Provisional Peer-Reviewed Toxicity Values for tert-Butyl Formate (CASRN 762-75-4)


£%	United States
Environmental Protection
M % Agency
EPA/690/R-17/011
FINAL
09-27-2017
Provisional Peer-Reviewed Toxicity Values for
tert-Butyl Formate
(CASRN 762-75-4)
Superfund Health Risk Technical Support Center
National Center for Environmental Assessment
Office of Research and Development
U.S. Environmental Protection Agency
Cincinnati, OH 45268

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AUTHORS, CONTRIBUTORS, AND REVIEWERS
CHEMICAL MANAGER
Jeffry L. Dean II, PhD
National Center for Environmental Assessment, Cincinnati, OH
DRAFT DOCUMENT PREPARED BY
SRC, Inc.
7502 Round Pond Road
North Syracuse, NY 13212
PRIMARY INTERNAL REVIEWERS
Scott C. Wesselkamper, PhD
National Center for Environmental Assessment, Cincinnati, OH
Dan D. Petersen, PhD, DABT
National Center for Environmental Assessment, Cincinnati, OH
This document was externally peer reviewed under contract to:
Eastern Research Group, Inc.
110 Hartwell Avenue
Lexington, MA 02421-3136
Questions regarding the content of this PPRTV assessment should be directed to the EPA Office
of Research and Development's National Center for Environmental Assessment, Superfund
Health Risk Technical Support Center (513-569-7300).
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TABLE OF CONTENTS
COMMONLY USED ABBREVIATIONS AND ACRONYMS	iv
BACKGROUND	1
DISCLAIMERS	1
QUESTIONS REGARDING PPRTVs	1
INTRODUCTION	2
REVIEW OF POTENTIALLY RELEVANT DATA (NONCANCER AND CANCER)	5
OTHER DATA (SHORT-TERM TESTS, OTHER EXAMINATIONS)	5
Acute Animal Studies	5
DERIVATION 01 PROVISIONAL VALUES	6
DERIVATION 01 ORAL REFERENCE DOSES	6
DERIVATION OF INHALATION REFERENCE CONCENTRATIONS	7
CANCER WEIGHT-OF-EVIDENCE DESCRIPTOR	7
DERIVATION OF PROVISIONAL CANCER POTENCY VALUES	7
APPENDIX A. SCREENING PROVISIONAL VALUES	8
APPENDIX B. REFERENCES	29
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COMMONLY USED ABBREVIATIONS AND ACRONYMS1
a2u-g
alpha 2u-globulin
MN
micronuclei
ACGIH
American Conference of Governmental
MNPCE
micronucleated polychromatic

Industrial Hygienists

erythrocyte
AIC
Akaike's information criterion
MOA
mode of action
ALD
approximate lethal dosage
MTD
maximum tolerated dose
ALT
alanine aminotransferase
NAG
7V-acetyl-P-D-glucosaminidase
AR
androgen receptor
NCEA
National Center for Environmental
AST
aspartate aminotransferase

Assessment
atm
atmosphere
NCI
National Cancer Institute
ATSDR
Agency for Toxic Substances and
NOAEL
no-observed-adverse-effect level

Disease Registry
NTP
National Toxicology Program
BMD
benchmark dose
NZW
New Zealand White (rabbit breed)
BMDL
benchmark dose lower confidence limit
OCT
ornithine carbamoyl transferase
BMDS
Benchmark Dose Software
ORD
Office of Research and Development
BMR
benchmark response
PBPK
physiologically based pharmacokinetic
BUN
blood urea nitrogen
PCNA
proliferating cell nuclear antigen
BW
body weight
PND
postnatal day
CA
chromosomal aberration
POD
point of departure
CAS
Chemical Abstracts Service
PODadj
duration-adjusted POD
CASRN
Chemical Abstracts Service registry
QSAR
quantitative structure-activity

number

relationship
CBI
covalent binding index
RBC
red blood cell
CHO
Chinese hamster ovary (cell line cells)
RDS
replicative DNA synthesis
CL
confidence limit
RfC
inhalation reference concentration
CNS
central nervous system
RfD
oral reference dose
CPN
chronic progressive nephropathy
RGDR
regional gas dose ratio
CYP450
cytochrome P450
RNA
ribonucleic acid
DAF
dosimetric adjustment factor
SAR
structure activity relationship
DEN
diethylnitrosamine
SCE
sister chromatid exchange
DMSO
dimethylsulfoxide
SD
standard deviation
DNA
deoxyribonucleic acid
SDH
sorbitol dehydrogenase
EPA
Environmental Protection Agency
SE
standard error
ER
estrogen receptor
SGOT
serum glutamic oxaloacetic
FDA
Food and Drug Administration

transaminase, also known as AST
FEVi
forced expiratory volume of 1 second
SGPT
serum glutamic pyruvic transaminase,
GD
gestation day

also known as ALT
GDH
glutamate dehydrogenase
SSD
systemic scleroderma
GGT
y-glutamyl transferase
TCA
trichloroacetic acid
GSH
glutathione
TCE
trichloroethylene
GST
glutathione-S-transferase
TWA
time-weighted average
Hb/g-A
animal blood-gas partition coefficient
UF
uncertainty factor
Hb/g-H
human blood-gas partition coefficient
UFa
interspecies uncertainty factor
HEC
human equivalent concentration
UFc
composite uncertainty factor
HED
human equivalent dose
UFd
database uncertainty factor
i.p.
intraperitoneal
UFh
intraspecies uncertainty factor
IRIS
Integrated Risk Information System
UFl
LOAEL-to-NOAEL uncertainty factor
IVF
in vitro fertilization
UFS
subchronic-to-chronic uncertainty factor
LC50
median lethal concentration
U.S.
United States of America
LD50
median lethal dose
WBC
white blood cell
LOAEL
lowest-observed-adverse-effect level


Abbreviations and acronyms not listed on this page are defined upon first use in the PPRTV document.
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PROVISIONAL PEER-REVIEWED TOXICITY VALUES FOR
tert-BUTYL FORMATE (CASRN 762-75-4)
BACKGROUND
A Provisional Peer-Reviewed Toxicity Value (PPRTV) is defined as a toxicity value
derived for use in the Superfund Program. PPRTVs are derived after a review of the relevant
scientific literature using established Agency guidance on human health toxicity value
derivations. All PPRTV assessments receive internal review by at least two National Center for
Environment Assessment (NCEA) scientists and an independent external peer review by at least
three scientific experts.
The purpose of this document is to provide support for the hazard and dose-response
assessment pertaining to chronic and subchronic exposures to substances of concern, to present
the major conclusions reached in the hazard identification and derivation of the PPRTVs, and to
characterize the overall confidence in these conclusions and toxicity values. It is not intended to
be a comprehensive treatise on the chemical or toxicological nature of this substance.
PPRTV assessments are eligible to be updated on a 5-year cycle to incorporate new data
or methodologies that might impact the toxicity values or characterization of potential for
adverse human-health effects and are revised as appropriate. Questions regarding nomination of
chemicals for update can be sent to the appropriate U.S. Environmental Protection Agency
(EPA) Superfund and Technology Liaison (https://www.epa.gov/research/fact-sheets-regional-
science).
DISCLAIMERS
The PPRTV document provides toxicity values and information about the adverse effects
of the chemical and the evidence on which the value is based, including the strengths and
limitations of the data. All users are advised to review the information provided in this
document to ensure that the PPRTV used is appropriate for the types of exposures and
circumstances at the site in question and the risk management decision that would be supported
by the risk assessment.
Other U.S. EPA programs or external parties who may choose to use PPRTVs are
advised that Superfund resources will not generally be used to respond to challenges, if any, of
PPRTVs used in a context outside of the Superfund program.
This document has been reviewed in accordance with U.S. EPA policy and approved for
publication. Mention of trade names or commercial products does not constitute endorsement or
recommendation for use.
QUESTIONS REGARDING PPRTVs
Questions regarding the content of this PPRTV assessment should be directed to the EPA
Office of Research and Development's (ORD's) NCEA, Superfund Health Risk Technical
Support Center (513-569-7300).
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INTRODUCTION
tert-Butyl formate, CASRN 762-75-4, belongs to the class of compounds known as
formic acid esters, tert-Butyl formate has been used as an oxygenate in gasoline formulations
(Drogos and Diaz, 2002). It is not listed on U.S. EPA's Toxic Substances Control Act's public
inventory (U.S. EPA 20151 nor is it registered with Europe's Regulation on Registration,
Evaluation, Authorisation and Restriction of Chemicals (REACH) program (ECHA 2017).
tert-Butyl formate is produced by the oxidation of methyl tert-butyl ether (MTBE).
Formic acid is a coproduct of this reaction (Reutemann and Kieczka. 2011). tert-Butyl formate
is also produced by environmental degradation of MTBE, particularly in the atmosphere (Church
et al.. 1999).
The empirical formula for tert-butyl formate is C5H10O2 and the structure is shown in
Figure 1. Table 1 summarizes the compound's physicochemical properties, tert-Butyl formate
is a flammable, colorless liquid at room temperature (Sigma-Aldrich. 2014). The main fate
pathway of tert-butyl formate in the environment is hydrolysis to tert-butyl alcohol and formic
acid. Half-lives in aqueous solution of 6 hours, 5 days, and 8 minutes have been reported at pH 2
(at 4°C), pH 7 (at 22°C), and pH 11 (at 22°C), respectively (Church et al.. 1999). tert-Butyl
formate's high vapor pressure indicates that it will exist solely as a vapor in the atmosphere.
Given its vapor pressure and high estimated Henry's law constant, it is likely to volatilize from
either dry or moist soil surfaces and from water surfaces. Once in the atmosphere, it will
undergo hydrolysis via reaction with atmospheric moisture. The estimated high water solubility
and low soil adsorption coefficient for tert-butyl formate indicate that it has the potential to leach
to groundwater or undergo runoff after a rain event, where it will undergo hydrolysis.
o ch3
3
Figure 1. tert-Butyl Formate Structure
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Table 1. Physicochemical Properties of terf-Butyl Formate (CASRN 762-75-4)
Property (unit)
Value
Physical state
Liquid
Boiling point (°C)
82.5a
Melting point (°C)
1
VO
cr
Density (g/cm3)
0.886 (at 20°C)°
Vapor pressure (mm Hg at 20 °C)
81°
pH (unitless)
NV
pKa (unitless)
NV
Solubility in water (mg/L at 25 °C)
-4.0 x 104c
Octanol-water partition coefficient (log Kow)
1.19 (estimated)3
Henry's law constant (atm-m3/mol at 25°C)
6.9 x ur4a
Soil adsorption coefficient Koc (L/kg)
13b
Atmospheric OH rate constant (cm3/molecule-sec at 25°C)
7.37 x 10-13a
Atmospheric half-life (d)
22 (estimated)3
Relative vapor density (air = 1)
NV
Molecular weight (g/mol)
102a
Flash point (closed cup, °C)
-9d
"U.S. EPA (2012b).
bVaws (2015).
cDrogos and Diaz (2002).
dSigma-Aldrich (2014).
NV = not available.
No toxicity values for tert-butyl formate are available from EPA or other
agencies/organizations searched, as shown in Table 2.
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Table 2. Summary of Available Toxicity Values for tert-Butyl Formate (CASRN 762-75-4)
Source"
Value (applicability)
Notes
Reference
Noncancer
IRIS
NV
NA
U.S. EPA (2017)
HEAST
NV
NA
U.S. EPA (201 la)
DWSHA
NV
NA
U.S. EPA (2012a)
ATSDR
NV
NA
ATSDR (2017)
IPCS
NV
NA
IPCS (2017); WHO (2017)
Cal/EPA
NV
NA
Cal/EPA (2014): Cal/EPA (2017a): Cal/EPA (2017b)
OSHA
NV
NA
OSHA (2006): OSHA (2011)
NIOSH
NV
NA
NIOSH (2016)
ACGIH
NV
NA
ACGIH (2016)
Cancer
IRIS
NV
NA
U.S. EPA (2017)
HEAST
NV
NA
U.S. EPA (2011a)
DWSHA
NV
NA
U.S. EPA (2012a)
NTP
NV
NA
NTP (2014)
IARC
NV
NA
IARC (2017)
Cal/EPA
NV
NA
Cal/EPA (2011): Cal/EPA (2017a): Cal/EPA (2017b)
ACGIH
NV
NA
ACGIH (2016)
aSources: ACGIH = American Conference of Governmental Industrial Hygienists; ATSDR = Agency for Toxic
Substances and Disease Registry; Cal/EPA = California Environmental Protection Agency; DWSHA = Drinking
Water Standards and Health Advisories; HEAST = Health Effects Assessment Summary Tables;
IARC = International Agency for Research on Cancer; IPCS = International Programme on Chemical Safety;
IRIS = Integrated Risk Information System; NIOSH = National Institute for Occupational Safety and Health;
NTP = National Toxicology Program; OSHA = Occupational Safety and Health Administration.
NA = not applicable; NV = not available.
Non-date-limited literature searches were conducted in November 2015 and updated in
July 2017 for studies relevant to the derivation of provisional toxicity values for tert-butyl
formate (CASRN 762-75-4). Searches were conducted using U.S. EPA's Health and
Environmental Research Online (HERO) database of scientific literature. HERO searches the
following databases: PubMed, ToxLine (including TSCATS1), and Web of Science. The
following databases were searched outside of HERO for health-related data: American
Conference of Governmental Industrial Hygienists (ACGIH), Agency for Toxic Substances and
Disease Registry (ATSDR), California Environmental Protection Agency (Cal/EPA), U.S. EPA
Integrated Risk Information System (IRIS), U.S. EPA Health Effects Assessment Summary
Tables (HEAST), U.S. EPA Office of Water (OW), U.S. EPA TSCATS2/TSCATS8e, U.S. EPA
High Production Volume Information System (HPVIS), National Institute for Occupational
Safety and Health (NIOSH), National Toxicology Program (NTP), Occupational Safety and
Health Administration (OSHA), European Centre for Ecotoxicology and Toxicology of
Chemicals (ECETOC), European Chemicals Agency (ECHA), Japan Existing Chemical Data
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Base (JECDB), Organisation for Economic Co-operation and Development Screening
Information dataset (OECD SIDS), International Uniform Chemical Information Database
(IUCLID), and High Product Volume (HPV).
REVIEW OF POTENTIALLY RELEVANT DATA
(NONCANCER AND CANCER)
No potentially relevant short-term-, subchronic-, or chronic-duration studies or
developmental or reproductive toxicity studies of tert-butyl formate in humans or animals have
been identified.
OTHER DATA (SHORT-TERM TESTS, OTHER EXAMINATIONS)
Acute Animal Studies
The only available animal toxicity study that evaluated /f/ /-butyl formate was an acute
gavage study that examined the testicular toxicity of MTBE and its environmental breakdown
products, A.'/7-butyl alcohol and tert-butyl formate (Billitti et al.. 1998).
Billitti et al. (1998)
Groups of male white mice (five/group; strain not specified) were exposed to MTBE,
tert-butyl alcohol, or tert-butyl formate at doses of 0, 400, 1,000, or 2,000 mg/kg via gavage in
canola oil. Mice exposed to MTBE were exposed three times over a 5-day period, and mice
exposed to tert-butyl alcohol and tert-butyl formate were only exposed once. Positive control
mice (n = 3) were injected with cadmium chloride, a known testicular toxicant (dose not
reported). Feces were collected before and after final exposure to determine fecal testosterone
levels (biomarker for testicular damage). After fecal samples were collected postexposure, the
mice were subcutaneously injected with 2.5 IU/g human chorionic gonadotropin (hCG) in
0.9% sterile saline to stimulate testicular testosterone production. Additional fecal samples were
collected 22 and 26 hours postinjection for all groups and 3 days postexposure for mice exposed
to tert-butyl alcohol and /1,000 mg/kg tert-butyl
alcohol (increased -10% compared with controls) and significantly (p < 0.05) decreased absolute
testes weight was observed at >400 mg/kg tert-butyl formate (decreased -18, 25, and 9% at 400,
1,000, and 2,000 mg/kg, respectively, compared with controls); no changes in absolute testes
weight were noted with MTBE exposure (relative weights were not reported). The only
histopathological change noted in the high-dose MTBE group was a significant (p < 0.05)
increase in the number of tubules having gross disruption (6% compared with 0% in controls);
no changes in the percent of tubules with seminiferous epithelial vacuolization, marginated
chromatin, or multinucleated giant cells were observed. No treatment-related histopathological
lesions were observed in mice exposed to tert-butyl alcohol or tert-butyl formate. Positive
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control mice showed significant (p < 0.05) decreases in serum and fecal testosterone levels and
testes weight, and evidence of histopathological damage (98.6% of tubules showed gross
disruption), compared with control. Taken together, these findings indicate minimal testicular
toxicity in mice following acute exposure to MTBE or its breakdown products.
DERIVATION OF PROVISIONAL VALUES
Tables 3 and 4 present summaries of noncancer and cancer references values,
respectively.
Table 3. Summary of Noncancer Reference Values for
tert-Butyl Formate (CASRN 762-75-4)
Toxicity Type
(units)
Species/Sex
Critical
Effect
p-Reference
Value
POD Method
POD
UFc
Principal Study
Screening
subchronic p-RfD
(mg/kg-d)
S-D rat,
M&F
Decreased
serum BUN
8 x 1(T3
LOAEL
(HED)
23 (based on
surrogate
POD)
3,000
Robinson et al.
(1990) as cited in
ATSDR (1996)
Chronic p-RfD
(mg/kg-d)
NDr
Subchronic p-RfC
(mg/m3)
NDr
Chronic p-RfC
(mg/m3)
NDr
BUN = blood urea nitrogen; F = female(s); HED = human equivalent dose;
LOAEL = lowest-observed-adverse-effect level; M = male(s); NDr = not determined; POD = point of departure;
p-RfC = provisional reference concentration; p-RfD = provisional reference dose; S-D = Sprague-Dawley;
UFC = composite uncertainty factor.
Table 4. Summary of Cancer Reference Values for tert-Butyl Formate (CASRN 762-75-4)
Toxicity Type (units)
Species/Sex
Tumor Type
Cancer Value
Principal Study
p-OSF (mg/kg-d) 1
NDr
p-IUR (mg/m3) 1
NDr
NDr = not determined; p-IUR = provisional inhalation unit risk; p-OSF = provisional oral slope factor.
DERIVATION OF ORAL REFERENCE DOSES
No studies regarding the toxicity of tert-butyl formate to humans by oral exposure have
been identified. Animal studies of oral exposure to tert-butyl formate are limited to an acute
testicular toxicity study, which is of inadequate duration and scope to support derivation of a
subchronic or chronic provisional reference dose (p-RfD). Due to limitations in the available
oral toxicity data for tert-butyl formate, subchronic and chronic p-RfDs were not derived
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directly. Instead, a screening subchronic p-RfD is derived in Appendix A using an alternative
surrogate approach. A screening chronic p-RfD is not derived due to lack of any relevant data
for the target chemical, tert-butyl formate and due to the lack of a chronic toxicity value for
MTBE (see Appendix A).
DERIVATION OF INHALATION REFERENCE CONCENTRATIONS
No studies regarding the toxicity of tert-butyl formate to humans or animals by inhalation
have been identified; therefore, subchronic and chronic provisional reference concentrations
(p-RfCs) could not be derived directly. An alternative surrogate approach was attempted for the
p-RfCs, but screening p-RfCs were not derived due to lack of adequate inhalation toxicity data to
identify an appropriate toxicity-like surrogate (see Appendix A).
CANCER WEIGHT-OF-EVIDENCE DESCRIPTOR
No relevant data are available. Under the U.S. EPA Guidelines for Carcinogen Risk
Assessment (U.S. EPA. 2005). there is "Inadequate Information to Assess Carcinogenic
Potential" of tert-butyl formate.
Table 5. Cancer WOE Descriptor for tert-Butyl Formate
Possible WOE Descriptor
Designation
Route of Entry
(oral, inhalation, or both)
Comments
"Carcinogenic to Humans "
NS
NA
There are no human data to support
this.
"Likely to Be Carcinogenic to
Humans "
NS
NA
There are no animal studies to
support this.
"Suggestive Evidence of
Carcinogenic Potential"
NS
NA
There are no animal studies to
support this.
"Inadequate Information to
Assess Carcinogenic Potential"
Selected
Both
No adequate studies evaluating
carcinogenicity effects in humans
or animals exposed to tert-butyl
formate are available.
"Not Likely to Be Carcinogenic
to Humans "
NS
NA
No evidence of noncarcinogenicity
is available.
NA = not applicable; NS = not selected; WOE = weight of evidence.
DERIVATION OF PROVISIONAL CANCER POTENCY VALUES
The absence of suitable data precludes development of cancer potency values for
tert-butyl formate.
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APPENDIX A. SCREENING PROVISIONAL VALUES
For reasons noted in the main Provisional Peer-Reviewed Toxicity Value (PPRTV)
document, it is inappropriate to derive provisional toxicity values for tert-butyl formate.
However, information is available for this chemical which, although insufficient to support
derivation of a provisional toxicity value, under current guidelines, may be of limited use to risk
assessors. In such cases, the Superfund Health Risk Technical Support Center summarizes
available information in an appendix and develops a "screening value." Appendices receive the
same level of internal and external scientific peer review as the PPRTV documents to ensure
their appropriateness within the limitations detailed in the document. Users of screening toxicity
values in an appendix to a PPRTV assessment should understand that there is considerably more
uncertainty associated with the derivation of an appendix screening toxicity value than for a
value presented in the body of the assessment. Questions or concerns about the appropriate use
of screening values should be directed to the Superfund Health Risk Technical Support Center.
APPLICATION OF AN ALTERNATIVE SURROGATE APPROACH
The surrogate approach allows for the use of data from related compounds to calculate
screening values when data for the compound of interest are limited or unavailable. Details
regarding searches and methods for surrogate analysis are presented in Wang et al. (2012).
Three types of potential surrogates (structural, metabolic, and toxicity-like) are identified to
facilitate the final surrogate chemical selection. The surrogate approach may or may not be
route-specific or applicable to multiple routes of exposure. All information is considered
together as part of the final weight-of-evidence (WOE) approach to select the most suitable
surrogate, both toxicologically and chemically.
Structural Surrogates (Structural Analogs)
Initial surrogate searches focused on identifying a pool of structurally similar chemicals.
Those chemicals that had published oral and/or inhalation toxicity values from the Integrated
Risk Information System (IRIS), PPRTV, Agency for Toxic Substances and Disease Registry
(ATSDR), or California Environmental Protection Agency (Cal/EPA) databases were considered
further as candidate analogs. Two structural analogs to tert-butyl formate with published toxicity
values were identified: methyl /c/7-butyl ether (MTBE) (ATSDR. 1996; U.S. EPA. 1993) and
formic acid (U.S. EPA. 2010). Coincidentally, these the two candidates had both oral and
inhalation toxicity values [i.e., MTBE has oral and inhalation toxicity values published in
ATSDR (1996)1; formic acid has oral and inhalation toxicity values published in U.S. EPA
(2010)1. The initial surrogate search strategy also identified additional chemicals with structural
similarity (e.g., tert-butyl alcohol; ChemlDPlus similarity score of 61%, which is the major toxic
metabolite of MTBE and a degradation product of tert-butyl formate) (see "Metabolic
Surrogates" section below). However, there are no published toxicity values for tert-butyl
alcohol in the IRIS, PPRTV, ATSDR, or Cal/EPA databases, which precludes the identification
of tert-butyl alcohol as a candidate analog in this PPRTV assessment.
Under Wang et al. (2012). structural similarity for analogs is typically evaluated using
U.S. EPA's DSSTox database (DSSTox, 2016) and the National Library of Medicine's (NLM's)
ChemlDplus database (ChemlDplus. 2017). However, DSSTox was not available to the public
at the time this PPRTV assessment was developed, and no date is available for the
implementation of its replacement dashboard. In lieu of DSSTox scores, the Organisation for
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Economic Co-operation and Development (OECD) toolbox was used to calculate structural
similarity using the Tanimoto method (the same quantitative method used by ChemlDplus and
DSSTox). Table A-l summarizes the physicochemical properties and similarity scores of MTBE
and formic acid. ChemlDplus and OECD toolbox similarity scores for MTBE were 56 and 40%,
respectively. The OECD toolbox similarity score for formic acid was only 6%. No similarity
score was available for formic acid in ChemlDplus. The low similarity score for formic acid is
likely related to the limited number of structural descriptors available for this compound.
Structural similarity metrics use a variety of structural descriptors to calculate similarity
(although the nature of the descriptors may vary across different tools). Similarity scores
calculated for compounds with few structural descriptors will be disproportionately influenced
by changes in, or absence of, a single descriptor, while these same changes have relatively lower
impact on similarity scores for compounds with many descriptors. Thus, similarity scores may
be of limited use when comparing surrogates with relatively simple structures such as those
evaluated in this assessment. In total, the similarity results suggest that MTBE is a preferred
structural surrogate in contrast to formic acid.
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Table A-l. Physicochemical Properties of terf-Butyl Formate (CASRN 762-75-4) and
Candidate Structural Surrogates"

tert-Butyl Formate
MTBE
Formic Acid
Structure
0	GH o
1	X!
H O'^^CH,
CH3
CH 3
h3c^o V-CH3
ch3
O
A
H OH
CASRN
762-75-4
1634-04-4
64-18-6
Molecular weight
102
88
46
DSSTox similarity score (%)b
100
NV
NV
ChemlDplus similarity score (%)°
100
56
NV
OECD toolbox similarity score (%)d
100
40
6
Melting point (°C)
Os
1
-108.6
8.3
Boiling point (°C)
82.5
55.2
101
Vapor pressure (mm Hg at 25°C)
81 (at 20°C)f
250
42.6
Henry's law constant (atm-m3/mole at 25°C)
6.9 x 10-4
5.87 x 10-4
1.67 x 10-7
Water solubility (mg/L)
-4.0 x 104f
5.1 x 104
1 x 106
Log Kow
1.19 (estimated)3
0.94
-0.54
pKa
NV
NV
3.75
'Data was gathered from PHYSPROP database for each respective compound unless otherwise specified (U.S.
HP A. 2012b).
bDSSTox (2016).
°ChemIDplus Advanced, similarity scores (ChenilDnliis. 2017).
¦Xjl-X't) (2016).
"Yaws (2015).
fDrogos and Diaz (2002).
MTBE = methyl tert-butyl ether; NV = not available; OECD = Organisation for Economic Co-operation and
Development.
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B
Vu
\ H
tert-Buty I Formate
Hydrolysis
-V*
MTBE
v
+
0 -0
H c ::"


H
tert-Buty I Alcohol Formic Acid
Formaldehyde
tert-Butyl Alcohol
V

II
0
0

2-lv1ethyl-1,2-propanediol
Methanol
Formic Acid
I
1 Carbon Carbon
Pool	Dioxide
a-Hydroxyisobutyric Acid
I
Acetone
Figure A-1. (A) Proposed Environmental Breakdown Pathway of tert-Butyl Formate based
on Information Described in Garoma et al. (2008) and Church et al. (19991. (B) Schematic
Describing MTBE Metabolism as Summarized in ATSDR (1996).
Metabolic Surrogates
Figure A-l depicts known environmental degradation products for /m-butyl formate
(see Figure A-l [A]) and metabolites for MTBE (see Figure A-l [B]). Table A-2 summarizes
available toxicokinetics data for /e/7-butyl formate and the structurally similar compounds
identified as potential surrogates (i.e., MTBE and formic acid).
No toxicokinetic studies have been identified for tert-butyl formate in mammalian
species. Based on data from an environmental fate study, tert-butyl formate is expected to be
hydrolyzed to fc/7-butyI alcohol and formic acid (hydrolysis half-life of 6 hours at pF[ 2 [4°C],
5 days at neutral pli [22°C], and 8 minutes at pFI 11 [22°C]) (Garoma et al., 2008; Church et al..
1999). These data ultimately suggest that hydrolysis of tert-butyl formate can occur across a
wide physiologic range. The study by Garoma et al. (2008 also identified additional
11
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degradation products following ozone/ultra violet-mediated breakdown of MTBE. Of these,
formaldehyde has specifically been determined to have a known role in the generation of formic
acid from the metabolism of MTBE (see Figure A-l [B]). MTBE was identified as a potential
surrogate chemical based on structural similarities. It is initially oxidized by cytochrome P450s
(CYP450s) to both tert-butyl alcohol and formaldehyde (ATSDR. 1996). However, unchanged
MTBE was the major component in expired air, regardless of route of exposure (ATSDR, 1996).
tert-Butyl alcohol is further oxidized to form 2-methyl-l,2-propanediol, alpha-hydroxyisobutyric
acid, and acetone (BioResearch. 1990). Among in vivo metabolism studies of MTBE,
formaldehyde metabolism is shown to proceed more rapidly than tert-butyl alcohol oxidation,
and results in the production of formic acid, suggesting that the localized concentration of
formaldehyde will be very low (ATSDR. 1996). and these findings are consistent with studies
demonstrating no measurable formaldehyde in blood or urine following human MTBE exposure
(l.euschner et al.. 1991). Formic acid, the other potential surrogate of tert-butyl formate, is
converted to carbon dioxide (CO2) and/or rapidly taken up into the carbon pool via folic
acid-dependent metabolic pathways (U.S. EPA. 2010; ATSDR. 1996). Consistent with the
notion that formic acid metabolism is a rapid event and not likely to contribute significantly to
the overall toxicity of tert-butyl formate, studies examining the intracystic infusion of MTBE (a
precursor of formic acid through generation of the intermediate formaldehyde) in humans
demonstrate that both formaldehyde and formic acid were undetectable in blood or urine of
patients in as little as 5 hours of postclinical exposure (l.euschner et al.. 1991)
As stated above, tert-butyl alcohol is a common primary degradation product of tert-butyl
formate and MTBE. tert-Butyl alcohol remains detectable in the blood and urine of humans for
12-18 hours post intracystic MTBE infusion and likely contributes to the observed systemic
effects of MTBE exposure (see "Toxicity-Like Surrogates" section below). For example, in
humans exposed to MTBE via intracystic infusion for dissolution of gallstones (n = 27), mean
blood levels of tert-butyl alcohol were 0.04 mg/mL, up to 5 hours after treatment, and
0.025 mg/mL at 12-18 hours after treatment. Mean urinary levels of tert-butyl alcohol were
0.036 mg/mL at 5 hours, and 0.03 mg/mL at 12-18 hours after treatment (l.euschner et al..
1991). Studies examining the biodegradation of a commonly used fuel oxygenate analog of
MTBE, ethyl tert-butyl ether (ETBE), provide additional evidence to identify tert-butyl alcohol
as a primary and potentially toxic metabolite of both MTBE and ETBE in humans and rats
(Dekant et al.. 2001). However, as stated above, there are no published toxicity values for
tert-butyl alcohol in the IRIS, PPRTV, ATSDR, or Cal/EPA databases which ultimately
precludes its consideration as a potential surrogate for tert-butyl formate. In summary, in vivo
metabolism of MTBE produces similar compounds to those generated from the environmental
breakdown of tert-butyl formate (e.g., tert-butyl alcohol and formic acid, see Figure A-l).
Studies examining MTBE exposure describe a rapid return of both formaldehyde and ultimately
formic acid to the carbon pool, suggesting that the longer bioavailability of tert-butyl alcohol
could drive the toxi col ogical response of MTBE (ATSDR. 1996). Despite the expected rapid
metabolism of formic acid, the ability of MTBE to degrade into both demonstrated degradation
products of tert-butyl formate (i.e., tert-butyl alcohol and formic acid) makes it a preferred
metabolic surrogate in contrast to formic acid.
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Table A-2. Comparison of Available ADME Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates
tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
0	CH,
1	L
H 0 oT0"3
CH3
H,C^ ,
0CH,
ch3 3
0
x
H OH
Absorption
ND
Rapid and extensive absorption by the GI tract postoral
exposure.
•	Demonstrated in animal studies—at least 80% of a
radiolabeled MTBE dose was excreted in expired air
(principally as MTBE and tert-butyl alcohol) and urine (as
oxidation products of tert-butyl alcohol) within 48 hr.
Rapid and extensive absorption by the respiratory tract.
•	Demonstrated in human and animal studies—MTBE blood
concentrations rose rapidly within 1-6-hr exposure periods.
ND
Distribution
ND
Rapid distribution to most tissues (e.g., blood, fatty tissue,
brain, liver, kidney) followed by rapid elimination with
limited accumulation.
• Demonstrated in animal studies following short-term
inhalation or dermal exposures.
ND
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Table A-2. Comparison of Available ADME Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates
tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Metabolism
Metabolism to tert-butyl alcohol and formic
acid is inferred.
•	Chemical hydrolysis to tert-butyl alcohol and
formic acid demonstrated in environmental
fate studies (hydrolysis measured over time
under acidic, basic, and neutral conditions);
half-life of ~5 d at neutral pH.
•	Acidic conditions in stomach expected to
increase rate of chemical hydrolysis
(hydrolysis half-life is 6 hr at pH 2 and 4°C).
Initial metabolism by CYP450s to tert-butyl alcohol, and
formaldehyde, followed by: (1) oxidation of fer/-butyl alcohol
to 2-methyl-l,2-propanediol and alpha-hydroxyisobutyric acid
and (2) reduction of formaldehyde to methanol or oxidation of
formaldehyde to formic acid and eventual production of CO2.
•	tort-Butyl alcohol was the primary metabolite detected in
blood and urine in studies of humans breathing airborne
MTBE or given intracystic infusions; formaldehyde and
formic acid were not detected in blood or urine in these
studies.
•	Metabolic profile was independent of exposure route in rat
studies.
Absorbed formic acid is oxidized to CO2, partly
excreted unchanged in urine, and partly metabolized
and incorporated into tissue macromolecules.
•	Hepatic detoxifying metabolism of formate (the
anion derived from formic acid) to CO2 (via folic
acid-dependent pathways) is much faster in rat liver
than monkey liver due to higher levels of
tetrahydrofolate.
•	Metabolism appears to be saturable; dogs excreted
8-9% unchanged formic acid following a 1 g oral
dose and 65% unchanged following 5 g oral dose.
Excretion
ND
Main routes of excretion are expired air (>80% of orally
dosed, radiolabeled MTBE excreted as unchanged MTBE and
tert-butyl alcohol) and some urinary excretion of oxidized
metabolites of tert-butyl alcohol.
• Metabolism and routes of excretion were independent of
route of exposure in rat studies.
The half-lives of sodium formate (a sodium salt of
formic acid) in blood are 12-23, 31-51, and 55 minin
rats, monkeys, and humans, respectively.
Sources
Church et al. (1999); Garotna et al. (2008)
ATSDR (1996)
U.S. EPA (2010); NTP (1992)
ADME = adsorption, distribution, metabolism, and excretion; CO2 = carbon dioxide; CYP450 = cytochrome P450; GI = gastrointestinal; MTBE = methyl tert-butyl
ether; ND = no data.
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Toxicity-Like Surrogates (Oral)
Table A-3 summarizes available oral and inhalation toxicity values for tert-butyl formate
and the compounds identified as potential structural surrogates.
Oral exposure data for /400 mg/kg (Billitti et al.. 1998). Evidence for mild testicular toxicity was also observed
following a 5-day exposure to MTBE (2,000 mg/kg three times) and was manifested through an
increased number of tubules having gross histopathological disruption compared to controls
(Billitti et al.. 1998). Although the one available chronic-duration oral exposure study of MTBE
showed no non-neoplastic effects in the testes of male rats, an increase in the incidence of
testicular Ley dig cell tumors was observed at 1,000 mg/kg-day (ATSDR. 1996). In a
one-generation oral reproductive toxicity study, tert-butyl alcohol exposure promoted a
significant decrease in sperm motility in Sprague-Dawley (S-D) rats (l.vondell Chemical Co.,
2004). Importantly, no evidence of impaired reproductive function or systemic toxicity was
observed in rats exposed to formic acid at doses up to 277 mg/kg-day in a combined 2-year
toxicity/reproduction study that included multiple generations (U.S. EPA, 2010). Taken
together, these data support the notion that the testes are a shared site of toxicity between
tert-butyl formate, MTBE, and tert-butyl alcohol.
Other systemic targets of toxicity, including the central nervous system (CNS), kidney,
and liver, were identified following repeat exposure to MTBE at oral doses (>100 mg/kg-day)
lower than the acute dose associated with testicular toxicity (ATSDR. 1996). The neurological
effects of MTBE exposure (i.e., CNS depression) are believed to be due, at least in part, to the
presence of tert-butyl alcohol (the primary metabolite of MTBE and degradation product of
tert-butyl formate) in the brain of male Wistar rats (Church et al.. 1999; ATSDR. 1996).
Subchronic- and chronic-duration oral administration studies of tert-butyl alcohol in rats
exhibited increased absolute and relative kidney weights (l.vondell Chemical Co.. 2004; NTP.
1997, 1995), as well as increased incidence and severity of histopathological lesions in the
kidney (NTP. 1997. 1995). Thyroid histopathological effects were also observed in mice
following chronic-duration oral exposure to tert-butyl alcohol (NTP. 1995). Furthermore,
developmental effects in rats and mice indicate that tert-butyl alcohol exposure can promote loss
of fetal viability (e.g., increased rates of resorption and decreased numbers of neonates per litter)
(l.vondell Chemical Co.. 2004; Faulkner et al. 1989; Daniel and Evans. 1982). Formic acid
(>360 mg/kg-day) is associated with decreased body weight and reduced offspring survival in
other studies (U.S. EPA. 2010). Thus, there is insufficient evidence to evaluate formic acid as an
oral toxicity-like surrogate due to the absence of data regarding testicular toxicity or additional
sites of toxicity that may be shared with tert-butyl formate following oral exposure.
In summary, oral exposure studies of tert-butyl formate, MTBE, and tert-butyl alcohol
indicate that the testes are a shared site of toxicity. Furthermore, repeated and longer-duration
studies of exposures to MTBE and tert-butyl alcohol indicate additional shared sites of toxicity
for MTBE and tert-butyl alcohol outside of the reproductive tract. However, as stated above,
there are no published toxicity values for tert-butyl alcohol in the IRIS, PPRTV, ATSDR, or
Cal/EPA databases which ultimately precludes its consideration as a potential surrogate for
tert-butyl formate. Therefore, MTBE is considered the most appropriate toxicity-like surrogate.
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Toxicity-Like Surrogates (Inhalation)
There are no inhalation toxicity data for tert-butyl formate. The CNS (2,000 ppm), liver
(3,000 ppm), and kidney (4,000 ppm) were identified as the primary non-neoplastic targets of
inhalation MTBE exposure (ATSDR. 1996). Subchronic-duration inhalation studies of tert-buty\
alcohol in rats reported increased absolute and relative kidney weights, as well as increased
incidence and severity of histopathological lesions in the kidney ( N I P. 1997). Portal-of-entry
effects were observed in rats (241 mg/m3) and mice (120 mg/m3) exposed to formic acid via
inhalation for 2 or 13 weeks (U.S. EPA. 2010). Neutropenia (15 mg/m3) was also observed in
rats exposed to formic acid by inhalation for 13 weeks, although these findings were not dose
related and the mechanism of toxicity is unclear, as mouse bone marrow did not display classical
hi stopathol ogi cal characteristics of neutropenia (NIP. 1992).
While the inhalation-specific effects of MTBE and formic acid are generally divergent,
there is no relevant information regarding the effects of inhalation-specific tert-butyl formate
exposure. This precludes the identification of a best toxicity-like surrogate for the inhalation
route of exposure, and neither compound was selected as an inhalation toxicity-like surrogate for
/c'/7-butyl formate.
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Structure
? <* H,
H '"i i. "" CH„.

O
• i
li.
H" ""OH
Repeat-dose toxicity—oral, subchronic
POD (mg/kg-d)
NA
100
277
POD type
NA
LOAEL
NOAEL (no LOAEL was identified)
Subchronic UFC
NA
300 (UFh, UFa, UFl)
300 (UFh, UFa, UFl)
Subchronic MRL
(MTBE)/p-RfD (formic
acid) (mg/kg-d)
NA
0.3 (MRL)
9 x 101 (p-RfD)
Critical effects
NA
Decreased serum BUN levels at 100 mg/kg-d (M
andF).
No effects at doses up to 277 mg/kg-d.
Other effects
(in principal study)
NA
Additional effects at >900 mg/kg-d included
temporary sedation, increased serum LDH and
cholesterol (F), increased AST (M), increased
relative liver weight (M and F), and increased
adrenal gland weight (F). All exposed males
showed nephropathy associated with hyaline
droplets. No other histopathological lesions or
body-weight effects were associated with
exposure at doses up to 1,200 mg/kg-d.
No exposure-related changes in reproductive or
developmental endpoints, animal growth, or organ
function (details not specified).
Species
NA
S-D rat, M and F
Rat, M and F
Duration
NA
90 d
2 yr (combined toxicity/reproductive study). NOAEL
used for the derivation of the subchronic p-RfD was
based on the lack of reproductive or developmental
effects.
Route
NA
Gavage (in corn oil)
Drinking water
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Additional toxicity data
(from other studies)
• In an acute testicular
toxicity screen, a
9-25% decrease in
testicular weight was
observed in mice exposed to
400-2,000 mg/kg. No
exposure-related changes in
serum or fecal testosterone
levels or testicular histology
were observed.
• In a 4-wk gavage study, a NOAEL of
440 mg/kg-d and a LOAEL of 1,750 mg/kg-d
were identified for increased relative liver
weight and increased serum cholesterol in rats.
Exposed males showed nephropathy associated
with hyaline droplets. Body-weight effects
were not observed at doses up to
1,750 mg/kg-d.
• Biochemical changes (decreased BUN,
increased AST and LDH) were observed in rats
exposed to doses >1,071 mg/kg-d via gavage
for 14 d.
• Sedation has been reported in acute studies at
doses as low as 400 mg/kg-d.
• In an acute testicular toxicity screen, the
number of tubules having gross disruption was
increased in mice exposed to
2,000 mg/kg (6%) compared with
controls (0%). No exposure-related changes in
serum or fecal testosterone levels or testicular
weight were observed.
• Numerous human case studies report irritation and
corrosive effects of ingested formic acid, including
ulceration and perforation of the GI tract.
• Acute doses of 429-673 mg/kg are potentially lethal
in humans, attributed to corrosive perforations of the
abdominal viscera, gastrointestinal hemorrhage, or
acute renal failure. Survivors of high acute
exposures show acute renal failure, liver impairment,
and hematemesis.
• Decreased body-weight and food consumption were
observed in rats following exposure to 360 mg/kg-d
in drinking water for 9-15 wk.
• Reduced offspring survival was observed in rats
following chronic parental exposure to
1,360 mg/kg-d in drinking water (7 mo).
• Additional short-term-, subchronic-, and
chronic-duration oral studies report no adverse
effects following oral exposure to formic acid;
however, these studies have limited reporting or are
available only from secondary sources.
Source
Billitti et al. (1998)
ATSDR (1996)
U.S. EPA (2010)
Repeat-dose toxicity—oral, chronic
POD (mg/kg-d)
NA
NA
277
POD type
NA
NA
NOAEL (freestanding)
Chronic UFc
NA
NA
300 (UFh, UFa, UFl)
Chronic p-RfD (mg/kg-d)
NA
NA
9 x 10-1
Critical effects
NA
NA
No adverse effects at doses up to 277 mg/kg-d.
Other effects
(in principal study)
NA
NA
No exposure-related changes in reproductive or
developmental endpoints, animal growth, or organ
function (details not specified).
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Species
NA
NA
Rat, M and F
Duration
NA
NA
2 yr (combined toxicity/reproductive study)
Route
NA
NA
Drinking water
Additional toxicity data
(from other studies)
ND
The only available chronic-duration oral study
reported decreased survival in female rats
accompanied by dysplastic proliferation of
lymphoreticular tissues at all tested doses (250 or
1,000 mg/kg-d, 4 times/wk for 104 wk via
gavage), compared with control. These findings
were associated with statistically significant
increases (p < 0.01) in lymphoma and leukemia
in female rats at >250 mg/kg-d. No adverse
non-neoplastic effects were observed in male
rats, but a statistically significant increase in the
incidence of testicular Leydig cell tumors was
observed at 1,000 mg/kg-d.
See "Repeat-dose toxicity—oral, subchronic" section
above.
Source
ND
ATSDR (1996)
U.S. EPA (2010)
Repeat-dose toxicity—inhalation, subchronic
POD (mg/m3)
NA
260 (71 ppm)
2.7
POD type
NA
NOAEL (HEC)
LOAEL (HEC)
Subchronic UFC
NA
100 (UFh, UFa)
3,000 (UFh, UFa, UFl, UFd)
Subchronic p-RfC/MRL
(mg/m3)
NA
3 (0.7 ppm)
9 x 10-4
Critical effects
NA
Sedation (hypoactivity, lack of startle response)
and blepharospasm in parental animals at
3,000 ppm (LOAEL [HEC] = 1,900 mg/m3).
Neutropenia and increased serum ALP at 15 mg/m3
(LOAEL [HEC] = 2.7 mg/m3).
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Other effects
(in principal study)
NA
Reduced F1 and F2 pup weight was observed at
the same administered concentration that elicited
CNS effects in parental animals. Increased
relative liver weight was observed at 3,000 ppm
in F1 parental males and at 8,000 ppm in
F1 parental females (duration-adj = 1,900 and
5,200 mg/m3, respectively). Reduced body
weight was observed in parental males at
8,000 ppm (duration-adj = 5,200 mg/m3). No
adverse effects on reproduction at concentrations
up to 8,000 ppm (duration-adj = 5,200 mg/m3).
Mild nasal lesions (olfactory epithelium degeneration,
respiratory epithelium squamous metaplasia) were
increased in males and females at a higher
administered concentration (241 mg/m3) than selected
critical effects. No other expo sure-related effects were
observed.
Species
NA
Rat, M and F
Rat, M and F
Duration
NA
14-19 wk (2-generation reproduction study)
13 wk
Route
NA
Whole-body inhalation
Whole-body inhalation
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Additional toxicity data
(from other studies)
ND
•	Effects observed in 13-wk studies in rats
include altered motor activity (increased then
decreased) and increased relative liver and
kidney weights at >800 ppm
(duration-adj =510 mg/m3); sedation, ataxia,
and decreased hind-limb grip strength at
>4,000 ppm (duration-adj = 2,600 mg/m3); and
hyperplasia of submandibular lymph nodes in
males at 8,000 ppm
(duration-adj = 5,100 mg/m3). No
body-weight effects were observed at any
concentration.
•	Effects observed in 4-5-wk studies in rats and
mice include sedation and increased absolute
and relative liver and kidney weight at
>3,000 ppm (duration-adj = 1,900 mg/m3);
centrilobular hepatocellular hypertrophy was
observed at 8,000 ppm in mice
(duration-adj = 5,100 mg/m3). Decreased body
weight was observed in male mice only at
8,000 ppm (duration-adj = 5,100 mg/m3).
•	In a 1-generation rat study, no adverse
reproductive or developmental effects were
observed at concentrations up to 2,500 ppm
(9,010 mg/m3; duration-adj = 1,600 mg/m3).
•	Effects observed in the companion 13-wk mouse
study included nasal lesions and decreased body
weight female mice at >120 mg/m3, respectively.
No other exposure-related effects were noted.
•	Effects observed in 2-wk dose range-finding studies
included nasal lesions in rats and mice at
>118 mg/m3; clinical signs of toxicity, decreased
body weight, and reduced thymus weight in rats and
mice at >470 mg/m3; and corneal opacity in rats and
mice at 941 mg/m3.
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Continued:
Continued:
Continued:
•	In gestational exposure studies in mice,
reduced fetal body weight and skeletal
ossification were observed at 4,000 ppm
(14,000 mg/m3); this concentration also
produced maternal toxicity (sedation, ataxia).
At 8,000 ppm (28,000 mg/m3), increased
number of nonviable implants/litter, increased
late absorptions, and increased incidence of
cleft palate were observed. No developmental
effects were observed at <2,500 ppm
(9,000 mg/m3).
•	No developmental effects were observed in
rats or rabbits exposed to concentrations up to
2,500 ppm (9,000 mg/m3) or 8,000 ppm
(28,000 mg/m3), respectively. Maternal
toxicity (reduced body weight, sedation) was
observed in rabbits at >4,000 ppm
(14,000 mg/m3).
Continued:
Source
ND
ATSDR (1996)
U.S. EPA (2010)
Repeat-dose toxicity—inhalation, chronic
POD (mg/m3)
NA
259
2.7
POD type
NA
NO A F.I. (HEC)
LOAEL (HEC)
Chronic UFC
NA
100 (UFh, UFa, UFd)
10,000 (UFh, UFa, UFs, UFl, UFd)
Chronic p-RfC/RfC (mg/m3)
NA
3
3 x 10 4 (screening)
Critical effects
NA
Increased absolute and relative liver and kidney
weights and increased severity of spontaneous
renal lesions (F), increased prostration (F), and
swollen periocular tissue (M and F) at
10,899 mg/m3 (LOAEL [HEC] = 1,946 mg/m3).
Neutropenia and increased serum ALP at 15 mg/m3
(LOAEL [HEC] = 2.7 mg/m3).
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Other effects
(in principal study)
NA
Additional effects noted at higher concentrations
in both sexes included additional signs of clinical
toxicity (ataxia, salivation) and decreased body
weight. Male rats showed dose-related increases
in a2u-g-mediated nephropathy and an associated
decrease in survival. No additional organ-weight
or histopathological changes were associated
with exposure.
See "Repeat-dose toxicity—inhalation,
subchronic" section above.
Species
NA
Rat, M and F
Rat, M and F
Duration
NA
24 mo
13 wk
Route
NA
Whole-body inhalation
Whole-body inhalation
Additional toxicity data
(from other studies)
ND
• In an 18-mo mouse study, an NOAEL (HEC)
of 1,288 mg/m3 and an LOAEL (HEC) of
2,575 mg/m3 were based on anesthetic effects,
decreased body weight, increased absolute and
relative liver weights, and hepatocellular
hypertrophy (M).
• Effects associated with short-term-duration,
subchronic-duration, and
reproductive/developmental studies are
reported in "Repeat-dose toxicity—inhalation,
subchronic" section above.
Note: ATSDR (1996) derived a chronic
inhalation MRL of 0.7 ppm (3 mg/m3) using the
same principal study and the critical endpoint of
increased severity of chronic progressive
nephropathy in female rats.
See "Repeat-dose toxicity—inhalation,
subchronic" section above.
Source
NA
U.S. EPA (1993)
U.S. EPA (2010)
Acute lethality studies
Rat oral LD5o (mg/kg)
NA
4,000
1,100
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Table A-3. Comparison of Available Toxicity Data for tert-Butyl Formate (CASRN 762-75-4) and Potential Surrogates

tert-Butyl Formate
CASRN 762-75-4
MTBE
CASRN 1634-04-4
Formic Acid
CASRN 64-18-6
Toxicity at rat oral LD50
NA
NA
General depressed activity, dyspnea
Mouse oral LD50 (mg/kg)
NA
4,410
700
Toxicity at mouse oral LD50
NA
NA
General depressed activity, dyspnea
Rat inhalation LC50 (mg/m3)
NA
85,000
15,000
Toxicity at rat inhalation
LC50
NA
NA
General depressed activity, dyspnea
Mouse inhalation LC50
(mg/m3)
NA
141,000
6,200
Toxicity at mouse inhalation
LC50
NA
CNS (anesthesia)
General depressed activity, dyspnea
Source
GiemlDplus (2017)
GiemlDplus (2017)
GiemlDplus (2017)
a2u-g = alpha 2u-globulin; ADJ = adjusted; ALP = alkaline phosphatase; AST = aspartate aminotransferase; BUN = blood urea nitrogen; CNS = central nervous system;
F = female(s); GI = gastrointestinal; HEC = human equivalent concentration; LC50 = median lethal concentration; LD50 = median lethal dose; LDH = lactate
dehydrogenase; LOAEL = lowest-observed-adverse-effect level; M = male(s); MRL = minimal risk level; MTBE = methyl tert-butyl ether; NA = not applicable;
ND = no data; NOAEL = no-observed-adverse-effect level; POD = point of departure; p-RfC = provisional reference concentration; p-RfD = provisional reference dose;
S-D = Sprague-Dawley; UFa = interspecies uncertainty factor; UFC = composite uncertainty factor; UFD = database uncertainty factor; UFH = intraspecies uncertainty
factor; UFL = LOAEL-to-NOAEL uncertainty factor; UFS = subchronic-to-chronic uncertainty factor.
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Weight-of-Evidence Approach—Oral
MTBE is selected as the surrogate compound for deriving the screening subchronic
provisional reference dose (p-RfD). While formic acid (a second potential candidate surrogate)
is a degradation product of tert-butyl formate, MTBE is a better metabolic surrogate for
tert-butyl formate because MTBE and tert-butyl formate are both expected to degrade and/or
metabolize to tert-butyl alcohol and formic acid. Importantly, evidence suggests that tert-butyl
alcohol is primarily responsible for the oral toxicity associated with exposure to MTBE and is
presumed to be associated with the toxicity of tert-butyl formate. Structural similarity scores (as
determined by OECD toolbox) were 6% for formic acid and 40% for MTBE, further supporting
the selection of MTBE as a more appropriate chemical surrogate. Additionally, the MTBE
database provides evidence for a potential common target of toxicity (testes) with tert-butyl
formate, while formic acid has a limited oral database only describing decreased body weight
and food consumption in rats, in a single, poorly-reported study.
Weight-of-Evidence Approach—Inhalation
The absence of inhalation toxicity data for tert-butyl formate precludes the development
of a surrogate-driven inhalation value for tert-butyl formate. Therefore, screening provisional
reference concentrations (p-RfCs) were not derived.
ORAL TOXICITY VALUES
Derivation of a Screening Subchronic Provisional Reference Dose
Based on the overall surrogate approach presented in this PPRTV assessment, MTBE
was selected as the surrogate for tert-butyl formate for deriving a screening subchronic p-RfD.
The study used to derive the ATSDR intermediate-duration oral minimal risk level (MRL) for
MTBE was a 90-day gavage study in rats [Robinson et al. (1990) as cited in ATSDR (1996)1.
The ATSDR profile for MTBE described this study as follows:
Experimental design: Groups of 10 male and 10 female Sprague-Dawley rats
were treated by gavage with MTBE in corn oil at doses of 0, 100, 300, 900, and
1,200 mg/kg/day, 7 days/week for 90 days.
Effects noted in study and corresponding doses: Relative and absolute lung
weights were significantly increased in males at 1,200 mg/kg/day. Treated rats in
all dose groups had diarrhea throughout the exposure period. Heart weight was
significantly increased in female rats at 900 mg/kg/day. In females at
1,200 mg/kg/day, erythrocyte counts, hemoglobin, and hematocrit values were
significantly increased, while leukocyte counts were significantly decreased. In
male rats at 1,200 mg/kg/day, mean corpuscular volume values were significantly
decreased and monocyte values were significantly elevated. Significant increases
in relative liver weights were found in females at 900 mg/kg/day and in males at
900 and 1,200 mg/kg/day. Serum lactate dehydrogenase levels were significantly
elevated in females at 300 mg/kg/day, and serum aspartate aminotransferase
levels were significantly elevated in males at 300 and 1,200 mg/kg/day. Blood
urea nitrogen (BUN) levels were significantly decreased in males andfemales at
all dose levels, i.e., at >100 mg/kg/day. No histopathological lesions were found
in the liver. Relative kidney weights were significantly elevated in female rats at
>300 mg/kg/day, and absolute and relative kidney weights were significantly
elevated in male rats at >900 mg/kg/day. Significant microscopic changes were
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observed in kidneys from treated male rats. Tubular changes, which were more
severe in the 1,200 mg/kg/day dose-group males compared with controls,
consisted of mild increases in cytoplasmic hyaline droplets in proximal tubular
cells and small numbers of intratubular granular casts at the junction of the outer
and inner stripe of the outer medulla. Female rats given 1,200 mg/kg/day had
significantly elevated adrenal gland weights. Final body weight in both males
and females decreased in a dose-dependent manner compared with controls, but
the decrease in final body weight was significant only in females at
1,200 mg/kg/day. Cholesterol was significantly elevated in all treatedfemale rats
and in 900 mg/kg/day males. Profound anesthesia was observed immediately
following dosing with 1,200 mg/kg/day, but the rats recovered in approximately
2 hours.
The critical effect for the 90-day rat study (Robinson et al.. 1990) was decreased BUN
levels in female and male Sprague-Dawley (S-D) rats at the lowest administered dose; the
lowest-observed-adverse-effect level (LOAEL) of 100 mg/kg-day was used as the point of
departure (POD) (a no-observed-adverse-effect level [NOAEL] was not identified).
Furthermore, because the current practice is to only adopt existing PODs, benchmark dose
modeling is not performed when applying the alternative surrogate approach (Wang et al.. 2012)
in PPRTV assessments. The LOAEL of 100 mg/kg-day was converted to a human equivalent
dose (HED) according to current U.S. EPA (201 lb) guidance. In Recommended Use of Body
Weight3/4 as the Default Method in Derivation of the Oral Reference Dose (U.S. EPA. 201 lb),
the Agency endorses body-weight scaling to the 3/4 power (i.e., BW3/4) as a default to
extrapolate toxicologically equivalent doses of orally administered agents from all laboratory
animals to humans for the purpose of deriving a p-RfD from effects that are not portal-of-entry
effects.
Following U.S. EPA (2011b) guidance, the POD for decreased serum BUN in rats is
converted to an HED through the application of a dosimetric adjustment factor (DAF) derived as
follows:
DAF = (BWa1/4 - BWh1/4)
where
DAF = dosimetric adjustment factor
BWa = animal body weight
BWh = human body weight
Using a reference BWa of 0.267 and 0.204 kg for male and female S-D rats, respectively,
in a subchronic-duration study and a reference BWh of 70 kg for humans (U.S. EPA. 1988). the
resulting DAFs are 0.25 for males and 0.23 for females (U.S. EPA. 201 lb). The female DAF of
0.23 was applied to the LOAEL of 100 mg/kg-day, since it yields the most health-protective
POD (HED):
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POD (HED) = LOAEL (mg/kg-day) x DAF
= 100 mg/kg-day x 0.23
= 23 mg/kg-day
For tert-butyl formate, a UFa of 3 is applied because cross-species dosimetric adjustment
was performed. A UFh of 10 is applied to account for intraspecies human-to-human variability.
Additionally, for the derivation of the screening subchronic p-RfD for tert-butyl formate, a
database uncertainty factor (UFd) of 10 is used to account for the absence of any toxicity
information for tert-butyl formate, and a LOAEL-to-NOAEL uncertainty factor (UFl) of 10 is
employed due to the use of a LOAEL as the POD. Thus, the screening subchronic p-RfD for
tert-butyl formate is derived using the surrogate POD (HED) and a composite uncertainty factor
(UFc) of 3,000 (reflecting a UFa of 3, a UFh of 10, a UFd of 10, and a UFl of 10):
Screening Subchronic p-RfD = Surrogate POD (HED) ^ UFc
= 23 mg/kg-day ^ 3,000
= 8 x 10"3 mg/kg-day
Table A-4 summarizes the uncertainty factors for the screening subchronic p-RfD for
/c'/7-butyl formate.
Table A-4. Uncertainty Factors for the Screening Subchronic p-RfD for
tert-Butyl Formate (CASRN 762-75-4)
UF
Value
Justification
UFa
3
A UFa of 3 (10°5) is applied to account for uncertainty associated with extrapolating from animals to
humans when cross-species dosimetric adjustment (HED calculation) is performed.
UFd
10
A UFd of 10 is applied to account for the absence of repeat-dose toxicity data for tert-butyl formate.
UFh
10
A UFh of 10 is applied for intraspecies variability to account for human-to-human variability in
susceptibility in the absence of quantitative information to assess the toxicokinetics and
toxicodynamics of tert-butyl formate in humans.
UFl
10
A UFl of 10 is applied because the POD is a LOAEL.
UFS
1
A UFS of 1 is applied because a subchronic-duration study was selected as the principal study.
UFC
3,000
Composite UF = UFA x UFD x UFH x UFL x UFS.
HED = human equivalent dose; LOAEL = lowest-observed-adverse-effect level; POD = point of departure;
p-RfD = provisional reference dose; UF = uncertainty factor; UFA = interspecies uncertainty factor;
UFc = composite uncertainty factor; UFD = database uncertainty factor; UFH = intraspecies variability uncertainty
factor; UFL = LOAEL-to-NOAEL uncertainty factor; UFS = subchronic-to-chronic uncertainty factor.
Derivation of a Screening Chronic Provisional Reference Dose
Derivation of a screening chronic p-RfD is not proposed due to the following reasons:
(1) a lack of any chronic-duration data for the target chemical, tert-butyl formate; (2) a lack of
distinctly adverse non-neoplastic effects following chronic-duration, oral MTBE exposure; and
(3) a lack of a published chronic-duration toxicity value for MTBE (see "Weight-of-Evidence
Approach—Oral" section above for rationale).
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Consideration of Potential Carcinogenicity
As discussed above, MTBE was selected as the surrogate for tert-butyl formate for
derivation of a screening subchronic p-RfD using an alternative surrogate approach (Wane et ai
2012). The Cal/EPA has previously derived the following cancer potency estimates for MTBE:
an oral slope factor (OSF), inhalation unit risk (IUR), and an inhalation slope factor (ISF)
(Cal/EPA, 2009). Furthermore, the Cal/EPA"s drinking water Public Health Goal is based on a
carcinogen risk assessment (Cal/EPA. 1999). This information suggests that /c/V-butyl formate
might have carcinogenic potential as well, but does not preclude the development of noncancer,
surrogate-derived screening provisional values within this document.
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