has received a pesticide petition as
follows proposing the establishment and/or amendment of regulations for
residues of certain pesticide chemical in or on various food
commodities under section 408 of the Federal Food, Drug, and Comestic
Act (FFDCA), 21 U.S.C. 346a. EPA has determined that this petition
contains data or information regarding the elements set forth in
section 408(d)(2); however, EPA has not fully evaluated the sufficiency
of the submitted data at this time or whether the data supports
granting of the petition. Additional data may be needed before EPA
rules on the petition.
The official record for this notice of filing, as well as the
public version, has been established for this notice of filing under
docket control number [PF-862] (including comments and data submitted
electronically as described below). A public version of this record,
including printed, paper versions of electronic comments, which does
not include any information claimed as CBI, is available for inspection
from 8:30 a.m. to 4 p.m., Monday through Friday, excluding legal
holidays. The official record is located at the address in
``ADDRESSES'' at the beginning of this document.
Electronic comments can be sent directly to EPA at:
opp-docket@epamail.epa.gov
Electronic comments must be submitted as an ASCII file avoiding the
use of special characters and any form of encryption. Comment and data
will also be accepted on disks in Wordperfect 5.1/6.1 file format or
ASCII file format. All comments and data in electronic form must be
identified by the docket control number [PF-862] and appropriate
petition number. Electronic comments on this notice may be filed online
at many Federal Depository Libraries.
List of Subjects
Environmental protection, Agricultural commodities, Food additives,
Feed additives, Pesticides and pests, Reporting and recordkeeping
requirements.
Dated: February 22, 1999.
James Jones,
Director, Registration Division, Office of Pesticide Programs.
Summary of Petition
The petitioner summaries of the pesticide petitions are printed
below as required by section 408(d)(3) of the FFDCA. The summary of
each petition was prepared by the petitioner and represents the views
of the petitioner. EPA is publishing the petition summaries verbatim
without editing them in any way. The petition summary announces the
availability of a description of the analytical methods available to
EPA for the detection and measurement of the pesticide chemical
residues or an explanation of why no such method is needed.
1. American Cyanamid Company
PP 7F4816
EPA has received a pesticide petition (PP 7F4816) from American
Cyanamid Company, P.O. Box 400 Princeton, NJ 08543-0400 proposing,
pursuant to section 408(d) of the Federal Food, Drug, and Cosmetic Act
(FFDCA), 21 U.S.C. 346a(d), to amend 40 CFR part 180 by establishing a
tolerance for residues of dimethomorph, (E,Z)4-[3-(4-chlorophenyl)-3-
(3,4-dimethoxyphenyl)-1-oxo-2-propenyl]morpholine in or on the raw
agricultural commodity cereal grains (Crop Group 15) and forage of
cereal grain crops (Crop Group 16) at 0.05 parts per million (ppm) and
fodder and straw of cereal grain crops (Crop Group 16) at 0.10 ppm. EPA
has determined that the petition contains data or information regarding
the elements set forth in section 408(d)(2) of the FFDCA; however, EPA
has not fully evaluated the sufficiency of the submitted data at this
time or whether the data supports granting of the petition. Additional
data may be needed before EPA rules on the petition.
A. Residue Chemistry
1. Plant metabolism. The metabolism of dimethomorph in plants is
adequately understood for the purposes of these tolerances. A
rotational crop study showed the potential for indirect or inadvertent
residues of dimethomorph in or on commodities of cereal crops.
2. Analytical method. There is a practical method for measuring
0.050 ppm of dimethomorph in or on commodities of cereal crops. This
gas chromatography method with nitrogen-phosphorus detection (M3112) is
appropriate for enforcement purposes. Confirmation of residues is
provided by liquid chromatography/mass spectroscropy of the final
extract of this method.
3. Magnitude of residues. The magnitude of residue studies were
conducted for wheat as a rotational crop to potatoes treated at 1.4 x
the maximum labeled rate. Residues found in these studies were below
the level of quantitation (LOQ) in the forage and grain samples from
all six trials and in the hay, and straw samples from four of the
trials. The maximum observed residue (sample means) was 0.057 ppm for
hay, and 0.086 ppm for straw for the other two trials. Therefore, at
the maximum labeled rate, residues of dimethomorph in or on hay are
expected to be below the LOQ (< 0.05 ppm) and residues in or on straw
are expected to be less than 0.10 ppm.
B. Toxicological Profile
1. Acute toxicity. An acute oral toxicity study in the Sprague-
Dawley rat for dimethomorph technical with a LD<INF>50</INF> of 4,300
milligram per kilogram bodyweight (mg/kg bwt) for males and 3,500 mg/kg
bwt for females. Based upon EPA toxicity criteria, the acute oral
toxicity category for dimethomorph technical is Category III or
slightly toxic. Oral LD<INF>50</INF> studies were conducted on the two
isomers (E and Z) alone: An acute oral toxicity study in the Wistar rat
for the E-isomer with a LD<INF>50</INF> greater than 5,000 mg/kg bwt
for males and approximately 5,000 mg/kg bwt for females. An acute oral
toxicity study in the Wistar rat for the Z-isomer with a
LD<INF>50</INF> greater than 5,000 mg/kg bwt for both males and
females. An acute dermal toxicity study in the Wistar rat for
dimethomorph technical with a dermal LD<INF>50</INF> greater than 5,000
mg/kg bwt for both males and females. Based on the EPA toxicity
category criteria, the Acute dermal toxicity category for dimethomorph
is Category IV or relatively non-toxic. A 4-hour inhalation study in
Wistar rats for dimethomorph technical with a LC<INF>50</INF> greater
than 4.2 milligram per liter (mg/L) for both males and females. Based
on the EPA toxicity category criteria, the acute inhalation toxicity
category for dimethomorph technical is Category IV or relatively non-
toxic.
2. Genotoxicty. Salmonella reverse gene mutation assays (2 studies)
were negative up to a limit dose of 5,000 <greek-m>g/plate. Chinese
hamster lung cells were negative in V79 cells up to toxic doses in 2
studies. Two Chinese hamster lung structural chromosomal studies were
[[Page 11876]]
reportedly positive for chromosomal aberrations at the highest dose
tested (HDT) (160 <greek-m>g/ml/-S9; 170 <greek-m>g/ml/+S9).
Dimethomorph induced only a weak response in increasing chromosome
aberrations in this test system. These results were not confirmed in
two micronucleus tests under in vivo conditions. Structural Chromosomal
Aberration studies were weakly positive, in human lymphocyte cultures,
but only in S9 activated cultures treated at the HDT (422 <greek-m>g/
ml) which was strongly cytotoxic. Dimethomorph was negative in the
absence of activation at all doses and the positive in human lymphocyte
cultures was only in S9 activated cultures treated at the HDT (422
<greek-m>g/ml) which was strongly cytotoxic. Dimethomorph was negative
in the absence of activation at all doses and the positive clastogenic
response observed under the in vitro conditions was not confirmed in
two in vivo micronucleus assays. Micronucleus assay (2 studies)
indicated that dimethomorph was negative for inducing micronuclei in
bone marrow cells of mice following i.p. administration of doses up to
200 mg/kg or oral doses up to the limit dose of 5,000 mg/kg. Thus,
dimethomorph was found to be negative in these studies for causing
cytogenic damage in vivo. Dimethomorph was negative for inducing
unscheduled DNA synthesis in cultured rat liver cells at doses up to
250 <greek-m>/ml, a weak cytotoxic level. Dimethomorph was negative for
transformation in Syrian hamster embryo cells treated in the presence
and absence of activation up to cytotoxic concentrations (265
<greek-m>g/ml/+S9; 50 <greek-m>g/ml-S9).
3. Reproductive and developmental toxicity. A rat developmental
toxicity study with a maternal toxicity lowest-observed-adverse-effect
Level (LOAEL) of 160 mg/kg/day and a maternal toxicity no-observed
adverse-effect level (NOAEL) of 60 mg/kg/day. The NOAEL for
developmental toxicity is 60 mg/kg/day. Dimethomorph is not teratogenic
in the Sprague-Dawley rat. A rabbit development toxicity study with
parental LOAEL for systemic toxicity of 80 mg/kg/day, and a NOAEL of 24
mg/kg/day. The NOAEL for fertility and reproductive function was 80 mg/
kg/day, the HDT.
4. Subchronic toxicity A 90-day dog dietary study in Sprague-Dawley
rats with a NOAEL of greater than or equal to 73 mg/kg/day in males and
82 mg/kg/day in females, the HDT. A 90-day dog dietary study with a
NOAEL 15 mg/kg/day, and a LOAEL of 43 mg/kg/day.
5. Chronic toxicity. A 2-year oncogenicity study in Sprague-Dawley
rats with a NOAEL for systemic toxicity of 9 mg/kg/day for males and 12
mg/kg/day for females. The LOAEL for systemic toxicity is 36 mg/kg/day
for males and 58 mg/kg/day for females. A 1-year chronic toxicity study
in dogs with a NOAEL of 14.7 mg/kg/day and a LOAEL of 44.6 mg/kg/day. A
2-year oncogenicity study in Sprague-Dawley rats with a NOAEL for
systemic toxicity of 9 mg/kg/day for males and 11 mg/kg/day for
females. The LOAEL for system toxicity was 34 mg/kg/day for males and
46 mg/kg/ day for females. There was no evidence of increased incidence
of neoplastic lesions in treated animals. The NOAEL for oncogenicity is
95 mg/kg/day for males and 132 mg/kg/day for females, the HDT. A 2-year
oncogenicity study in mice with a NOAEL for systemic toxicity of 100
mg/kg/day, and LOAEL of 1,000 mg/kg/day. There was no evidence of
increased incidence of neoplastic lesions in treated animals. The NOAEL
for oncogenicity is 1,000 mg/kg/day, the HDT.
6. Animal metabolism. Results from livestock and rat metabolism
studies show that orally administered dimethomorph was rapidly excreted
by the animals. The principal route of elimination is the feces.
7. Metabolite toxicology. There were no metabolites identified in
plant or animal commodities which require regulation.
8. Endocrine disruption. There is no evidence of effects of
dimethomorph on the endocrine system. There were no changes noted in
organ weights for the pituitary, thyroid, ovaries or testes. There was
no increased incidence of mammary tumors observed. No effects on
fertility or reproduction were noted and there was no evidence of
related histopathological changes in reproductive or endocrine system
organs.
C. Aggregate Exposure
1. Dietary exposure. Dietary exposure should be based upon the
Theoretical Maximum Residue Concentration (TMRC) from the established
tolerances for residues of dimethomorph at 0.05 ppm in or on potato;
for the proposed tolerances for residues of dimethomorph at 2.0 ppm in
or on grapes; and 0.15 ppm on potatoes wet peel; for the proposed
tolerances for indirect and inadvertent residues of dimethomorph at
0.05 ppm in or on cereal grains, and in or on fodder and straw of
cereal grain crops, and from the time-limited tolerances (i.e. at 1.0
ppm for cantaloupes, cucumbers, squash, and watermelons) which were
established under Section 18 emergency exempt ions and which are not
due to expire at or near completion of this regulatory action.
i. Food. The goat and poultry metabolism studies demonstrate that
there is no reasonable expectation of transfer of residues to meat,
milk, poultry, or eggs from potato, grape, and cereal crop commodities.
Therefore, no consumption data associated with meat, milk, poultry or
eggs should be included in the calculation of the TMRC. Except for the
permanent tolerances on potato tubers, there are no other permanent
U.S. tolerances for dimethomorph.
ii. Drinking water. The predicted dimethomorph surface and ground
water concentrations are well below the drinking water level of
concern. Using the SCI-GROW model to generate the Estimated
Environmental Concentration (EEC) of dimethomorph residues in ground
water, the projected EEC is 0.26 parts per billion (ppb). Using the
Generic Estimated Environmental Concentration (GENEEC) model to
estimate acute and chronic EECs of dimethomorph residues in surface
water, the projected EEC ranged from a peak of 28 ppb to a 56 day
concentration of 24 ppb. The level of concern for chronic exposure to
residues of dimethomorph range from 960 ppb for children 1-6 years old
to 3,400 ppb for the U.S. population and males 13 years and older.
Therefore, American Cyanamid believes that exposure from water is below
the level of concern for all of the populations examined. In addition,
American Cyanamid believes that the aggregate (food, and water) chronic
exposure for infants, children, and adults does not exceed the level of
concern and adverse health effects from chronic exposure to
dimethomorph in food, and water are not expected in these populations.
2. Non-dietary exposure. In the United States, dimethomorph is
registered only for use on potatoes. Thus, there is no potential for
non-dietary exposure.
D. Cumulative Effects
There is no information to indicate that any toxic effects produced
by dimethomorph would be cumulative with those of any other chemical.
The fungicidal mode of action of dimethomorph is unique; dimethomorph
inhibits cell wall formation only in Oomycete fungi. The result is
lysis of the cell wall which kills growing cells and inhibits spore
formation in mature hyphae. This unique mode of action and limited pest
spectrum suggest that there is little or no potential for cumulative
toxic effects in mammals. In addition, the toxicity studies submitted
to support this
[[Page 11877]]
petition do not indicate that dimethomorph is a particularly toxic
compound.
E. Safety Determination
1. U.S. population. The established reference dose (RfD) is 0.1 mg/
kg bwt/day, based on a NOAEL of 10 mg/kg bwt/day from a 2-year dietary
toxicity study in rats that demonstrated decreased bwt, and liver foci
in females. The established RfD is also based on an uncertainty factor
of 100. The TMRC from the established tolerances for residues in or on
potato along with the current Section 18 time-limited tolerances
(cantaloupes, watermelons, cucumbers, and squash, as well as expiring
tolerances for tomato commodities) utilizes less than 4% of the RfD for
all population subgroups. The TMRC for grapes and cereal grains is not
expected to cause the RfD to be exceeded.
2. Infants and children. American Cyanamid believes that the
results of the studies submitted to support this package provide no
evidence that dimethomorph caused reproductive, developmental or
fetotoxic effects. No such effects were noted at dose levels which were
not maternally toxic. The NOAELs observed in the developmental and
reproductive studies were 6 to 65 times higher than the NOAEL (10 mg/kg
bwt/day) used to establish the RfD. There is no evidence to indicate
that children or infants would be more sensitive than adults to toxic
effects caused by exposure to dimethomorph.
F. International Tolerances
No Codex maximum residue levels (MRLs) have been established for
dimethomorph to date.
2. BASF Corporation
PP 7F4880
EPA has received a pesticide petition (7F4880) from BASF
Corporation, 26 Davis Drive, Post Office Box 13528, Research Triangle
Park, North Carolina 27709-3528, proposing pursuant to section 408(d)
of the Federal Food, Drug, and Cosmetic Act (FFDCA), 21 U.S.C. 346a(d),
to amend 40 CFR part 180 by establishing a tolerance for combined
residues of kresoxim-methyl (methyl (E)-2-methoxyimino-2-[2-(o-
tolyloxymethyl) phenyl] acetate) and the glycoside conjugates of its
metabolites 2-[o-(o-hydroxymethylphenoxymethyl) phenyl]-2-
(methoxyimino) acetic acid and 2-[o-(p-hydroxy-o-methylphenoxymethyl)
phenyl]-2-(methoxyimino) acetic acid in or on the raw agricultural
commodities pome fruit, grapes and pecans at 0.30 parts per million
(ppm) for pome fruit, 1.0 ppm for grapes, 0.15 ppm for pecans and 0.70
ppm for apple pomace. EPA has determined that the petition contains
data or information regarding the elements set forth in section
408(d)(2) of the FFDCA; however, EPA has not fully evaluated the
sufficiency of the submitted data at this time or whether the data
supports granting of the petition. Additional data may be needed before
EPA rules on the petition.
A. Residue Chemistry
1. Plant metabolism. BASF Corporation notes that metabolism in
plants is understood.
2. Analytical method. The proposed analytical method involves
extraction, enzyme hydrolysis, partition, clean-up and detection of
residues by high performance liquid chromotography using ultra-violet
(HPLC/UV) detection.
3. Magnitude of residues. Twelve grape residue trials were
conducted in six States. Residues of kresoxim-methyl and its two
metabolites were measured by HPLC/UV. The analytical method had a limit
of detection (LOD) of 0.05 ppm for each of the three analytes. Residues
ranged from < 0.15 ppm to 0.79 ppm.
Nineteen apple residue trials were conducted in 12 States. Residues
of kresoxim-methyl and its two metabolites were measured by HPLC/UV.
The analytical method had a LOD of 0.05 ppm for each of the three
analytes. Residue of parent and metabolites ranged from < 0.15 to 0.23
ppm.
Eight pear residue trials were conducted in five States. Residues
of kresoxim-methyl and its two metabolites were measured by HPLC/UV.
The analytical method had a LOD of 0.05 ppm for each of the three
analytes. Residues of parent plus metabolites ranged from < 0.15 to
0.26 ppm.
Six pecan residue trials were conducted in five States. Residues of
kresoxim-methyl and its two metabolites were measured by HPLC/UV. The
analytical method had a LOD of 0.05 ppm for each of the three analytes.
No residue of parent or metabolites was found in any sample above the
LOD.
B. Toxicological Profile
1. Acute toxicity--Acute/subchronic toxicology. Based on available
acute toxicity data, kresoxim-methyl does not pose any acute toxicity
risks. Acute toxicology studies place technical-grade kresoxim-methyl
in Toxicity Category IV for acute oral and Category III for acute
dermal and acute inhalation toxicity. The material is not an eye
irritant, a primary dermal irritant or a skin sensitizer. Additionally,
in acute and subchronic neurotoxicity studies, kresoxim-methyl did not
show any signs of neurotoxicity at dose levels up to and including
2,000, and 1,267 milligram/kilogram/day (mg/kg/day), respectively.
2. Genotoxicty. With regard to the liver tumors, kresoxim-methyl is
not a genotoxic agent and is not an initiator of the carcinogenic
process. The increased incidence of liver tumors in rats is the result
of liver tumor promoting properties of the test substance.
3. Reproductive and developmental toxicity--i. Reproductive
toxicity. The 2-generation reproduction study with rats resulted in a
reproductive no-observed adverse effect level (NOAEL) of 1,625 mg/kg/
day, and a maternal NOAEL of 100 mg/kg/day. These NOAEL values are
significantly higher than the NOAEL from the 2 year feeding study in
rats used to establish the reference dose (RfD).
ii. Developmental toxicity. The teratogenicity study in rats
resulted in a developmental toxicity NOAEL of 1,000 mg/kg/day, and a
maternal toxicity NOAEL of 1,000 mg/kg/day. These NOAEL values are
significantly higher than the NOAEL from the 2 year feeding study in
rats used to establish the RfD.
4. Subchronic toxicity--i. Acute/subchronic toxicology. Based on
available acute toxicity data, kresoxim-methyl does not pose any acute
toxicity risks. Acute toxicology studies place technical-grade
kresoxim-methyl in Toxicity Category IV for acute oral and Category III
for acute dermal and acute inhalation toxicity. The material is not an
eye irritant, a primary dermal irritant or a skin sensitizer.
Additionally, in acute and subchronic neurotoxicity studies, kresoxim-
methyl did not show any signs of neurotoxicity at dose levels up to and
including 2,000 and 1,267 mg/kg/day, respectively.
ii. Subchronic toxicology--a. Teratology - Rat. A teratogenicity
study in the rat with doses at 100, 400, and 1,000 mg/kg/day by gavage
was performed with a maternal NOAEL of 1,000 mg/kg/day and fetal NOAEL
of 1,000 mg/kg/day.
b. Teratology - Rabbits. A teratogenicity study in the rabbit with
doses at 100, 400, and 1,000 mg/kg/day by gavage was performed with a
maternal NOAEL of 1,000 mg/kg/day and fetal NOAEL of 1,000 mg/kg/day.
c. Mutagenicity. Modified Ames Test (2 studies; point mutation):
Negative; In Vitro chinese hamster ovary hypoxanthine guanine
phophoribosyl transferase (CHO/HGPRT) (point
[[Page 11878]]
mutation): Negative; In Vitro Cytogenetics Chromosome Damage Human
Lymphocytes: Negative; In Vivo Chromosome Mouse Micronucleus: Negative;
In Vitro DNA Damage & Repair Rat Hepatocytes: Negative; UDS ex Vivo DNA
Damage & Repair Wistar Rats (Single Oral Dose): Negative; UDS ex Vivo
DNA Damage & Repair Wistar Rats (3 Week Feeding): Negative.
5. Chronic toxicity--i. Threshold effects. Based on review of the
available data, BASF believes the RfD for kresoxim-methyl will be based
on the 2 year feeding study in rats with a threshold NOAEL of 36 mg/kg/
day in males, and 47 mg/kg/day in females. Using an uncertainty factor
of 100, the RfD is calculated to be 0.36 mg/kg/day.
ii. Non-threshold effects - carcinogenicity. Kresoxim-methyl was
shown to be non-carcinogenic in mice. In the rat carcinogenicity study,
a statistically significant increase in liver tumors was observed in
both male and female animals at 370 and 746 mg/kg/day, and 503 and 985
mg/kg/day dose levels, respectively. Kresoxim-methyl is not a genotoxic
agent and mechanistic studies have shown that the increased incidence
of liver tumors in rats is the result of liver tumor promoting
properties of the test substance. Kresoxim-methyl is not an initiator
of the carcinogenic process. Based on the available data, the mechanism
of promotion is the induction of liver cell proliferation of the test
substance. The data available also indicate that dose levels which do
not induce liver toxicity neither induce cell proliferation nor enhance
the carcinogenic process. Therefore, a threshold for liver
carcinogenicity in rats can be defined to be approximately 40 mg/kg/
day.
Based on the results of the carcinogenicity study in mice, the
results of genotoxicity testing, the results of the 24 month chronic
feeding/oncogenicity study in rats; and auxiliary mechanistic data
showing that kresoxim-methyl is not an initiator of the carcinogenic
process, BASF believes that the threshold approach to regulating
kresoxim-methyl is appropriate.
C. Toxicity Data Supporting Kresoxim-methyl Tolerances
1. Chronic feeding--i. Nonrodent. A 12 month feeding study in the
dog with doses of 29, 142, and 738 mg/kg/day was performed with a NOAEL
of 138 mg/kg/day for males, and 761 mg/kg/day for females. The only
effect observed was reduced body weights (bwt) in male dogs at the
highest dose tested (HDT).
ii. Chronic feeding/oncogenicity - Rats. A 24 month chronic
feeding/oncogenicity study in the rat with doses at 9, 36, 370, and 746
mg/kg/day for males and 12, 48, 503, and 985 mg/kg/day for females was
performed with a NOAEL of 36 mg/kg/day in males, and 47 mg/kg/day in
females. Reduced bwt changes were observed in male, and female rats in
the highest two dose groups. Histopathologically, changes in the liver
were observed in either or both of the highest two dose groups for
male, and female rats. These changes consisted of increased liver
weight, increased hepatocellular hypertrophy, increased incidence and
severity of eosinophilic foci of hepatocellular alterations, and
increased incidence and degree of severity of bile duct proliferation.
Associated with the liver, an increase of serum-gamma-
glutamyltransferase values was observed. A statistically significant
increase in liver tumors was observed in both male, and female animals
at 370 mg/kg/day and 985 mg/kg/day, respectively. With regard to the
liver tumors, kresoxim-methyl is not a genotoxic agent and is not an
initiator of the carcinogenic process. The increased incidence of liver
tumors in rats is the result of liver tumor promoting properties of the
test substance. Based on the available data, the mechanism of promotion
is the induction of liver cell proliferation of the test substance. The
data available also indicate that dose levels which do not induce liver
toxicity neither induce cell proliferation nor enhance the carcinogenic
process. Therefore, a threshold for liver carcinogenicity in rats can
be defined to be approximately 40 mg/kg/day.
iii. Oncogenicity - Mice. A mouse oncogenicity study using dosage
levels at 60, 304, and 1,305 mg/kg/day for males, and 81, 410, and
1,662 mg/kg/day for females was performed with a NOAEL of 304 mg/kg/day
for males, and 81 mg/kg/day for females, with no evidence of
oncogenicity. Bwt changes were observed in both male, and female mice
in the highest dose group and only in the females in the 410 mg/kg/day
group. Histopathology was limited only to the highest dose group and
consisted of increased incidence of renal papillary necrosis for both
male, and female mice and increased incidence and higher degree of
severity of liver amyloidosis in females only.
iv. 2-Generation reproduction - Rats. A 2-generation reproductive
study in the rat with doses at 5, 100, 407, and 1,625 mg/kg/day was
performed with a NOAEL of 100 mg/kg/day for parental and developmental
toxicity, and a NOAEL of 1,625 mg/kg/day for reproduction toxicity.
Decreased body weight was seen in both the pups and parents. Reduced
serum-gamma-glutamyltransferase was seen in F0 males and both sexes of
the F1 generation, and reduced kidney weights were seen in the F1
generation at the 407 and 1,625 mg/kg/day dose levels. Decreased fat
storage was observed in F0 and F1 male livers at the 407 and 1,625 mg/
kg/day dose levels.
6. Animal metabolism. BASF Corporation notes that metabolism in
animals is understood.
D. Aggregate Exposure
1. Dietary exposure. For purposes of assessing the potential
chronic dietary exposure, BASF has estimated aggregate exposure based
on the Theoretical Maximum Residue Contribution (TMRC) from the
proposed tolerance for kresoxim-methyl on pome fruit at 0.30 ppm,
grapes at 1.0 ppm, and pecans at 0.15 ppm. The TMRC is a ``worse case''
estimate of dietary exposure since it is assumed that 100% of all crops
for which tolerances are established are treated and that pesticide
residues are always found at the tolerance levels.
i. Food. Dietary exposure to residues of kresoxim-methyl in or on
food will be limited to residues on pome fruit, grapes, and pecans.
Apple pomace is fed to animals; thus exposure of humans to residues in
apple pomace might result if such residues carry through to meat, milk,
poultry, or eggs. However, BASF has concluded that there is no
reasonable expectation that measurable residues of kresoxim-methyl will
occur in meat, milk, poultry, or eggs from this use. There are no other
established U.S. tolerances for kresoxim-methyl, and there are no
currently registered uses for kresoxim-methyl on food or feed crops in
the U.S.
Dietary exposure to residues of kresoxim-methyl from the proposed
tolerances on pome fruit, grapes, and pecans would account for less
than 0.15% of the RfD (.36 mg/kg/day) for the general population of the
U.S. The most highly exposed group in the subpopulation groups would be
non-nursing infants < 1 year old, which uses 0.88% of the RfD.
ii. Drinking water. Other potential sources of exposure for the
general population to residues of kresoxim-methyl are residues in
drinking water and exposure from non-occupational sources. Based on the
available studies, BASF does not anticipate exposure to residues of
kresoxim-methyl in drinking water. There is no established Maximum
Concentration Level (MCL) for residues of kresoxim-methyl in
[[Page 11879]]
drinking water under the Safe Drinking Water Act (SDWA).
2. Non-dietary exposure. Kresoxim-methyl is currently registered
for use in greenhouses on ornamental plants. The potential for non-
occupational exposure to the general population is not significant.
E. Cumulative Effects
BASF has considered the potential for cumulative effects of
kresoxim-methyl and other substances that have a common mechanism of
toxicity. No evidence or information exists to suggest that toxic
effects produced by kresoxim-methyl would be cumulative with those of
any other chemical compound.
F. Safety Determination
1. U.S. population. Using the conservative exposure assumptions
described above and based on the completeness and the reliability of
the toxicity data, BASF has estimated that aggregate exposure to
kresoxim-methyl will utilize less than 0.15% of the RfD for the total
U.S. population. BASF concludes that there is a reasonable certainty
that no harm will result from the aggregate exposure to residues of
kresoxim-methyl, including anticipated dietary exposure and non-
occupational exposures.
2. Infants and children--i. Developmental toxicity. The
teratogenicity study in rats resulted in a developmental toxicity NOAEL
of 1,000 mg/kg/day, and a maternal toxicity NOAEL of 1,000 mg/kg/day.
These NOAEL values are significantly higher than the NOAEL from the 2
year feeding study in rats used to establish the RfD.
The teratogenicity study in rabbits resulted in a developmental
toxicity NOAEL of 1,000 mg/kg/day, and a maternal toxicity NOAEL of
1,000 mg/kg/day. These NOAEL values are significantly higher than the
NOAEL from the 2 year feeding study in rats used to establish the RfD.
ii. Reproductive toxicity. The 2-generation reproduction study with
rats resulted in a reproductive NOAEL of 1,625 mg/kg/day, and a
maternal NOAEL of 100 mg/kg/day. These NOAEL values are significantly
higher than the NOAEL from the 2 year feeding study in rats used to
establish the RfD.
iii. Reference Dose. Since developmental and reproductive toxicity
occurs at levels at or above the levels shown to exhibit parental
toxicity and since these levels are significantly higher than those
used to calculate the RfD, BASF believes the RfD of 0.36 mg/kg/day is
an appropriate measure of safety for infants and children.
Using the conservative exposure assumptions described above, BASF
has concluded that the portion of the RfD that will be utilized by
aggregate exposure to residues of kresoxim-methyl resulting from the
proposed tolerances will be less than 1% for all populations of infants
and children. The most highly exposed group in the subpopulation groups
would be non-nursing infant < 1-year old, which uses 0.88% of the RfD.
Therefore, based on the completeness and reliability of the toxicity
data and the conservative exposure assessment, BASF concludes that
there is a reasonable certainty that no harm will result to infants and
children from aggregate exposure to the residues of kresoxim-methyl,
including all anticipated dietary exposure and all other non-
occupational exposures.
G. International Tolerances
A maximum residue level has not been established for kresoxim-
methyl by the Codex Alimentarius Commission.
[FR Doc. 99-5823 Filed 3-9-99; 8:45 am]
BILLING CODE 6560-50-F