EPA Document# EPA-740-D-20-011
April 2020
United States	Office of Chemical Safety and
Environmental Protection Agency	Pollution Prevention
Draft Scope of the Risk Evaluation for
1,3-Butadiene
CASRN 106-99-0
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April 2020

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TABLE OF CONTENTS
ACKNOWLEDGEMENTS	5
ABBREVIATIONS AND ACRONYMS	6
EXECUTIVE SUMMARY	8
1	INTRODUCTION	11
2	SCOPE OF THE EVALUATION	11
2.1	Reasonably Available Information	11
2.1.1	Search of Gray Literature	12
2.1.2	Search of Literature from Publicly Available Databases (Peer-Reviewed Literature)	13
2.1.3	Search of TSCA Submissions	17
2.2	Conditions of Use	18
2.2.1	Categories and Subcategories of Conditions of Use Included in the Scope of the Risk
Evaluation	18
2.2.2	Activities Excluded from the Scope of the Risk Evaluation	21
2.2.3	Production Volume	21
2.2.4	Overview of Conditions of Use and Lifecycle Diagram	21
2.3	Exposures	24
2.3.1	Physical and Chemical Properties	24
2.3.2	Environmental Fate and Transport	24
2.3.3	Releases to the Environment	24
2.3.4	Environmental Exposures	26
2.3.5	Occupational Exposures	26
2.3.6	Consumer Exposures	27
2.3.7	General Population Exposures	27
2.4	Hazards (Effects)	28
2.4.1	Environmental Hazards	28
2.4.2	Human Health Hazards	28
2.5	Potentially Exposed or Susceptible Subpopulations	28
2.6	Conceptual Models	29
2.6.1	Conceptual Model for Industrial and Commercial Activities and Uses	29
2.6.2	Conceptual Model for Consumer Activities and Uses	31
2.6.3	Conceptual Models for Environmental Releases and Wastes: Potential Exposures and
Hazards (Regulatory Overlay)	33
2.6.3.1	Ambient Air Pathway	35
2.6.3.2	Drinking W ater Pathway	35
2.6.4	Conceptual Model for Environmental Releases and Wastes: Potential Exposures and
Hazards	36
2.7	Analysis Plan	38
2.7.1	Physical and Chemical Properties and Environmental Fate	38
2.7.2	Exposure	39
2.7.2.1	Environmental Releases	39
2.7.2.2	Environmental Exposures	41
2.7.2.3	Occupational Exposures	42
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2.7.2.4	Consumer Exposures	44
2.7.2.5	General Population	45
2.7.3	Hazards (Effects)	47
2.7.3.1	Environmental Hazards	47
2.7.3.2	Human Health Hazards	48
2.7.4	Summary of Risk Approaches for Characterization	51
2.8 Peer Review	51
REFERENCES	52
APPENDICES	62
Appendix A LIST OF GRAY LITERATURE SOURCES	62
Appendix B PHYSICAL AND CHEMICAL PROPERTIES OF 1,3-BUTADIENE	65
Appendix C ENVIRONMENTAL FATE AND TRANSPORT PROPERTRIES	67
Appendix D REGULATORY HISTORY	69
D.l Federal Laws and Regulations														..............69
D.2 State Laws and Regulations 													...........73
D.3	International Laws and Regulations.....													74
Appendix E PROCESS, RELEASE AND OCCUPATIONAL EXPOSURE INFORMATION	76
E.l	Process Information									76
E. 1.1 Manufacture (Including Import)	76
E. 1.1.1 Domestic Manufacture	76
E.l. 1.2 Import	78
E. 1.2 Processing and Distribution	78
E. 1.2.1 Reactant or Intermediate	78
E. 1.2.2 Incorporated into a Formulation, Mixture or Reaction Product	78
E. 1.2.3 Incorporated into an Article	79
E. 1.2.4 Repackaging	79
E.l.2.5 Recycling	79
E.l.3 Other Uses	79
E.l.4 Disposal	80
E.2 Preliminary Occupational Exposure Data...													80
Appendix F SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR INDUSTRIAL AND
COMMERCIAL ACTIVITIES AND USES	82
Appendix G SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR CONSUMER
ACTIVITIES AND USES	94
Appendix H SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR
ENVIRONMENTAL RELEASES AND WASTES	96
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LIST OF TABLES
Table 2-1. Results of Title Screening of Submissions to EPA Under Various Sections of TSCA	18
Table 2-2. Categories and Subcategories of Conditions of Use Included in the Scope of the Risk
Evaluation	19
Table 2-3. Summary of 1,3-Butadiene TRI Production-related Waste Managed in 2018	25
Table 2-4. Summary of Releases of 1,3-Butadiene to the Environment During 2018	25
Table 2-5. Potential Categories and Sources of Environmental Release Data	39
Table 2-6. Potential Sources of Occupational Exposure Data	42
LIST OF FIGURES
Figure 2-1 Gray Literature Search Results for 1,3-Butadiene	12
Figure 2-2. Peer-reviewed Literature - Physical-Chemical Properties Search Results for 1,3-Butadiene.
	13
Figure 2-3. Peer-reviewed Literature - Fate and Transport Search Results for 1,3-Butadiene	14
Figure 2-4. Peer-reviewed Literature - Engineering Search Results for 1,3-Butadiene	15
Figure 2-5. Peer-reviewed Exposure Search Results for 1,3-Butadiene	16
Figure 2-6. Peer-reviewed Hazard Search Results for 1,3-Butadiene	17
Figure 2-7. 1,3-Butadiene Life Cycle Diagram	23
Figure 2-8. 1,3-Butadiene Conceptual Model for Industrial and Commercial Activities and Uses: Worker
and ONU Exposures and Hazards	30
Figure 2-9. 1,3-Butadiene Conceptual Model for Consumer Activities and Uses: Consumer Exposures
and Hazards	32
Figure 2-10. 1,3-Butadiene Conceptual Model for Environmental Releases and Wastes: Environmental
and General Population Exposures and Hazards (Regulatory Overlay)	34
Figure 2-11. 1,3-Butadiene Conceptual Model for Environmental Releases and Wastes: Environmental
and General Population Exposures and Hazards	37
LIST OF APPENDIX TABLES
Table_Apx A-l Gray Literature Sources for 1,3-Butadiene	62
TableApx B-l Physical and Chemical Properties of 1,3-Butadiene	65
TableApx C-l. Environmental Fate Characteristics of 1,3-Butadiene	67
Table_Apx D-l. Federal Laws and Regulations	69
Table_Apx D-2. State Laws and Regulations	73
Table Apx D-3. Regulatory Actions by other Governments, Tribes, and International Agreements	74
Table Apx E-l. Summary of NIOSH HHEs with Monitoring for 1,3-Butadiene21	80
Table Apx E-2. Summary of Industry Sectors with 1,3-Butadiene Monitoring Samples Available from
OSHA Inspections Conducted Between 2010 and 2019	80
Table Apx H-l. General Population and Environmental Exposure Conceptual Model Supporting Table
	96
LIST OF APPENDIX FIGURES
FigureApx E-l. Process Flow Diagram of Manufacture of 1,3-butadiene via Steam Cracking of
Hydrocarbons (EPA, 1996)	 77
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ACKNOWLEDGEMENTS
This report was developed by the United States Environmental Protection Agency (U.S. EPA), Office of
Chemical Safety and Pollution Prevention (OCSPP), Office of Pollution Prevention and Toxics (OPPT).
Acknowledgements
The OPPT Assessment Team gratefully acknowledges participation or input from intra-agency
reviewers that included multiple offices within EPA, inter-agency reviewers that included multiple
federal agencies, and assistance from EPA contractors GDIT (Contract No. HHSN316201200013W),
ERG (Contract No. EP-W-12-006), Versar (Contract No. EP-W-17-006), ICF (Contract
No.68HERC19D0003), Abt Associates (Contract No. EP-W-16-009) and SRC (Contract No.
68HERH19F0213). EPA also acknowledges the contributions of technical experts from EPA's Office of
Research and Development.
Docket
Supporting information can be found in public docket: [Docket ID: EPA-HQ-OP	14511.
Disclaimer
Reference herein to any specific commercial products, process or service by trade name, trademark,
manufacturer or otherwise does not constitute or imply its endorsement, recommendation or favoring by
the United States Government.
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ABBREVIATIONS AND ACRONYMS
ABS
Acrylonitrile Butadiene Styrene resin plastics
ACC
American Chemistry Council
ADME
Absorption, Distribution, Metabolism, and Excretion
AT SDR
Agency for Toxic Substances and Disease Registry
BAF
Bioaccumulation Factor
BCF
Bioconcentration Factor
BMF
Biomagnification factor
CAA
Clean Air Act
CASRN
Chemical Abstracts Service Registry Number
CBI
Confidential Business Information
CCL
Contaminant Candidate List
CDR
Chemical Data Reporting
CEHD
Chemical Exposure Health Data
CEPA
Canadian Environmental Protection Act
CERCLA
Comprehensive Environmental Response, Compensation and Liability Act
CFR
Code of Federal Regulations
COC
Concentration of Concern
CSCL
Chemical Substances Control Law
CWA
Clean Water Act
EC
Engineering Controls
ECB
European Chemicals Bureau
ECHA
European Chemicals Agency
EPA
Environmental Protection Agency
EPCRA
Emergency Planning and Community Right-to-Know Act
GACT
Generally Available Control Technology
ERG
Eastern Research Group
ESD
Emission Scenario Document
EU
European Union
FDA
Food and Drug Administration
FR
Federal Register
FYI
For Your Information
GDIT
General Dynamics Information Technology
GS
Generic Scenario
HAP
Hazardous Air Pollutant
HHE
Health Hazard Evaluation
HSDB
Hazardous Substances Data Bank
IARC
International Agency for Research on Cancer
ICES
International Council for the Exploration of the Sea
ICF
ICF is a global consulting services company
IECCU
Indoor Environmental Concentrations in Buildings with Conditioned and Unconditioned

Zones
IMAP
Inventory Multi-Tiered Assessment and Prioritisation (Australia)
IRIS
Integrated Risk Information System
ISHA
Industrial Safety and Health Act
Koc
Organic Carbon: Water Partition Coefficient
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Kow
Octanol: Water Partition Coefficient
LOEC
Lowest Observed Effect Concentration
MACT
Maximum Achievable Control Technology
MOA
Mode of Action
MSW
Municipal Solid Waste
NAICS
North American Industry Classification System
NICNAS
National Industrial Chemicals Notification and Assessment Scheme (Australia)
NIOSH
National Institute for Occupational Safety and Health
NOEC
No Observed Effect Concentration
NPDES
National Pollutant Discharge Elimination System
NPL
National Priorities List
NPRI
National Pollutant Release Inventory
NTP
National Toxicology Program
OCSPP
Office of Chemical Safety and Pollution Prevention
OECD
Organisation for Economic Co-operation and Development
OEHHA
Office of Environmental Health Hazard Assessment (California)
ONU
Occupational Non-User
OPPT
Office of Pollution Prevention and Toxics
OSHA
Occupational Safety and Health Administration
p-chem
Physical and Chemical
PBPK
Physiologically Based Pharmacokinetic
PEL
Permissible Exposure Limit
PESS
Potentially Exposed or Susceptible Subpopulations
POTW
Publicly Owned Treatment Works
PPE
Personal Protective Equipment
RAD
Risk Assessment Division
RCRA
Resource Conservation and Recovery Act
REACH
Registration, Evaluation, Authorisation and Restriction of Chemicals (European Union)
SARA
Superfund Amendments and Reauthorization Act
SDS
Safety Data Sheet
SDWA
Safe Drinking Water Act
SRC
SRC Inc., formerly Syracuse Research Corporation
STEL
Short-term Exposure Limit
TBD
To be determined
TIAB
Title and Abstract
TSCA
Toxic Substances Control Act
TLV
Threshold Limit Value
TMF
Trophic Magnification Factors
TRI
Toxics Release Inventory
TWA
Time-weighted average
UMCR
Unregulated Contaminants Monitoring Rule
USGS
United States Geological Survey
VOC
Volatile Organic Compound
VP
Vapor Pressure
WWT
Wastewater Treatment

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EXECUTIVE SUMMARY
In December 2019, EPA designated 1,3-butadiene (CASRN 106-99-0) as a high-priority substance for
risk evaluation following the prioritization process required by section 6(b) of the Toxic Substances
Control Act (TSCA) and implementing regulations (40 CFR Part 702) (Docket ID: EPA-HQ-OPPT-
2018-0451). The first step of the risk evaluation process is the development of the scope document and
this document fulfills the TSCA regulatory requirement to issue a draft scope document as described in
40 CFR 702 JX The draft scope for 1,3-butadiene includes the following information: the
conditions of use, potentially exposed or susceptible subpopulations (PESS), hazards, and exposures that
EPA plans to consider in this risk evaluation, along with a description of the reasonably available
information, conceptual model, analysis plan and science approaches, and plan for peer review for this
chemical substance. EPA is providing a 45-day comment period on the draft scope. Comments received
on this draft scope document will help inform development of the final scope document and the risk
evaluation.
General Information. 1,3-Butadiene is a colorless gas with a total production volume in the United
States between 1 and 5 billion pounds.
Reasonably Available Information. EPA leveraged the data and information sources already described
in the document supporting the High-Priority Substance designation for 1,3-butadiene to inform the
development of this draft scope document. To further develop this draft scope document, EPA
conducted a comprehensive search to identify and screen multiple evidence streams (i.e., chemistry, fate,
release and engineering, exposure, hazard) and the search and screening results are provided in Section
2.1. EPA is seeking public comment on this draft scope document and will consider additional
information identified following publication of this draft scope document, as appropriate, in developing
the final scope document. EPA is using the systematic review process described in the Application of
Systematic Review in TSCA Risk Evaluations document (U.S. EPA, 2018a) to guide the process of
searching for and screening reasonably available information, including information already in EPA's
possession, for use and inclusion in the risk evaluation. EPA applied these systematic review methods to
collect reasonably available information regarding hazards, exposures, PESS, and conditions of use that
will help inform the risk evaluation for 1,3-butadiene.
Conditions of Use. EPA plans to evaluate manufacturing, including importing; processing; distribution
in commerce; industrial, commercial and consumer uses; and disposal of 1,3-butadiene in the risk
evaluation. 1,3-Butadiene is manufactured within the U.S. as well as imported into the U.S. The
chemical is processed as a reactant, incorporated into a formulation, mixture, or reaction product, and
incorporated into articles. The identified processing activities also include the repackaging and recycling
of 1,3-butadiene. Several industrial and commercial uses were identified that ranged from use in plastic
and rubber products to use in lubricants. Only two consumer uses were reported in plastic and rubber
products and automotive care products. EPA identified these conditions of use from information
reported to EPA through Chemical Data Reporting (CDR) and Toxics Release Inventory (TRI)
reporting, published literature, and consultation with stakeholders both for uses currently in production
and used. Section 2.2 provides details regarding the conditions of use within the scope of the risk
evaluation. In addition, EPA plans to analyze distribution in commerce and disposal as part of the risk
evaluation.
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Conceptual Model The conceptual models for 1,3-butadiene are presented in Section 2.6. Conceptual
models are graphical depictions of the actual or predicted relationships of conditions of use, exposure
pathways (e.g., media), exposure routes (e.g., inhalation, dermal, oral), hazards, and receptors
throughout the life cycle of the chemical substance - from manufacturing, processing, distribution in
commerce, storage, or use, to release or disposal. EPA plans to focus the risk evaluation for 1,3-
butadiene on the following exposures, hazards, and receptors, however, EPA also plans to consider
comments received on this draft scope and other reasonably available information when finalizing this
scope document, and to adjust the exposure pathways, exposure routes and hazards included in the scope
document as needed.
• Exposures (Pathways and Routes), Receptors and PESS. EPA plans to analyze both human and
environmental exposures resulting from the conditions of use of 1,3-butadiene that EPA plans to
consider in risk evaluation. Exposures to 1,3-butadiene are discussed in Section 2.3. EPA
identified environmental monitoring data reporting the presence of 1,3-butadiene in air, drinking
water, and groundwater. 1,3-Butadiene is subject to reporting to EPA's Toxics Release Inventory
(TRI), which is reasonably available information that EPA anticipates using to inform 1,3-
butadiene's environmental release assessment. For the 2018 reporting year, 188 facilities
reported to EPA releases of 1,3-butadiene to air, water, and via land disposal. Additional
information gathered through systematic review searches will also inform expected exposures.
EPA's plan as to evaluating environmental exposure pathways in the draft scope document
considers whether and how other EPA-administered statutes and regulatory programs address the
presence of 1,3-butadiene in media pathways falling under the jurisdiction of those authorities.
Section 2.6.3 discusses those pathways that may be addressed pursuant to other Federal laws. In
Section 2.6.4, EPA presents the conceptual model describing the identified exposure (pathways
and routes), receptors and hazards associated with the conditions of use of 1,3-butadiene within
the scope of the risk evaluation:
Preliminarily, EPA plans to evaluate the following human and environmental exposure
pathways, routes, receptors and PESS in the scope of the risk evaluation. However, EPA plans to
consider comments received on this draft scope and other reasonably available information when
finalizing this scope document, and to adjust the exposure pathways, exposure routes and
hazards included in the scope document as needed.
-	Occupational exposures associated with industrial and commercial conditions of use:
EPA plans to evaluate exposures to workers and/or occupational non-users via the
inhalation route and exposures to workers via the dermal route associated with the
manufacturing, processing, use or disposal of 1,3-butadiene (Section 2.2.1).
-	Consumer and bystander exposures associated with consumer conditions of use: EPA
plans to evaluate inhalation exposures to 1,3-butadiene vapor for consumers and
bystanders during use and disposal of automotive care products, and plastics and rubber
products. EPA plans to evaluate dermal exposure to 1,3-butadiene for consumers but not
for bystanders. EPA does not plan to evaluate oral exposures to 1,3-butadiene.
-	General population exposures: EPA plans to evaluate exposure to 1,3-butadiene via
groundwater and fish ingestion for the general population.
-	Environmental exposures: EPA plans to evaluate exposure to 1,3-butadiene for aquatic
and terrestrial receptors.
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- Receptors andPESS: EPA plans to evaluate children, women of reproductive age,
pregnant women, workers, and consumers as receptors and PESS in the risk evaluation.
• Hazards. Hazards for 1,3-butadiene are discussed in Section 2.4. EPA completed preliminary
reviews of information from peer-reviewed assessments and databases to identify potential
environmental and human health hazards for 1,3-butadiene as part of the prioritization process.
Although EPA did not identify environmental hazard information during the prioritization
process, EPA is in the process of identifying additional reasonably available information through
systematic review methods and public comments that may inform potential environmental
hazards associated with 1,3-butadiene exposure.
EPA plans to use systematic review methods to evaluate the epidemiological and toxicological
literature for 1,3-butadiene. Relevant mechanistic evidence will also be considered, if reasonably
available, to inform the interpretation of findings related to potential human health effects and
the dose-response assessment. EPA plans to evaluate all the potential human health hazards for
1,3-butadiene identified during prioritization. The broad health effect categories include
reproductive and developmental, immunological, nervous system, and irritation effects. Studies
were identified that reported information on genotoxicity, carcinogenicity, and ADME.
Analysis Plan. The analysis plan for 1,3-butadiene is presented in Section 2.7. The analysis plan
outlines the general scientific approaches that EPA plans to use for the various information streams (i.e.,
chemistry, fate, release and engineering, exposure, hazard) supporting the risk evaluation. The analysis
plan is based on EPA's knowledge of 1,3-butadiene to date which includes a partial, but ongoing, review
of identified information as described in Section 2.1. EPA plans to continue to consider new information
submitted by the public. Should additional data or approaches become reasonably available, EPA may
update its analysis plan in the final scope document.
EPA plans to seek public comments on the systematic review methods supporting the risk evaluation for
1,3-butadiene, including the methods for assessing the quality of data and information and the approach
for evidence synthesis and evidence integration supporting the exposure and hazard assessments. The
details will be provided in a supplemental document that EPA anticipates releasing for public comment
prior to the finalization of the scope document.
Peer Review. The draft risk evaluation for 1,3-butadiene will be peer reviewed. Peer review will be
conducted in accordance with relevant and applicable methods for chemical risk evaluations, including
using EPA's Peer Review Handbook and other methods consistent with section 26 of TSCA (See 40
CFR 702.451
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1 INTRODUCTION
This document presents for comment the draft scope of the risk evaluation to be conducted for 1,3-
butadiene under the Frank R. Lautenberg Chemical Safety for the 21st Century Act. The Frank R.
Lautenberg Chemical Safety for the 21st Century Act amended the Toxic Substances Control Act
(TSCA) on June 22, 2016. The new law includes statutory requirements and deadlines for actions related
to conducting risk evaluations of existing chemicals.
TSCA § 6(b) the Environmental Protection Agency (EPA) must designate chemical substances as high-
priority substances for risk evaluation or low-priority substances for which risk evaluations are not
warranted at the time, and upon designating a chemical substance as a high-priority substance, initiate a
risk evaluation on the substance. TSCA § 6(b)(4) directs EPA, in conducting risk evaluations for
existing chemicals, to "determine whether a chemical substance presents an unreasonable risk of injury
to health or the environment, without consideration of costs or other non- risk factors, including an
unreasonable risk to a potentially exposed or susceptible subpopulation identified as relevant to the risk
evaluation by the Administrator, under the conditions of use."
TSCA § 6(b)(4)(D) and implementing regulations require that EPA publish the scope of the risk
evaluation to be conducted, including the hazards, exposures, conditions of use and PESS that the
Administrator expects to consider within 6 months after the initiation of a risk evaluation. In addition, a
draft scope is to be published pursuant to 40 CFR 702.41. In December 2019, EPA published a list of 20
chemical substances that have been designated high-priority substances for risk evaluations (Docket ID:
EP A-HQ-OPPT-2018-0451). as required by TSCA § 6(b)(2)(B). 1,3-Butadiene is one of the chemicals
designated as a high-priority substance for risk evaluation.
2 SCOPE OF THE EVALUATION
2.1 Reasonably Available Information
EPA conducted a comprehensive search for reasonably available information1 to support the
development of this draft scope document for 1,3-butadiene. EPA leveraged the data and information
sources already identified in the documents supporting the chemical substance's high-priority substance
designation. In addition, EPA searched for additional data and information on physical and chemical
properties, environmental fate, engineering, exposure, environmental and human health hazards that
could be obtained from the following general categories of sources:
1.	Databases containing publicly available, peer-reviewed literature;
2.	Gray literature, which is defined as the broad category of data/information sources not found in
standard, peer-reviewed literature databases.
3.	Data and information submitted under TSCA sections 4, 5, 8(e), and 8(d), as well as "for your
information" (FYI) submissions.
Following the comprehensive search, EPA performed a title and abstract screening to identify
information potentially relevant for the risk evaluation process. This step also classified the references
into useful categories or tags to facilitate the sorting of information through the systematic review
process. The search and screening process was conducted based on EPA's general expectations for the
1 Reasonably available information means information that EPA possesses or can reasonably generate, obtain, and synthesize
for use in risk evaluations, considering the deadlines specified in TSCA section 6(b)(4)(G) for completing such evaluation.
Information that meets the terms of the preceding sentence is reasonably available information whether or not the information
is confidential business information, that is protected from public disclosure under TSCA section 14 (40 CFR 702.33).

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planning, execution and assessment activities outlined in the Application of Systematic Review in TSCA
Risk Evaluations document (U.S. EPA. 2018a). EPA plans to publish supplemental documentation on
the systematic review methods supporting the 1,3-butadiene risk evaluation to explain the literature and
screening process presented in this document in the form of literature inventory trees. Please note that
EPA focuses on the data collection phase (consisting of data search, data screening, and data extraction)
during the preparation of the TSCA scope document, whereas the data evaluation and integration stages
will occur during the development of the draft risk evaluation and thus are not part of the scoping
activities described in this document.
The subsequent sections summarize the data collection activities completed to date for the general
categories of sources and topic areas (or disciplines) using systematic review methods. EPA plans to
seek public comments on the systematic review methods supporting the risk evaluation for 1,3-butadiene
upon publication of the supplemental documentation of those methods.
2.1A_ Search of Gray Literature
EPA surveyed the gray literature2 and identified 276 search results relevant to EPA's risk assessment
needs for 1,3-butadiene. Table Apx A-l lists the gray literature sources that yielded 276 discrete data or
information sources relevant to 1,3-butadiene. EPA further categorized the data and information into the
various topic areas (or disciplines) supporting the risk evaluation (e.g., physical chemistry,
environmental fate, ecological hazard, human health hazard, exposure, engineering) and the breakdown
is shown in Figure 2-1. EPA is currently identifying additional reasonably available information (e.g.,
public comments), and the reported numbers in Figure 2-1 may change.
PhysicaLChemical
I Iumaii. I lealth. Hazard
u
• 3	Fate
a
u
g	Exposure
Environmental. I Iazard
Engineering
Gray Literature Tags by Discipline
43/276
83/276
31/276
158/276
11/276
187/276
25	50
Percent Tagged (%
75
100
Figure 2-1 Gray Literature Search Results for 1,3-Butadiene
The percentages across disciplines do not add up to 100%, as each source may provide data or information for various topic
areas (or disciplines).
2 Gray literature is defined as the broad category of data/information sources not found in standard, peer-reviewed literature
databases (e.g., PubMed and Web of Science). Gray literature includes data/information sources such as white papers,
conference proceedings, technical reports, reference books, dissertations, information on various stakeholder websites, and
other databases.
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2.1.2 Search of Literature from Publicly Available Databases (Peer-Reviewed
Literature)
EPA is currently conducting a systematic review of the reasonably available literature. This includes
performing a comprehensive search of the reasonably available peer review literature on physical-
chemical properties, environmental fate and transport, engineering (environmental release and
occupational exposure), exposure (environmental, general population and consumer) and environmental
and human health hazards of 1,3-butadiene. Eligibility criteria were applied in the form of PECO
(population, exposure, comparator, outcome) statements. Included references met the PECO criteria,
whereas excluded references did not meet the criteria (i.e., not relevant), and supplemental material was
considered as potentially relevant. EPA plans to analyze the reasonably available information identified
for each discipline during the development of the risk evaluation. The literature inventory trees depicting
the number of references that were captured and those that were included, excluded, or tagged as
supplemental material during the screening process for each discipline area are shown in Figure 2-2.
Peer-reviewed Literature - Physical-Chemical Properties Search Results for 1,3-Butadiene, through
Figure 2-6. "TIAB" in these figures refer to "title and abstract" screening. Note that in some of the
figures the sum of the numbers for the various sub-categories may be larger than the broader category
because some studies may be included under multiple sub-categories. In other cases, the sum of the
various sub-categories may be smaller than the main category because some studies may not be depicted
in the sub-categories if their relevance to the risk evaluation was unclear.
Boiling Point
Water Solublity
Henry's Law Constant
Vapor Pressure
Vapor Density
Retrieved for Full-text
Review
included for Data
Extraction and Data
Evaluation
Dielectric Constant
2663
Refractive Index
Total for TIAB:
P-Chem
-»( 2658
Supplemental Information
Exclusion
Exclusion
Figure 2-2. Peer-reviewed Literature - Physical-Chemical Properties Search Results for 1,3-
Butadiene.
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©
Bioconcentration, Biomagnification, etc.
Q
Biodegradation
®
Hydrolysis
@
Photolysis
©
Sorption
©
Volatilization
©
Wastewater Treatment
0
Other
Figure 2-3. Peer-reviewed Literature - Fate and Transport Search Results for 1,3-Butadiene.
Click here for interactive Health Assessment Workplace Collaborative (HAWC) Diagram.
14
®
Included
3218
3279
TSCA Fate BTD (2020) X	Excluded
©
Supplemental

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S„<£
Figure 2-4. Peer-reviewed Literature - Engineering Search Results for 1,3-Butadiene
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aquatic species (14)
biosolids/sludge (6)
foreign language (20)
consumer uses and/or products (84)
drinking water (2)
Supplemental (349)
dietary (6)
ambient air (331)
epidemiological/biomonitoring study (82)
Unique HERO IDs (1850)
~4 Excluded (1029)
PECO relevant (300)
~j ground water (13)
Included (472)
Unclear (172)
indoor air (102)
sediment (16)
soil (11)
surface water (39)
terrestrial species (6)
Figure 2-5. Peer-reviewed Exposure Search Results for 1,3-Butadiene
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Human Health Model
Human
Artima
Ecotoxicological Model
Retrieved for Full-text
Review
Total for TIAB:
Hazard
M 9203
Exclusion
Mixture
Case Report/Series
-*©
Conference Abstract
	
Field Study
r—
Mechanistic
Supplemental
Material
Non-English Record
V	
No Original Daia
o
PECO-relevant Isomer
¦*©
Susceptible Population
Figure 2-6. Peer-reviewed Hazard Search Results for 1,3-Butadiene
2.1.3 Search of TSCA Submissions
Table 2-1 presents the results of screening the titles of data sources and reports submitted to EPA under
various sections of TSCA. EPA screened a total of 109 submissions using inclusion and exclusion
criteria specific to individual disciplines (see Table 2-1 for the list of disciplines). The details about the
criteria are not part of this document but will be provided in a supplemental document that EPA
anticipates releasing prior to the finalization of the scope document.
EPA identified 92 submissions that met the inclusion criteria and identified 18 submissions with
supplemental human health data. EPA excluded 17 submissions because the reports were identified as
one of the following:
• Published report that would be identified via other peer or gray literature searches
17

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•	Summary of other reports
•	Preliminary report of a final available submitted report
•	Duplicate of another report
•	Submission on a different chemical
•	List of references with no original data
EPA plans to conduct additional deduplication at later stages of the systematic review process (e.g., full-
text screening), when more information regarding the reports is available.
Table 2-1. Results of Title Screening of Submissions to EPA
Jnder Various Sections of TSCA
Discipline
Included
Supplemental
Physicochemical Properties
1
0
Environmental Fate and
0
0
Transport


Environmental and General
14
0
Population Exposure


Occupational Exposure/Release
Information
34
0
Environmental Hazard
0
0
Human Health Hazard
43
18
2.2 Conditions of Use
As described in the Promised Designation of 1,3-Butadiem (CASRN106-99-0) as a High-Priority
Substance for Risk Evaluation (U.S. EPA 2019a), EPA assembled information from the CDR and TRI
programs to determine conditions of use3 or significant changes in conditions of use of the chemical
substance. EPA also consulted a variety of other sources to identify uses of 1,3-butadiene, including:
published literature, company websites, and government and commercial trade databases and
publications. To identify formulated products containing 1,3-butadiene, EPA searched for safety data
sheets (SDS) using internet searches, EPA Chemical and Product Categories (CPCat) data, and other
resources in which SDSs could be found. In addition, EPA incorporated communications with
companies, industry groups, environmental organizations, and public comments to supplement the
conditions of use information.
EPA identified and described the categories and subcategories of conditions of use that EPA plans to
include in the scope of the risk evaluation (Section 2.2.1; Table 2-2). The conditions of use that EPA
plans to include in the scope are those reflected in the life cycle diagrams and conceptual models.
After gathering reasonably available information related to the manufacture, processing, distribution in
commerce, use, and disposal of 1,3-butadiene, EPA identified those categories or subcategories of use
activities for 1,3-butadiene the Agency determined not to be conditions of use or will otherwise be
excluded during scoping. These categories and subcategories are described in Section 2.2.2.
2.2.1 Categories and Subcategories of Conditions of Use Included in the Scope of the
Risk Evaluation
Table 2-2 lists the conditions of use that are included in the scope of the risk evaluation.
3 Conditions of use means the circumstances, as determined by the Administrator, under which a chemical substance is
intended, known, or reasonably foreseen to be manufactured, processed, distributed in commerce, used, or disposed of.
18

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Table 2-2. Categories and Subcategories of Conditions of Use Included in the Scope of the Risk
Evaluation
l.il'c Cycle Slsi«e
C:ilc«i<>r\
SiihciHe»orv
Ueferences
Manufacture
Domestic
manufacturing
Domestic manufacturing
U.S. EPA (2019b)
Importing
Importing
U.S. EPA (2019b)
Processing
Processing as a
reactant
Other: Fuel binder for solid
rocket fuels in: Aerospace
U.S. EPA (2019b)
Intermediate in: Adhesive
manufacturing; All other basic
organic chemical
manufacturing; Organic fiber
manufacturing; Petrochemical
manufacturing; Petroleum
refineries; Plastic material and
resin manufacturing; Synthetic
rubber manufacturing;
Wholesale and retail trade
U.S. EPA (2019b)
Other: Monomer used in
polymerization process in:
Plastic material and resin
manufacturing; Manufacturing
synthetic rubber and plastics
U.S. EPA ("2019b* EPA-HO-
OPPT-2018-0451-0004
Plasticizers in: Plastic material
and resin manufacturing
U.S. EPA (2019b)
Solvents (which become part of
product formulation or mixture)
in: Synthetic rubber
manufacturing
U.S. EPA (2019b)
Processing -
incorporation
into formulation,
mixture, or
reaction product
Processing aids, not otherwise
listed in: Petrochemical
manufacturing
U.S. EPA (2019b)
Other: Adhesive
manufacturing, paints and
coatings manufacturing,
petroleum lubricating oil and
grease manufacturing, and all
other chemical product and
preparation manufacturing
EP A-HO-OPPT-2018-0451 -
0003; EP A-HO-OPPT-20 '18-
0451 -0005; EPA-HO-OPPT-
2018-0451 -0009; EPA-HO-
OPP' 2
Processing -
incorporation
into article
Other: Polymer in: Rubber
product manufacturing
U.S. EPA (2019b)
Repackaging
Intermediate in: Wholesale and
retail trade
U.S. EPA (2019b)
Recycling
Recycling
U.S. EPA (2019b); TRI (2017)
Distribution in
commerce
Distribution in
commerce
Distribution in commerce (e.g.,
Sold to a trader; Sold to re-
U.S. EPA (2019b)

-------
l.il'c Cycle Slsi«e
C:ilc«i<>ry
SiihciHe»ory
Ucfcrcnccs


sellers for petroleum fuel and
petrochemical industry in:
Petrochemical manufacturing)

Industrial Use
Adhesives and
sealants
Adhesives and sealants
EP A-HO-OPPT-2018-1
0003; EPA-HO-OPP f 201S -
K I 1 cvm { V\ KO-OPPT-
2018-0451 -0009; EPA-HO-
2
Processing
aids, specific
to petroleum
production
Hydraulic fracturing
U.S. EPA (2016)
Commercial Use
Fuels and related
products
Fuels and related products
U.S. EPA (2019b)
Plastic and
rubber products
not covered
elsewhere
Plastic and rubber products not
covered elsewhere, including
rubber tires
U.S. EPA (2019b); EPA-HO-
OPPT-2018-0451-0003
Automotive care
products
Automotive care products
U.S. EPA (2019b)
Other use
Monomer used in
polymerization process
U.S. EPA C2019b); EPA-HO-
OPPT-2018-*•' s i
Laboratory chemicals
Sigma-Aldrich (2020)
Lubricants and
lubricant
additives
Lubricant additives, including
viscosity modifier
FJM
000
013
i-HO-GPPT-2018-0451-
3; EP A-HO-OPPT-2019-
1-0022
Paints and
coatings
Paints and coatings, including
aerosol spray paint
EP
000.
i-HO-OP
5; EP A-HO-OPPT-2019-
1-0022.
Adhesives and
sealants
Adhesives and sealants
EP A-HO-OPPT-2018-1
0003; EPA-HO-OP
0451-00'{ P VKO-OPPT-
2 2
Consumer Use
Plastic and
rubber products
not covered
elsewhere
Plastic and rubber products not
covered elsewhere, including
rubber tires
U.S. EPA C2019b); EPA-HO-
OPPWi m
Automotive care
products
Automotive care products
U.S. EPA (2019b)
Disposal
Disposal
Disposal

Life Cycle Stage Use Definitions (40 CFR § 711.3)
-	"Industrial use" means use at a site at which one or more chemicals or mixtures are manufactured (including
imported) or processed.
-	"Commercial use" means the use of a chemical or a mixture containing a chemical (including as part of an article)
in a commercial enterprise providing saleable goods or services.
-	"Consumer use" means the use of a chemical or a mixture containing a chemical (including as part of an article,
such as furniture or clothing) when sold to or made available to consumers for their use.
20

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I.il'c Cvclc Slsi«c
C:ile"orv
Suhc:ile"orv
Ucl'orcncos
Although EPA has identified both industrial and commercial uses here for purposes of distinguishing scenarios in this
document, the Agency interprets the authority over "any manner or method of commercial use" under TSCA section
6(a)(5) to reach both.
"Monomer used in polymerization process," as reported to the 2016 CDR under commercial use, indicates processing of
1,3-butadiene for a polymerization reaction. This reported use will be evaluated under processing as a reactant.
2.2.2 Activities Excluded from the Scope of the Risk Evaluation
As explained in the final rule, Procedures for Chemical Risk Evaluation Under the Amended Toxic
Substances Control Act, TSCA section 6(b)(4)(D) requires EPA to identify the hazards, exposures,
conditions of use, and the PESS the Administrator expects to consider in a risk evaluation, suggesting
that EPA may exclude certain activities that it determines to be conditions of use on a case-by-case basis
(82 FR 33726, 33729; July 20, 2017). TSCA section 3(4) also grants EPA the authority to determine
what constitutes a condition of use for a particular chemical substance. EPA does not plan to include in
this scope or in the risk evaluation the activities described below that the Agency has concluded do not
constitute conditions of use.
Organizations submitted docket comments to EPA regarding the presence of 1,3-butadiene in smoke
from tobacco (EPA-HQ-OPPT-2018-0451-0016) and smoke from wildfires (EPA-HO-QPPT-2018-
), but these activities and releases are not TSCA conditions of use and will not be evaluated
during the risk evaluation. TSCA's definition of "chemical substance"4 separately excludes tobacco
(TSCA section 3(2)(B)(iii)) and tobacco use is therefore outside the scope of TSCA. Wildfires are also
outside the scope of the risk evaluation because there is no condition of use for 1,3-butadiene (i.e.,
manufacture, processing, distribution in commerce, use, or disposal) associated with wildfire activity.
2.2.3	Production Volume
As reported to EPA during the 2016 CDR reporting period and described here as a range to protect
production volumes that were claimed as confidential business information (CBI), total production
volume of 1,3-butadiene in 2015 was between 1 billion and 5 billion pounds (U.S. EPA 2017a). EPA
also uses pre-2015 CDR production volume information, as detailed in the Proposed Designation of 1,3-
Butadiene fCASRN 106-99-0) as a High-Priority Substance for Risk Evaluation (U.S. EPA 2019a) and
will include future production volume information as it becomes available to support the exposure
assessment.
2.2.4	Overview of Conditions of Use and Lifecycle Diagram
The life cycle diagram provided in Figure 2-7 depicts the conditions of use that EPA plans to consider in
the risk evaluation for the various life cycle stages. This section provides a brief overview of the
4 Chemical substance means any organic or inorganic substance of a particular molecular identity, including any combination
of such substances occurring in whole or in part as a result of a chemical reaction or occurring in nature, and any element or
uncombined radical. Chemical substance does not include (1) any mixture; (2) any pesticide (as defined in the Federal
Insecticide, Fungicide, and Rodenticide Act) when manufactured, processed, or distributed in commerce for use as a
pesticide; (3) tobacco or any tobacco product; (4) any source material, special nuclear material, or byproduct material (as
such terms are defined in the Atomic Energy Act of 1954 and regulations issued under such Act); (5) any article the sale of
which is subject to the tax imposed by section 4181 of the Internal Revenue Code of 1954 (determined without regard to any
exemptions from such tax provided by section 4182 or 4221 or any other provision of such Code), and; (6) any food, food
additive, drug, cosmetic, or device (as such terms are defined in section 201 of the Federal Food, Drug, and Cosmetic Act)
when manufactured, processed, or distributed in commerce for use as a food, food additive, drug, cosmetic, or device.
21

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industrial, commercial, and consumer use categories included in the life cycle diagram. Appendix E
contains more detailed descriptions (e.g., process descriptions, worker activities) for each
manufacturing, processing, distribution in commerce, use, and disposal category based on preliminary
information.
The information in the life cycle diagram is grouped according to the CDR processing codes and use
categories (including functional use codes for industrial uses and product categories for commercial and
consumer uses).5
5 The descriptions are primarily based on the corresponding industrial function category and/or commercial and consumer
product category descriptions and can be found in EPA's Instructions for Reporting 20.1.6 TSCA Chemical Data Reporting.
22

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MFG/IMPORT
PROCESSING
INDUSTRIAL, COMMERCIAL, CONSUMER USE RELEASES and WASTE DISPOSAL
Manufacture
(Including
Import)
(1 B - 5 B lbs)
Processing as Reactant
(Intermediate in: Adhesive manufacturing; All
other basic organic chemical manufacturing:
Organic fiber manufacturing: Petrochemical
manufacturing; Petroleum refineries; Plastic
material and resin manufacturing; Synthetic
rubber manufacturing; Monomer in: Plastics
material and resin manufacturing; Synthetic
rubber manufacturing; Other: binder for rocket
propellant; Plasticizers in: Synthetic rubber
manufacturing. Solvent in: Synthetic rubber
manufacturing;)
Incorporation into Formulation, Mixture,
or Reaction Product (Processing aids:
Petrochemical manufacturing; Other: Adhesive
manufacturing, paints and coatings
manufacturing, petroleum lubricating oil and
grease manufacturing, and all other chemical
product and preparation manufacturing)
Incorporation into Article
(Polymer in: Rubber product manufacturing)
Repackaging
3
Adhesive and Sealants1
Automotive Care Products1,2
Fuel and Related Products1
Laboratory Chemicals1
Lubricants and lubricant additives1
Paints and Coatings1
(e.g., Asphalt Emulsion Coating)
Plastic and Rubber Products1>2
(e.g., mbber tires)
Processing aids, specific to Petroleum
production1
(e.g., hydraulic fluid)
¦4
Disposal
Recycling
See Conceptual Mode!for
Environmental Releases and Wastes
j [ Manufacture (Including Import)
~ Processing
~
Uses.
1.	Industrial and/or commercial
2.	Consumer
Figure 2-7. 1,3-Butadiene Life Cycle Diagram
Volume is not depicted in the life cycle diagram for processing and industrial, commercial, and consumer uses as specific production volume is claimed confidential
business information (CBI) or withheld pursuant to TSCA section § 14.
23

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2.3 Exposures
For TSCA exposure assessments, EPA plans to analyze exposures and releases to the environment
resulting from the conditions of use within the scope of the risk evaluation for of 1,3 -butadiene. Release
pathways and routes will be described to characterize the relationship or connection between the
conditions of use of the chemical and the exposure to human receptors, including potentially exposed or
susceptible subpopulations, and environmental receptors. EPA plans to consider, where relevant, the
duration, intensity (concentration), frequency, and number of exposures in characterizing exposures to
1,3-butadiene.
2.3.1	Physical and Chemical Properties
Physical and chemical properties are essential for a thorough understanding or prediction of
environmental fate (i.e., transport and transformation) and the eventual environmental concentrations.
They can also inform the hazard assessment. EPA plans to use the physical and chemical properties
described in the Proposed Designation of 1,3-Butadiene (CASRN 106-99-0) as a Hish-Priority
Substance for Risk Evaluation (reference) to support the development of the risk evaluation for 1,3-
butadiene. The values for the physical and chemical properties (Appendix B) may be updated as EPA
collects additional information through systematic review methods.
2.3.2	Environmental Fate and Transport
Understanding of environmental fate and transport processes assists in the determination
of the specific exposure pathways and potential human and environmental receptors that need to be
assessed in the risk evaluation for 1,3-butadiene. EPA plans to use the environmental fate characteristics
described in Appendix C of the Proposed Designation o f 1,3-Butadiene (CASRN106-99-0) as a High-
Priority Substance for Risk Evaluation (U.S. EPA 2019) to support the development of the risk
evaluation for 1,3-butadiene. The values for the environmental fate properties (Appendix C) may be
updated as EPA collects additional information through systematic review methods.
2.3.3	Releases to the Environment
Releases to the environment from conditions of use (e.g., manufacturing, industrial and commercial
processes, commercial or consumer uses) are a component of potential exposure and may be derived
from reported data that are obtained through direct measurement, calculations based on empirical data or
assumptions and models.
A source of information that EPA plans to consider in evaluating exposure are data reported to the
Toxics Release Inventory (TRI) program. EPA's TRI database contains information on chemical waste
management activities that are reported to EPA by industrial and federal facilities, including quantities
released into the environment (i.e., to air, water, and disposed of to land), treated, burned for energy,
recycled, or transferred off-site to other facilities for these purposes.
Under Section 313 of the Emergency Planning and Community Right-to-Know Act (EPCRA) 1,3-
butadiene is a TRI-reportable substance effective January 1, 1987 (40 CFR 372.65). For TRI reporting,6
facilities in covered sectors in the United States are required to disclose release and other waste
management activity quantities of 1,3-butadiene under the CASRN 106-99-0 if they manufacture
(including import) or process more than 25,000 pounds or otherwise use more than 10,000 pounds of the
chemical in a given year by July 1 of the following year.
6 For TRI reporting criteria see https://www.epa.gov/toxics-release-inventore-tri-prograin/basics-tri-reporting
24

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Table 2-3 provides production-related waste management data for 1,3-butadiene reported by facilities to
the TRI program for reporting year 2018. As shown in the table, 188 facilities reported a total of nearly
114 million pounds of 1,3-butadiEene production-related waste managed in 2018. Of this total, roughly
equal amounts were recycled or treated (49 million pounds or 43% each). Quantities of 1,3-butadiene
burned for energy recovery or released to the environment accounted for 15 million pounds (13%) and
1.2 million pounds (1%) of the total, respectfully. Overall, nearly all production-related waste of 1,3-
butadiene was managed on site, with only 2.4% managed off site.
Table 2-3. Summary of 1,3-Butadiene TRI Production-related Waste Managed in 2018
Year
Number of
l-'acilities
Recycled
(lbs)
Recovered
for
Knergy
(lbs)'
Treated
(lbs)
Released11"
(lbs)
Tolal
Product ion
Related Waste
(lbs)
2018
188
48,924,121
14,931,906
48,818,860
1,236,393
113,911,280
Data source: 2018 TRI Data (Updated November 2019)
3 Terminology used in these columns may not match the more detailed data element names used in the TRI public data and analysis access points.
b Does not include releases due to one-time event not associated with production such as remedial actions or earthquakes.
c Counts all releases including release quantities transferred and release quantities disposed of by a receiving facility reporting to TRI.
Table 2-4 provides a summary of the quantities of 1,3-butadiene released to the environment during
2018 as reported to TRI.7 Of the total quantity released to the environment during 2018, 98% was
released to air. Roughly three-quarters of these air emissions originated from point sources, with the
remainder from fugitive sources. Land disposal accounted for nearly all remaining releases, with 93%
disposed of on-site to Class I underground injection wells. Overall, more than 99% of disposal and other
releases of 1,3-butadiene to the environment occurred on site.
Table 2-4. Summary of Releases of 1,3-Butadiene to the Environment During 2018

Nil in her
ol
l-'sicililics
Air R«
Si sick Air
Rclcsiscs
(Ills)
¦Icsiscs
l"ii!iili\c
Air
Rclcsiscs
(ll)N)
\\ siler
Rclcsiscs
(Ihs)
1
(hiss 1
I ndcr-
limnnd
Injection
(Ihs)
.sind Dispos
R( RA
Subtitle (
I.siikMiIIs
(Ihs)
Sll
All oilier
I.siikI
Dispossil ¦'
(Ihs)
Oilier
Rclcsiscs •'
(Ihs)
lolsil
Rclcsiscs 1,1
(Ihs)
Totals
2018
188
918,009
303,486
248.98
22,340
34
1,698
10.715
1,245,827
1,221,495
24,073
Data source: 2018 TRI Data (Updated November 2019)
' Terminology used in these columns may not match the more detailed data element names used in the TRI public data and analysis access points.
b These release quantities do include releases due to one-time events not associated with production such as remedial actions or earthquakes.
c Counts release quantities once at final disposition, accounting for transfers to other TRI reporting facilities that ultimately dispose of the chemical waste.
While the production-related waste managed shown in Table 2-3 excludes any quantities reported as
catastrophic or one-time releases (TRI section 8 data), release quantities shown in Table 2-4 include
both production-related and non-production-related quantities. Approximately 9,660 pounds of 1,3-
7 Reporting year 2018 is the most recent TRI data available. Data presented in Table 2-3 were queried using TRI Explorer
and uses the 2018 National Analysis data set (released to the public in November 2019). This dataset includes revisions for
the years 1988 to 2018 processed by EPA.
25

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butadiene waste not related to production were reported for 2018. These waste quantities are included in
the total releases stated in Table 2-4.
EPA plans to review these data in conducting the exposure assessment component of the risk evaluation
for 1,3-butadiene.
2.3.4	Environmental Exposures
The manufacturing, processing, distribution, use, and disposal of 1,3-butadiene can result in releases to
the environment and exposure to aquatic and terrestrial receptors (biota). Environmental exposures to
biota are informed by releases into the environment, overall persistence, degradation, and
bioaccumulation, and partitioning across different media. Concentrations of chemical substances in biota
provide evidence of exposure. EPA plans to review reasonably available information on environmental
exposures in biota to inform development of the environmental exposure assessment for 1,3-butadiene.
2.3.5	Occupational Exposures
EPA plans to analyze worker activities where there is a potential for exposure under the various
conditions of use (manufacturing, processing, industrial/commercial uses and disposal) described in
Section 2.2. In addition, EPA plans to analyze exposure to occupational non-users (ONU's), workers
who do not directly handle the chemical but perform work in an area where the chemical is present. EPA
also expects to consider the effect(s) that engineering controls (EC) and/or personal protective
equipment (PPE) have on occupational exposure levels as part of the draft risk evaluation.
Worker activities associated with the conditions of use within the scope of the risk evaluation for 1,3-
butadiene that will be analyzed include, but are not limited to
•	Unloading and transferring 1,3-butadiene to and from storage containers to process vessels;
•	Handling, transporting and disposing of waste containing 1,3-butadiene;
•	Cleaning and maintaining equipment;
•	Sampling chemicals, formulations, or products containing 1,3-butadiene for quality control;
•	Repackaging chemicals, formulations, or products containing 1,3-butadiene;
•	Performing other work activities in or near areas where 1,3-butadiene is used.
Several commercial uses (adhesives, automotive care products, lubricant additive, and plastic and rubber
products) in Section 2.2 are reported to be downstream uses of the polymers produced using 1,3-
butadiene as a monomer (ACC, 2019a). Residual 1,3 butadiene in plastic and rubber products is
expected to be low, so occupational exposures for the commercial use of these products have been
reported to be low (ECB, 2002). Additional key data that EPA expects will inform occupational
exposure assessment include: OSHA Chemical Exposure Health Data (CEHD) and NIOSH Health
Hazard Evaluation (HHE) program data, presented in Appendix E.
1,3-Butadiene is a gas with a vapor pressure of 2,110 mm Hg (at 25 °C); hence, inhalation exposure is
expected to be a significant route of exposure for workers and ONU's from potential fugitive emissions.
Where mist generation is expected (e.g. spray application), EPA will also analyze inhalation exposure to
mist for workers and ONU. 1,3-Butadiene has an Occupational Safety and Health Administration
(OSHA) standard (29 CFR 1910.1051). The Permissible Exposure Limit (PEL) is 1 part per million
(ppm) over an 8-hour work day, time-weighted average (TWA), and there is a Short-Term Exposure
Limit (STEL) of 5 ppm (OSHA 2019V
26

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EPA generally does not evaluate occupational exposures through the oral route. Workers may
inadvertently transfer chemicals from their hands to their mouths, ingest inhaled particles that deposit in
the upper respiratory tract or consume contaminated food. The frequency and significance of this
exposure route are dependent on several factors including the p-chem properties of the substance during
expected worker activities, workers' awareness of the chemical hazards, the visibility of the chemicals
on the hands while working, workplace practices, and personal hygiene that is difficult to predict
(Cherrie et al., 2006). However, EPA will consider oral exposure on a case-by-case basis.
EPA plans to evaluate dermal exposure to workers for the conditions of use described in Section 2.2.
The manufacturing processes as described Appendix E are noted to include handling of 1,3-butadiene in
a pressurized liquid form within closed systems. Review of preliminary data sources suggest exposure
by dermal contact may be limited for these processes, information collected through systematic review
methods and public comments will help inform this assessment. ONU's do not directly handle 1,3-
butadiene; therefore, direct liquid contact with 1,3-butadiene is not expected for any condition of use.
2.3.6	Consumer Exposures
According to reports in the 2016 CDR, automotive care products, and plastic and rubber products
including synthetic rubbers, were identified as consumer products for 1,3-butadiene. Consumers using or
disposing of automotive care products may be exposed to 1,3-butadiene through direct liquid contact
which may lead to a dermal exposure, or through vapor emissions which may lead to inhalation
exposure, given its volatility at room temperature. In addition, consumers using or disposing of plastic
and rubber products may be exposed to 1,3-butadiene through vapor emissions which may lead to
inhalation exposure, given its volatility at room temperature. Bystanders present during the consumer
use of automotive care products, plastic, rubber products, or disposal of 1,3-butadiene may also be
exposed to vapor emissions leading to an inhalation exposure. Of note, 1,3-butadiene, a monomer used
in polymer-derived products such as synthetic rubbers, is stable and is not expected to degrade to the
1,3-butadiene monomer. Therefore, the potential for dermal exposure to 1,3-butadiene during consumer
use of articles produced from synthetic rubber may be negligible (ECHA 2019). EPA plans to evaluate
1,3-butadiene monomer, not the polymer which is expected to be stable in products. Based on these
potential sources and pathways of exposure, EPA plans to analyze inhalation and dermal routes of
exposures to consumers and the inhalation route of exposure to bystanders that may result from the
conditions of use of the 1,3-butadiene monomer. EPA does not plan to evaluate consumer exposures to
1,3-butadiene via the oral route since it is not expected given the expected consumer conditions of use.
2.3.7	General Population Exposures
Monitoring data were identified in EPA's data search for 1,3-butadiene and can be used in the exposure
assessment. Relevant and reliable monitoring studies provide information that can be used in an
exposure assessment. Monitoring studies that measure environmental concentrations or concentrations
of chemical substances in biota provide evidence of exposure. EPA plans to review reasonably available
environmental monitoring data for 1,3-butadiene. EPA's Ambient Monitoring Technology Information
Center Air Toxics database has identified 1,3-butadiene in air. In addition, EPA's Unregulated
Contaminant Monitoring Rule has identified 1,3-butadiene in drinking water. USGS's Monitoring Data
- National Water Quality Monitoring Council has identified 1,3-butadiene in ground water.
Releases of 1,3-butadiene from certain conditions of use, such as manufacturing, processing,
distribution, use, and disposal activities, may result in general population exposures (OEHHA 2013).
1,3-Butadiene is likely present at low ambient air concentrations in U.S. cities and large suburban areas
(OEHHA 2013). Elevated ambient air concentrations of 1,3-butadiene have been measured in the
vicinity of heavily trafficked areas, refineries, chemical manufacturing plants, and plastic and rubber
27

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factories (OEHHA 2013). Reasonably available assessments note the general population is exposed to
low levels of 1,3-butadiene in the air due to its presence in gasoline, motor-vehicle exhausts as a product
of incomplete combustion of gasoline and diesel oil, and thermal breakdown of plastics (NTP 2016). In
addition, the general population is also exposed to low levels of 1,3-butadiene in U.S. drinking water
supplies (NTP 2016, AT SDR 2012).
2.4	Hazards (Effects)
2.4.1	Environmental Hazards
As described in the Promised Designation of 1,3-Butadiene fCASRN 106-99-0) as a Hieh-Priority
Substance for Risk Evaluation (U.S. EPA 2019), EPA considered reasonably available information from
peer-reviewed assessments and databases to identify potential environmental hazards for 1,3-butadiene.
EPA did not identify environmental hazard information for 1,3-butadiene during the prioritization
process. However, EPA is in the process of identifying additional reasonably available information
through systematic review methods and public comments that may inform potential environmental
hazards associated with 1,3-butadiene exposure.
2.4.2	Human Health Hazards
As described in the Proposed Designation of 1,3-Butadiene fCASRN 106-99-0) as a Hieh-Priority
Substance for Risk Evaluation (U.S. EPA 2019), EPA considered reasonably available information from
peer-reviewed assessments and databases to identify potential human health hazards for 1,3-butadiene.
EPA plans to evaluate all of the potential human health hazards for 1,3-butadiene identified during
prioritization. The health effect categories screened for during prioritization included acute toxicity,
irritation/corrosion, dermal sensitization, respiratory sensitization, genetic toxicity, repeated dose
toxicity, reproductive toxicity, developmental toxicity, immunotoxicity, neurotoxicity, carcinogenicity,
epidemiological or biomonitoring studies and ADME[1]. EPA is in the process of identifying additional
reasonably available information through systematic review methods and public input, which may
update the list of potential human health hazards under the scope of the risk evaluation. If necessary,
EPA plans to update the list of potential hazards in the final scope document of the 1,3-butadiene risk
evaluation.
2.5	Potentially Exposed or Susceptible Subpopulations
TSCA § 6(b)(4) requires EPA to determine whether a chemical substance presents an unreasonable risk
to "a potentially exposed or susceptible subpopulation identified as relevant to the risk evaluation."
TSCA §3(12) states that "the term 'potentially exposed or susceptible subpopulation' means a group of
individuals within the general population identified by the Administrator who, due to either greater
susceptibility or greater exposure, may be at greater risk than the general population for adverse health
effects from exposure to a chemical substance or mixture, such as infants, children, pregnant women,
workers, or the elderly." General population is "the total of individuals inhabiting an area or making up a
whole group" and refers here to the U.S. general population (	011).
During the Prioritization process, EPA identified the following PESS based on CDR information and
studies reporting developmental and reproductive effects: children, women of reproductive age
(including, but not limited to, pregnant women), workers and consumers (U.S. EPA 2019). EPA plans to
evaluate these potentially exposed or susceptible subpopulations in the risk evaluation.
[1] ADME= absorption, distribution, metabolism, and excretion
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In developing exposure scenarios, EPA plans to analyze reasonably available information to ascertain
whether some human receptor groups may be exposed via exposure pathways that may be distinct to a
particular subpopulation or life stage (e.g., children's crawling, mouthing or hand-to-mouth behaviors)
and whether some human receptor groups may have higher exposure via identified pathways of
exposure due to unique characteristics (e.g., activities that would lead to elevated fish ingestion or
otherwise lead to increased duration or level of exposure) when compared with the general population
(U.S. EPA. 2006a). For example, elevated ambient air concentrations of 1,3-butadiene have been
measured in the vicinity of heavily trafficked areas, refineries, chemical manufacturing plants, and
plastic and rubber factories (OEHHA 2013). Populations living in areas near oil refineries, chemical
manufacturing plants, and plastic and rubber factories where 1,3-butadiene is manufactured or used
would be expected to have higher exposures (ATSDR 2012). Likewise, EPA plans to evaluate available
human health hazard information to ascertain whether some human receptor groups may have greater
susceptibility than the general population to the chemical's hazard(s).
2.6 Conceptual Models
In this section, EPA presents the conceptual models describing the identified exposures (pathways and
routes), receptors and hazards associated with the conditions of use of 1,3-butadiene. Pathways and
routes of exposure associated with workers and ONU's are described in Section 2.6.1, and pathways and
routes of exposure associated with consumers are described in Section 2.6.2. Pathways and routes of
exposure associated with environmental releases and wastes, including those pathways that may be
addressed pursuant to other Federal laws are discussed and depicted the conceptual model shown in
Section 2.6.3. Pathways and routes of exposure associated with environmental releases and wastes,
excluding those pathways that may be addressed pursuant to other Federal laws are presented in the
conceptual model shown in Section 2.6.4.
2.6.1 Conceptual Model for Industrial and Commercial Activities and Uses
Figure 2-8 illustrates the conceptual model for the pathways of exposure from industrial and commercial
activities and uses of 1,3-butadiene that EPA plans to include in the risk evaluation. There is potential
for exposures to workers and/or ONU's via inhalation routes and exposures to workers via dermal
routes. Due to 1,3-butadiene high vapor pressure, it is expected that inhalation exposure to vapors is the
most likely exposure pathway. In addition, workers at waste management facilities may be exposed via
inhalation or dermal routes during waste handling, treatment, and disposal. EPA plans to evaluate
activities resulting in exposures associated with distribution in commerce (e.g., loading, unloading)
throughout the various lifecycle stages and conditions of use (e.g., manufacturing, processing, industrial
use, commercial use, and disposal) rather than a single distribution scenario.
One of the commercial uses of 1,3-butadiene is in fuel and fuel products, EPA plans to assess
occupational exposures related to the processing and handling of fuel. Preliminary literature suggests
1,3-butadiene presence in fuel is low (ECB, 2002). However, 1,3-butadiene is also generated as a
byproduct from the incomplete combustion of fuel, EPA does not plan to assess occupational exposures
resulting 1,3-butadiene formed as a byproduct (e.g., exhaust emissions). EPA believes it is more
appropriate to evaluate the potential risks arising from the byproduct within the scope of the risk
evaluation for the chemical substances from which the byproduct is produced, rather than the 1,3-
butadiene risk evaluation. For each condition of use identified in Table 2-2, a determination was made as
to whether or not EPA plans to assess each unique combination of exposure pathway, route, and receptor
in the risk evaluation. The supporting rationale is presented in Appendix F.
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INDUSTRIAL AND
COMMERCIAL AC TIVITIES -	EXPOSURE PATHWAY EXPOSURE ROl TE	RECEPTORS	HAZARDS
USES
Liquid Contact
Hazard* potentially
associated with
acute and/of
chrome exposures
Processing
-As a reactant
-Incorporation mrc
ferrouliticn. mixture,
or	product
-Iccorporition mc
Article
Vapor Mi-
"HBisIves'ainT
Sealants
'XutomoHveTariT
Products
Processing aids,
specific to petroleum
production
Tueist3]Eiat3
Products
Lubricants and
lubricant additives
Paints and Coatings
Plastic and Rubber
Products
Waste Handling.
Treatment, and Disposal
/See Etwi
Figure 2-8.1,3-Butadiene Conceptual Model for Industrial and Commercial Activities and Uses: Worker and ONU Exposures and
Hazards
The conceptual model presents the exposure pathways, exposure routes, and hazards to human receptors from industrial and commercial activities and uses
of 1,3-butadiene.
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2.6.2 Conceptual Model for Consumer Activities and Uses
The conceptual model in Figure 2-9 presents the exposure pathways, exposure routes and hazards to
human receptors from consumer activities and uses of 1,3-butadiene that EPA plans to include in the
risk evaluation. EPA expects inhalation to be the primary route of exposure and plans to evaluate
inhalation exposures to 1,3-butadiene vapor for consumers and bystanders during use and disposal of
automotive care products, and plastics and rubber products. There is potential for consumer dermal
exposures to 1,3-butadiene via direct contact during use of automotive care products, such as lubricants.
Bystanders are not expected to have direct dermal contact to 1,3-butadiene. Therefore, EPA plans to
evaluate dermal exposure to 1,3-butadiene for consumers but not for bystanders. In addition, oral
exposures to 1,3-butadiene are expected to be negligible and, as a result, EPA does not expect to
evaluate this route of exposure for consumers nor bystanders. The supporting rationale for consumer
pathways considered for 1,3 butadiene are included in 94.
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CONSUMER ACTIVITIES &
USES
EXPOSURE
PATHWAY
EXPOSURE
ROUTE
RECEPTORS
HAZARDS
Liquii"¥o"nIa"cf""
Consumers
£ z r '.i l
Automotive Care
Products
Plastic an
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2.6.3 Conceptual Models for Environmental Releases and Wastes: Potential
Exposures and Hazards (Regulatory Overlay)
In complying with TSCA, EPA plans to efficiently use Agency resources, avoid duplicating efforts
taken pursuant to other Agency programs, maximize scientific and analytical efforts, and meet the
statutory deadline for completing risk evaluations. OPPT is working closely with the offices within EPA
that administer and implement the Clean Air Act (CAA), the Safe Drinking Water Act (SDWA), the
Clean Water Act (CWA) and the Resource Conservation and Recovery Act (RCRA), to identify how
those statutes and any associated regulatory programs address the presence of 1,3-butadiene in exposure
pathways falling under the jurisdiction of these EPA statutes.
The conceptual model in Figure 2-10 presents the potential exposure pathways, exposure routes and
hazards to human and environmental receptors from releases and waste streams associated with
industrial and commercial uses of 1,3-butadiene. This figure includes overlays, labeled and shaded to
depict the regulatory programs (e.g., CAA, SDWA, CWA, RCRA) and associated pathways that EPA
considered in developing this conceptual model for the draft scope document. The pathways are further
described in Section 2.6.3.1 through Section 2.6.3.2.
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RELEASES AND WASTES FROM
INDUSTRIAL / COMMERCIAL /
CONSUMER USES
EXPOSURE PATHWAYS
EXPOSURE
ROUTES
RECEPTORS
HAZARDS
Wastewater or
Liquid Wastes
Industrial Pre
Treatment or
Industrial WWT
SDWA
Water. Sediment
Indirect discharge
t
Fish Ingestion	Aquatic
Species
POTW
Underground
Injection
Drinking
Water1
Biosolids
Hazardous and
Municipal Waste
Landfill
Disposal
General
Dermal
Population
Ground
Solid Wastes
Liquid Wastes
Water
Hazardous and
Municipal Waste
Incinerators
CAA-HAP
Fugitive Emissions
Inhalation
Off-site Waste
Transfer
Terrestrial
Recycling, Other
Treatment
Emissions to Air
Hazards Potentially
Associated with
Acute and/or Chronic
Exposures
1.	Drinking Water to inhalation would be if there was showering.
2.	For regulation of hazardous and municipal waste incinerators and hazardous and municipal waste landfills CAA
and RCRA have shared regulatory oversight.
Figure 2-10.1,3-Butadiene Conceptual Model for Environmental Releases and Wastes: Environmental and General Population
Exposures and Hazards (Regulatory Overlay)
The conceptual model presents the exposure pathways, exposure routes and hazards to human receptors from releases and wastes from industrial and commercial uses of
1,3-butadiene showing the environmental statutes covering those pathways. Notes:
a)	Industrial wastewater or liquid wastes may be treated on-site and then released to surface water (direct discharge), or pre-treated and released to a Publicly Owned
Treatment Works (POTW) (indirect discharge). For consumer uses, such wastes may be released directly to POTW. Drinking water will undergo further treatment in
drinking water treatment plant. Ground water may also be a source of drinking water.
b)	Receptors include PESS (see Section 2.5).
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2.6.3.1	Ambient Air Pathway
The Clean Air Act (CAA) contains a list of hazardous air pollutants (HAP) and provides EPA with the
authority to add to that list pollutants that present, or may present, a threat of adverse human health
effects or adverse environmental effects. For stationary source categories emitting HAPs, the CAA
requires issuance of technology-based standards and, if necessary, additions or revisions to address
developments in practices, processes, and control technologies, and to ensure the standards adequately
protect public health and the environment. The CAA thereby provides EPA with comprehensive
authority to regulate emissions to ambient air of any hazardous air pollutant. 1,3-Butadiene is a HAP.
EPA has issued a number of technology-based standards for source categories that emit 1,3-butadiene to
ambient air and, as appropriate, has reviewed or is in the process of reviewing remaining risks.
Emission pathways to ambient air from commercial and industrial stationary sources and associated
inhalation exposure of the general population or terrestrial species in this TSCA evaluation from
stationary source releases of 1,3-butadiene to ambient air are covered under the jurisdiction of the CAA.
EPA's Office of Air and Radiation and Office of Pollution Prevention and Toxics will continue to work
together to provide an understanding and analysis of the CAA regulatory analytical processes and to
exchange information related to toxicity and occurrence data on chemicals undergoing risk evaluation
under TSCA.
2.6.3.2	Drinking Water Pathway
EPA has regular analytical processes to identify and evaluate drinking water contaminants of potential
regulatory concern for public water systems under the Safe Drinking Water Act (SDWA). Under SDWA
EPA must also review and revise "as appropriate" existing drinking water regulations every 6 years.
The Contaminant Candidate List (CCL) is a list of unregulated contaminants that are known or
anticipated to occur in public water systems and that may require regulation. EPA must publish a CCL
every 5 years and make Regulatory Determinations to regulate (or not) at least five CCL contaminants
every 5 years. To regulate a contaminant, EPA must conclude the contaminant may have adverse health
effects, occurs or is substantially likely to occur in public water systems at a level of concern and that
regulation, in the sole judgement of the Administrator, presents a meaningful opportunity for health risk
reduction.
Once contaminants have been placed on the CCL, EPA identifies if there are any additional data needs,
including gaps in occurrence data for evaluation under the Regulatory Determination; if sufficient
occurrence data is lacking, the contaminant may be considered for monitoring under the Unregulated
Contaminant Monitoring Rule.
1,3-Butadiene is currently listed on EPA's Fourth Contaminant Candidate List (CCL 4) and was subject
to occurrence monitoring in public water systems under the third Unregulated Contaminants Monitoring
Rule (UMCR 3). Under UMCR 3, water systems were monitored for 1,3-butadiene during 2013-2015.
Of the 4,916 water systems monitored, 2 systems had detections of 1,3-butadiene in at least one sample.
In accordance with EPA Office of Water's process, 1,3-butadiene is currently being evaluated under the
fourth Regulatory Determination process under SDWA.
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2.6.4 Conceptual Model for Environmental Releases and Wastes: Potential Exposures
and Hazards
As described in Section 2.6.3, some pathways in the conceptual models are covered under the
jurisdiction of other environmental statutes administered by EPA. The conceptual model depicted in
Figure 2-11. 1,3-Butadiene Conceptual Model for Environmental Releases and Wastes: Environmental
and General Population Exposures and Hazards presents the exposure pathways, exposure routes and
hazards to human and environmental receptors from releases and wastes from industrial and commercial
uses of 1,3-butadiene that EPA plans to consider in the risk evaluation. The exposure pathways,
exposure routes and hazards presented in this conceptual model are subject to change in the final scope,
in light of comments received on this draft scope and other reasonably available information. EPA
continues to consider whether and how other EPA-administered statutes and any associated regulatory
programs address the presence of 1,3-butadiene in exposure pathways falling under the jurisdiction of
these EPA statutes.
Figure 2-11 depicts the environmental pathways that remain in scope after applying EPA's regulatory
overlay. EPA plans to evaluate exposures to general population, aquatic, terrestrial species that may
occur from industrial and/or commercial and consumer releases to water/sediment; biosolids and soil.
Some aquatic species may be exposed to 1,3 butadiene in water bodies in which 1,3-butadiene is found.
In addition, some terrestrial species may be exposed to 1,3-butadiene via surface water, soil and
biosolids found in their natural habitats. The general population may be exposed to 1,3-butadiene via
fish consumption and may be dermally exposed to 1,3 butadiene through ambient water. The supporting
basis for general population and environmental pathways considered for 1,3 butadiene are included in
96.
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RELEASES AND WASTES FROM
INDUSTRIAL / COMMERCIAL /
CONSUMER USES
EXPOSURE PATHWAYS
EXPOSURE
ROUTES
RECEPTORS
Wastewater or
Liquid Wastes
Solid Wastes
Liquid Wastes
CAA
RCRA
SDWA
CWA
Industrial Pre-
Treatment or
Industrial WWT


i
Indirect discharge
*
POTW



Underground
Injection


Water. Sediment
3
Hazardous and
Municipal Waste
Landfill2
Hazardous and
Municipal Waste
Incinerators2
Off-site Waste
Transfer
Land
Disposal
Fish Ingestion-
I
Aquatic
Species
Ground
Water J
General
Population
Hazards Potentially
Associated with
Acute and/or Chronic
Exposures
Recycling, Other
Treatment
Terrestrial
Species
Figure 2-11.1,3-Butadiene Conceptual Model for Environmental Releases and Wastes: Environmental and General Population
Exposures and Hazards
The conceptual model presents the exposure pathways, exposure routes and hazards to human receptors from releases and wastes from industrial and commercial uses of
1,3-butadiene that EPA plans to consider in the risk evaluation. Notes:
a)	Industrial wastewater or liquid wastes may be treated on-site and then released to surface water (direct discharge), or pre-treated and released to POTW (indirect
discharge). For consumer uses, such wastes may be released directly to POTW. Drinking water will undergo further treatment in drinking water treatment plant.
Ground water may also be a source of drinking water.
b)	Receptors include PESS (see Section 2.5).
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2.7 Analysis Plan
The analysis plan is based on EPA's knowledge of 1,3-butadiene to date which includes a partial, but
not complete, review of reasonably available information as described in Section 2.1 EPA encourages
submission of additional data, such as full study reports or workplace monitoring from industry sources,
that may be relevant for EPA's evaluation of conditions of use, exposures, hazards, and PESS during
risk evaluation. Further, EPA may consider any relevant CBI in a manner that protects the
confidentiality of the information from public disclosure. EPA plans to continue to consider new
information submitted by the public. Should additional data or approaches become reasonably available,
EPA may update its analysis plan in the final scope document.
2.7.1 Physical and Chemical Properties and Environmental Fate
EPA plans to analyze the physical and chemical (p-chem) properties and environmental fate and
transport of 1,3-butadiene as follows:
1)	Review reasonably available measured or estimated p-chem and environmental fate
endpoint data collected using systematic review procedures and, where available,
environmental assessments conducted by other regulatory agencies.
EPA plans to review data and information collected through the systematic review methods and
public comments about the p-chem properties (Appendix B) and fate endpoints (Appendix C)
previously summarized in the Proposed Designation of 1.3-Butadiene fCASRN 106-99-0) as a
High-Priority Substance for Risk Evaluation (U.S. EPA 2019a). All sources cited in EPA's
analysis will be evaluated according to the procedures described in the systematic review
documentation that EPA plans to publish prior to finalizing the scope document. Where the
systematic review process fails to identify experimentally measured chemical property values of
sufficiently high quality, these values will be estimated using chemical parameter estimation
models as appropriate. Model-estimated fate properties will be reviewed for applicability and
quality.
2)	Using measured data and/or modeling, determine the influence of p-chem properties and
environmental fate endpoints (e.g., persistence, bioaccumulation, partitioning, transport)
on exposure pathways and routes of exposure to human and environmental receptors.
EPA plans to use measured data and, where necessary, model predictions of p-chem properties
and environmental fate endpoints to characterize the persistence and movement of 1,3-butadiene
within and across environmental media. The p-chem and fate properties to be assessed are listed
in Appendix B and Appendix C, respectively. Given preliminary findings for physical chemical
property and fate data, EPA believes it is unlikely that 1,3-butadiene will sorb to biosolids due to
its volatility (vapor pressure and Henry's Law Constant), water solubility and unlikely sorption
to sludge (Log Koc). However, no assessment pathway will be removed until the full systematic
review of available literature is complete. EPA plans to use p-chem and fate endpoints in
exposure calculations.
3)	Conduct a weight-of-evidence evaluation of p-chem and environmental fate data, including
qualitative and quantitative sources of information.
During risk evaluation, EPA plans to evaluate and integrate the environmental fate evidence
identified in the literature inventory using the methods described in the systematic review
documentation that EPA plans to publish prior to finalizing the scope document.
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2.7.2 Exposure
EPA plans to analyze exposure levels for indoor air, surface water, sediment, soil, aquatic biota, and
terrestrial biota associated with exposure to 1,3-butadiene. EPA has not yet determined the exposure
levels in these media or how they may be used in the risk evaluation. Exposure scenarios are sources
(uses), exposure pathways, and exposed receptors. EPA plans to analyze scenario-specific exposures.
Based on their physical-chemical properties, expected sources, and transport and transformation within
the outdoor and indoor environment, chemical substances are more likely to be present in some media
and less likely to be present in others. Exposure level(s) can be characterized through a combination of
reasonably available monitoring data and modeling approaches.
2.7.2.1 Environmental Releases
EPA plans to analyze releases to environmental media as follows:
1)	Review reasonably available published literature and other reasonably available
information on processes and activities associated with the conditions of use to analyze the
types of releases and wastes generated.
EPA has reviewed some key data sources containing information on processes and activities
resulting in releases, and the information found is described in Appendix E. EPA plans to
continue to review data sources during risk evaluation using the evaluation strategy in the
systematic review documentation that EPA plans to publish prior to finalizing the scope
document. Potential sources of environmental release data are summarized in Table 2-5 below:
Table 2-5. Potential Categories and Sources of Environmental Release Data	
U.S. EPA TRI Data	
U.S. EPA Generic Scenarios	
OECD Emission Scenario Documents	
EU Risk Assessment Reports	
Discharge Monitoring Report (DMR) surface water discharge data for 1,3-butadiene
from NPDES-permitted facilities	
2)	Review reasonably available chemical-specific release data, including measured or
estimated release data (e.g., data from risk assessments by other environmental agencies).
EPA has reviewed key release data sources including the Toxics Release Inventory (TRI), and
the data from this source is summarized in Section 2.3.3. EPA plans to continue to review
relevant data sources during risk evaluation. EPA plans to match identified data to applicable
conditions of use and identify data gaps where no data are found for particular conditions of use.
EPA plans to attempt to address data gaps identified as described in steps 3 and 4 below by
considering potential surrogate data and models.
Additionally, for conditions of use where no measured data on releases are available, EPA may
use a variety of methods including release estimation approaches and assumptions in the
Chemical Screening Tool for Occupational Exposures and Releases ChemSTEER (U.S. EPA,
2013).
3)	Review reasonably available measured or estimated release data for surrogate chemicals
that have similar uses and physical properties.
Data for monomers used in the same types of applications may be considered as surrogate data
for 1,3-butadiene. As with 1,3-butadiene, styrene is used as a monomer in rubber and plastic
39

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polymer manufacturing. EPA plans to consider the use of data for monomers such as styrene as
surrogates to fill data gaps where uses of 1,3-butadiene and other monomers align. If surrogate
data are used, EPA normally converts air concentrations using the ratio of the vapor pressures of
the two chemicals. EPA plans to review literature sources identified and if surrogate data are
found, EPA plans to match these data to applicable conditions of use for potentially filling data
gaps.
4) Review reasonably available data that may be used in developing, adapting or applying
exposure models to the particular risk evaluation.
This item will be performed after completion of #2 and #3 above. EPA plans to evaluate relevant
data to determine whether the data can be used to develop, adapt, or apply models for specific
conditions of use (and corresponding release scenarios). EPA has identified information from
various EPA statutes (including, for example, regulatory limits, reporting thresholds or disposal
requirements) that may be relevant to release estimation. EPA plans to further consider relevant
regulatory requirements in estimating releases during risk evaluation.
5) Review and determine applicability of OECD Emission Scenario Documents (ESDs) and
EPA Generic Scenarios to estimation of environmental releases.
EPA has identified potentially relevant OECD Emission Scenario Documents (ESDs) and EPA
Generic Scenarios (GS) that correspond to some conditions of use; for example, the 2009 ESP
on Plastics Additives, the 2004 ESP on Additives in the Rubber Industry, the 2.011 ESP on the
Chemical Industry, the 1991 Petroleum Refining Processing, Crude Separation Process, and
Catalytic Cracking GS, and the 1994 Synthetic Fiber Manufacture GS may be useful to assess
potential releases. EPA plans to critically review these generic scenarios and ESDs to determine
their applicability to the conditions of use.
EPA Generic Scenarios are available at the following: https://www.epa.gov/tsca-screening-
OECD Emission Scenario Documents are available at the following:
http://www.oecd.org/chemicalsafetv/risk-assessment/emissionscenariodocuments.htm
EPA was not able to identify ESDs or GSs corresponding to several conditions of use, including
use of 1,3-butadiene in automotive care products and recycling of 1,3-butadiene. EPA plans to
perform additional targeted research to understand those conditions of use which may inform
identification of release scenarios. EPA may also need to perform targeted research for
applicable models and associated parameters that EPA may use to estimate releases for certain
conditions of use. If ESDs and GSs are not available, other methods may be considered.
Additionally, for conditions of use where no measured data on releases are available, EPA may
use a variety of methods including the application of default assumptions such as standard loss
fractions associated with drum cleaning (3%) or single process vessel cleanout (1%).
6) Map or group each condition of use to a release assessment scenario(s).
EPA has identified release scenarios and mapped (i.e., grouped) them to relevant conditions of
use as shown in Appendix F. EPA was not able to identify release scenarios corresponding to
some conditions of use (e.g., automotive care products, and recycling). EPA plans to perform
targeted research to understand those uses, which may inform identification of release scenarios.
EPA may further refine the mapping of release scenarios based on factors (e.g., process
equipment and handling, magnitude of production volume used, and release sources and usage
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rates of 1,3-butadiene and polymer products and formulations containing 1,3-butadiene, or
professional judgment) corresponding to conditions of use as additional information is identified
during risk evaluation.
7) Evaluate the weight of the scientific evidence of environmental release data.
During risk evaluation, EPA plans to evaluate and integrate the exposure evidence identified in
the literature inventory using the methods described in the systematic review documentation that
EPA plans to publish prior to finalizing the scope document. The data integration strategy will be
designed to be fit-for-purpose in which EPA plans to use systematic review methods to assemble
the relevant data, evaluate the data for quality and relevance, including strengths and limitations,
followed by synthesis and integration of the evidence.
2.7.2.2 Environmental Exposures
EPA plans to analyze the following in developing its environmental exposure assessment of 1,3-
butadiene:
1)	Review reasonably available environmental and biological monitoring data for all media
relevant to environmental exposure.
For 1,3-butadiene, environmental media which EPA plans to evaluate are biosolids, sediment,
soil, and water. EPA believes it is unlikely that 1,3-Butadiene will sorb to biosolids due to its
volatility (vapor pressure and Henry's Law Constant), water solubility and unlikely sorption to
sludge (Log Koc). This pathway will not be ruled out until further evaluation.
2)	Review reasonably available information on releases to determine how modeled estimates
of concentrations near industrial point sources compare with reasonably available
monitoring data.
Reasonably available environmental exposure models that meet the TSCA section 26(h) and (i)
Science Standards and that estimate water, sediment, soil and biosolids concentrations will be
analyzed and considered alongside reasonably available water, sediment, and soil monitoring
data to characterize environmental exposures. Modeling approaches to estimate surface water
concentrations, sediment concentrations, and soil concentrations generally, consider the
following inputs: direct release into water, sediment, or soil, indirect release into water,
sediment, or soil (i.e., air deposition), fate and transport (partitioning within media) and
characteristics of the environment (e.g., river flow, volume of lake, meteorological data).
3)	Determine applicability of existing additional contextualizing information for any
monitored data or modeled estimates during risk evaluation.
There have been changes to use patterns of 1,3-butadiene over the last few years. Monitoring
data or modeled estimates will be reviewed to determine how representative they are of
applicable use patterns.
Any studies which relate levels of 1,3-butadiene in the environment or biota with specific
sources or groups of sources will be evaluated.
4)	Group each condition(s) of use to environmental assessment scenario(s).
EPA plans to refine and finalize exposure scenarios for environmental receptors by considering
sources (use descriptors), exposure pathways including routes, and populations exposed. For 1,3-
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butadiene, the following are noteworthy considerations in constructing exposure scenarios for
environmental receptors:
Estimates of surface water concentrations, sediment concentrations, soil
concentrations and biosolids concentrations near industrial point sources based on
available monitoring data.
Generally, consider the following modeling inputs: release into the media of interest,
fate and transport and characteristics of the environment.
Reasonably available biomonitoring data. Monitoring data could be used to compare
with species or taxa-specific toxicological benchmarks.
Applicability of existing contextualizing information for any monitored data or
modeled estimates during risk evaluation. Review and characterize the spatial and
temporal variability, to the extent that data are available, and characterize exposed
aquatic and terrestrial populations.
Weight of the scientific evidence of environmental occurrence data and modeled
estimates.
5) Evaluate the weight of the scientific evidence of environmental occurrence data and
modeled estimates.
During risk evaluation, EPA plans to evaluate and integrate the exposure evidence identified in
the literature inventory using the methods described in the systematic review documentation that
EPA plans to publish prior to finalizing the scope document.
2.7.2.3 Occupational Exposures
EPA plans to analyze both worker and ONU exposures as follows:
1) Review reasonably available exposure monitoring data for specific condition(s) of use.
EPA plans to review exposure data including workplace monitoring data collected by
government agencies such as the Occupational Safety and Health Administration (OSHA) and
the National Institute for Occupational Safety and Health (NIOSH), and monitoring data found in
published literature. These workplace monitoring data include personal exposure monitoring data
(direct exposures) and area monitoring data (indirect exposures).
EPA has preliminarily reviewed reasonably available monitoring data collected by OSHA and
NIOSH and will match these data to applicable conditions of use. EPA has also identified
additional data sources that may contain relevant monitoring data for the various conditions of
use. EPA plans to review these sources (identified in Table 2-6) and extract relevant data for
consideration and analysis during risk evaluation.
OSHA has established a permissible exposure limit (PEL) of 1 ppm 8-hour time-weighted
average (TWA). The OSHA Short-Term Exposure Limit (STEL) for 1,3-Butadiene is 5 ppm
(OSHA 2019). EPA plans to consider the influence of these regulatory limits on occupational
exposures in the occupational exposure assessment. The following are some data sources
identified thus far:
Table 2-6. Potential Sources of Occupational Exposure Data	
2012 ATSDR Toxicological Profile for 1,3-Butadiene	
U.S. OSHA Chemical Exposure Health Data (CEHD) program data	
U.S. NIOSH Health Hazard Evaluation (HHE) Program reports	
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2)	Review reasonably available exposure data for surrogate chemicals that have uses,
volatility and chemical and physical properties similar to 1,3-butadiene.
EPA plans to review literature sources identified and if surrogate data are found, these data will
be matched to applicable conditions of use for potentially filling data gaps. For several
conditions of use (e.g., monomer in polymer manufacturing), EPA believes monomers utilized in
similar ways to 1,3-butadiene may serve as surrogates for 1,3-butadiene.
3)	For conditions of use where data are limited or not available, review existing exposure
models that may be applicable in estimating exposure levels.
EPA has identified potentially relevant OECD ESDs and EPA GS corresponding to some
conditions of use. For example, the ESD on Additives in Rubber Industry, the ESD on Plastics
Additives, the ESD on Chemical Industry, the Petroleum Refining Processing, Crude Separation
Process, and Catalytic Cracking GS, and the Synthetic Fiber Manufacture GS are some of the
ESDs and GS's that EPA may use to estimate occupational exposures. EPA plans to critically
review these generic scenarios and ESDs to determine their applicability to the conditions of use.
EPA was not able to identify ESDs or GS's corresponding to some conditions of use, including
use of 1,3-butadiene in automotive care products and recycling of 1,3-butadiene. EPA plans to
perform additional targeted research to understand those conditions of use, which may inform
identification of exposure scenarios. EPA may also need to perform targeted research to identify
applicable models that EPA may use to estimate exposures for certain conditions of use.
4)	Review reasonably available data that may be used in developing, adapting or applying
exposure models to a particular risk evaluation scenario.
This step will be performed after Steps #2 and #3 are completed. Based on information
developed from Steps #2 and #3, EPA plans to evaluate relevant data to determine whether the
data can be used to develop, adapt, or apply models for specific conditions of use (and
corresponding exposure scenarios). EPA may utilize existing, peer-reviewed exposure models
developed by EPA or other government agencies, or reasonably available in the scientific
literature, or EPA may elect to develop additional models to assess specific condition(s) of use.
Inhalation exposure models may be simple box models or two-zone (near-field/far-field) models.
In two-zone models, the near-field exposure represents potential inhalation exposures to workers,
and the far-field exposure represents potential inhalation exposures to ONU's.
5)	Consider and incorporate applicable EC and/or PPE into exposure scenarios.
EPA plans to review potentially relevant data sources on EC and PPE to determine their
applicability and incorporation into exposure scenarios during risk evaluation. EPA plans to
assess worker exposure pre- and post-implementation of EC, using reasonably available
information on available control technologies and control effectiveness. For example, EPA may
assess worker exposure in industrial use scenarios before and after implementation of local
exhaust ventilation.
6)	Map or group each condition of use to occupational exposure assessment scenario(s).
EPA has identified occupational exposure scenarios and mapped them to relevant conditions of
use (see 2.8Appendix F). As presented in the fourth column in Table Apx F-l. Worker and
Occupational Non-User Exposure Conceptual Model Supporting Table, EPA has grouped the
scenarios into representative release/exposure scenarios. EPA was not able to identify
occupational scenarios corresponding to some conditions of use. EPA plans to perform targeted
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research to understand those uses which may inform identification of occupational exposure
scenarios. EPA may further refine the mapping of occupational exposure scenarios based on
factors (e.g., process equipment and handling, magnitude of production volume used, and
exposure/release sources) corresponding to conditions of use as additional information is
identified during risk evaluation.
7) Evaluate the weight of the scientific evidence of occupational exposure data, which may
include qualitative and quantitative sources of information.
During risk evaluation, EPA plans to evaluate and integrate the exposure evidence identified in
the literature inventory using the methods described in the systematic review document that EPA
plans to publish prior to finalizing the scope document. EPA plans to rely on the weight of the
scientific evidence when evaluating and integrating occupational data. The data integration
strategy will be designed to be fit-for-purpose in which EPA plans to use systematic review
methods to assemble the relevant data, evaluate the data for quality and relevance, including
strengths and limitations, followed by synthesis and integration of the evidence.
2.7.2.4 Consumer Exposures
EPA plans to analyze both consumers using a consumer product and bystanders associated with the
consumer using the product as follows:
1)	Group each condition of use to consumer exposure assessment scenario(s).
Refine and finalize exposure scenarios for consumers by considering combinations of sources
(ongoing consumer uses), exposure pathways including routes, and exposed populations.
For 1,3-butadiene, the following are noteworthy considerations in constructing consumer
exposure scenarios:
Conditions of use and type of consumer product
Duration, frequency and magnitude of exposure
Weight fraction of chemical in products
Amount of chemical used
2)	Evaluate the relative potential of indoor exposure pathways based on reasonably available
data.
Indoor exposure pathways expected to be relatively higher include inhalation of vapors from
indoor air during 1,3-butadiene use and disposal. Indoor exposure pathways expected to be
relatively lower include dermal contact to liquid dermal contact to liquid. The data sources
associated with these respective pathways have not yet been comprehensively evaluated, so
quantitative comparisons across exposure pathways or in relation to toxicity thresholds are not
yet available.
3)	Review existing indoor exposure models that may be applicable in estimating indoor air
concentrations.
Indoor exposure models that estimate emissions from consumer products are available. These
models generally consider p-chem properties (e.g., vapor pressure, molecular weight), product
specific properties (e.g., weight fraction of the chemical in the product), use patterns (e.g.,
duration and frequency of use), user environment (e.g., room of use, ventilation rates), and
receptor characteristics (e.g., exposure factors, activity patterns). The OPPT's Consumer
Exposure Model (CEM) and other similar models can be used to estimate indoor air exposures
from consumer products.
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4)	Review reasonably available empirical data that may be used in developing, adapting or
applying exposure models to a particular risk evaluation scenario. For example, existing
models developed for a chemical assessment may be applicable to another chemical
assessment if model parameter data are available.
To the extent other organizations have already modeled a 1,3-butadiene consumer exposure
scenario that is relevant to the OPPT's assessment, EPA plans to evaluate those modeled
estimates. In addition, if other chemicals similar to 1,3-butadiene have been modeled for similar
uses, those modeled estimates will also be evaluated. The underlying parameters and
assumptions of the models will also be evaluated.
5)	Review reasonably available consumer product-specific sources to determine how those
exposure estimates compare with each other and with indoor monitoring data reporting
1,3-butadiene in specific media (e.g., indoor air).
The availability of 1,3-butadiene concentration for various ongoing uses will be evaluated. This
data provides the source term for any subsequent indoor modeling. Source attribution between
overall indoor air levels and various indoor sources will be analyzed.
6)	Review reasonably available population- or subpopulation-specific exposure factors and
activity patterns to determine if PESS need to be further refined.
During risk evaluation, EPA plans to evaluate and integrate the exposure evidence identified in
the literature inventory using the methods described in the systematic review documentation that
EPA plans to publish prior to finalizing the scope document.
7)	Evaluate the weight of the scientific evidence of consumer exposure estimates based on
different approaches.
EPA plans to rely on the weight of the scientific evidence when evaluating and integrating data
related to consumer exposure. The weight of the scientific evidence may include qualitative and
quantitative sources of information. The data integration strategy will be designed to be fit-for-
purpose in which EPA plans to use systematic review methods to assemble the relevant data,
evaluate the data for quality and relevance, including strengths and limitations, followed by
synthesis and integration of the evidence.
2.7.2.5 General Population
EPA plans to analyze general population exposures as follows:
While the primary route of exposure to 1,3-butadiene is inhalation, the general population may be
exposed via the oral route (i.e., fish ingestion). Dermal exposures to the general population are expected
to be negligible. However, depending on information identified and evaluated through EPA's systematic
review process, exposure through dermal routes may be considered in the risk evaluation of 1,3-
butadiene (NTP 2016, AT SDR 2012).
1) Refine and finalize exposure scenarios for general population by considering combinations
of sources and uses, exposure pathways including routes, and exposed populations.
For 1,3-butadiene, the following are noteworthy considerations in constructing exposure
scenarios for the general population: routes of exposure, releases to air, water or land resulting
from industrial, commercial, and other conditions of use, in addition to:
Reviewing reasonably available environmental and biological monitoring data for media
to which general population exposures are expected.
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For exposure pathways where data are not reasonably available, reviewing existing
exposure models that may be applicable in estimating exposure levels.
Considering and incorporating applicable media-specific regulations into exposure
scenarios or modeling.
Reviewing reasonably available data that may be used in developing, adapting or
applying exposure models to the particular risk evaluation. For example, existing models
developed for a chemical assessment may be applicable to another chemical assessment if
model parameter data are reasonably available.
Reviewing reasonably available information on releases to determine how modeled
estimates of concentrations near industrial point sources compare with reasonably
available monitoring data.
Reviewing reasonably available population- or subpopulation-specific exposure factors
and activity patterns to determine if PES S need to be further defined.
Evaluating the weight of the scientific evidence of general population exposure data.
Mapping or grouping each condition of use to general population exposure assessment
scenario(s).
EPA plans to evaluate a variety of data types to determine which types are most appropriate
when quantifying exposure scenarios. Environmental monitoring data, biomonitoring data,
modeled estimates, experimental data, epidemiological data, and survey-based data can all be
used to quantify exposure scenarios. In an effort to associate exposure estimates with sources of
exposure and/or conditions of use, EPA plans to consider source apportionment across exposure
scenarios during risk evaluation. EPA anticipates that there will be a wide range in the relative
exposure potential of the exposure scenarios identified in Appendix G. Source apportionment
characterizes the relative contribution of any of the following: a use/source toward a total media
concentration, a media concentration toward a total exposure route, or an exposure route toward
a total external or internal dose. This consideration may be qualitative, semi-quantitative, or
quantitative, and is dependent upon reasonably available data and approaches. For example, EPA
may consider the co-location of TSCA industrial facilities with reasonably available monitoring
data or modeled estimates. EPA may compare modeled estimates for discrete outdoor and indoor
sources/uses that apply to unique receptor groups.
After refining and finalizing exposure scenarios, EPA plans to quantify concentrations and/or
doses for these scenarios. The number of scenarios will depend on how combinations of uses,
exposure pathways, and receptors are characterized. The number of scenarios is also dependent
upon the reasonably available data and approaches to quantify scenarios. When quantifying
exposure scenarios, EPA plans to use a tiered approach. First-tier analysis is based on data that is
reasonably available without a significant number of additional inputs or assumptions, and may
be qualitative, semi-quantitative, or quantitative. The results of first tier analyses inform whether
scenarios require more refined analysis. Refined analyses will be iterative and require careful
consideration of variability and uncertainty. Should data become available that summarily alters
the overall conclusion of a scenario through iterative tiering, EPA can refine its analysis during
risk evaluation.
2) For exposure pathways where empirical data is not reasonably available, review existing
exposure models that may be applicable in estimating exposure levels.
For 1,3-butadiene, media where exposure models will be considered for general population
exposure include models that estimate surface water concentrations, sediment concentrations,
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soil concentrations, and uptake from aquatic and terrestrial environments into edible aquatic and
terrestrial organisms.
3)	Review reasonably available exposure modeled estimates. For example, existing models
developed for a previous 1,3-butadiene chemical assessment may be applicable to EPA's
assessment. In addition, another chemical's assessment may also be applicable if model
parameter data are available.
To the extent other organizations have already modeled 1,3-butadiene general population
exposure scenario that is relevant to this assessment, EPA plans to evaluate those modeled
estimates. In addition, if modeled estimates for other chemicals with similar physical chemical
properties and similar uses are available, those modeled estimates will also be evaluated. The
underlying parameters and assumptions of the models will also be evaluated.
4)	Review reasonably available information on releases to determine how modeled estimates
of concentrations near industrial point sources compare with reasonably available
monitoring data.
The expected releases from industrial facilities are changing over time. Any modeled
concentrations based on recent release estimates will be carefully compared with reasonably
available monitoring data to determine representativeness.
5)	Review reasonably available information about population- or subpopulation-specific
exposure factors and activity patterns to determine if PESS need to be further defined (e.g.,
early life and/or puberty as a potential critical window of exposure).
For 1,3-butadiene, exposure scenarios that involve PESS will consider age-specific behaviors,
activity patterns, and exposure factors unique to those subpopulations. For example, children will
have different intake rates for soil than adults.
6)	Evaluate the weight of the scientific evidence of general population exposure estimates
based on different approaches.
During risk evaluation, EPA plans to evaluate and integrate the exposure evidence identified in
the literature inventory using the methods described in the systematic review documentation that
EPA plans to publish prior to finalizing the scope document.
2.7.3 Hazards (Effects)
2.7.3.1 Environmental Hazards
If EPA identifies hazards through the current systematic review methods and public input, EPA plans to
conduct an environmental hazard assessment of 1,3-butadiene as follows:
1) Review reasonably available environmental hazard data, including data from alternative
test methods (e.g., computational toxicology and bioinformatics; high-throughput screening
methods; data on categories and read-across; in vitro studies).
EPA plans to analyze the hazards of 1,3-butadiene to aquatic and/or terrestrial organisms,
including plants, invertebrates (e.g., insects, arachnids, mollusks, crustaceans), and vertebrates
(e.g., mammals, birds, amphibians, fish, reptiles) across exposure durations and conditions if
potential environmental hazards are identified through systematic review results and public
comments. Additional types of environmental hazard information will also be considered (e.g.,
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analogue and read-across data) when characterizing the potential hazards of 1,3-butadiene to
aquatic and/or terrestrial organisms.
Environmental hazard data will be evaluated using the environmental toxicity data quality
criteria outlined in the systematic review documentation that EPA plans to publish prior to
finalizing the scope document. The study evaluation results will be documented in the risk
evaluation phase and data from suitable studies will be extracted and integrated in the risk
evaluation process.
Hazard endpoints (e.g., mortality, growth, immobility, reproduction) will be evaluated, while
considering data availability, relevance, and quality.
2)	Derive hazard thresholds for aquatic and/or terrestrial organisms.
Depending on the robustness of the evaluated data for a particular organism or taxa (e.g., aquatic
invertebrates), environmental hazard values (e.g., ECx, LCx, NOEC, LOEC) may be derived and
used to further understand the hazard characteristics of 1,3-butadiene to aquatic and/or terrestrial
species. Identified environmental hazard thresholds may be used to derive concentrations of
concern (COC), based on endpoints that may affect populations of organisms or taxa analyzed.
3)	Evaluate the weight of scientific evidence of environmental hazard data.
During risk evaluation, EPA plans to evaluate and integrate the environmental hazard evidence
identified in the literature inventory using the methods described in the systematic review
documentation that EPA plans to publish prior to finalizing the scope document.
4)	Consider the route(s) of exposure, based on reasonably available monitoring and modeling
data and other available approaches to integrate exposure and hazard assessments.
EPA plans to consider aquatic (e.g., water and sediment exposures) and terrestrial pathways in
the 1,3-butadiene conceptual model. These organisms may be exposed to 1,3-butadiene via a
number of environmental pathways (e.g., surface water, sediment, soil, diet).
5)	Conduct an environmental risk characterization of 1,3-butadiene.
EPA plans to conduct a risk characterization of 1,3-butadiene to identify if there are risks to the
aquatic and/or terrestrial environments from the measured and/or predicted concentrations of 1,3-
butadiene in environmental media (i.e., water, sediment, soil). Risk quotients (RQs) may be
derived by the application of hazard and exposure benchmarks to characterize environmental risk
(U.S. EPA. 1998; Bamthouse et al. 1982V
6)	Consider a Persistent, Bioaccumulative, and Toxic (PBT) Assessment of 1,3-butadiene.
EPA plans to consider the persistence, bioaccumulation, and toxic (PBT) potential of 1,3-
butadiene after reviewing relevant physical-chemical properties and exposure pathways. EPA
plans to assess the reasonably available studies collected from the systematic review process
relating to bioaccumulation and bioconcentration (e.g., BAF, BCF) of 1,3-butadiene. In addition,
EPA plans to integrate traditional environmental hazard endpoint values (e.g., LCso, LOEC) and
exposure concentrations (e.g., surface water concentrations, tissue concentrations) for 1,3-
butadiene with the fate parameters (e.g., BAF, BCF, BMF, TMF).
2.7.3.2 Human Health Hazards
EPA plans to analyze human health hazards as follows:
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1)	Review reasonably available human health hazard data, including data from alternative
test methods (e.g., computational toxicology and bioinformatics; high-throughput screening
methods; data on categories and read-across; in vitro studies; systems biology).
EPA plans to use systematic review methods to evaluate the epidemiological and toxicological
literature for 1,3-butadiene. EPA plans to publish the systematic review documentation prior to
finalizing the scope document.
Relevant mechanistic evidence will also be considered, if reasonably available, to inform the
interpretation of findings related to potential human health effects and the dose-repose
assessment. Mechanistic data may include analyses of alternative test data such as novel in vitro
test methods and high throughput screening. The association between acute and chronic exposure
scenarios to the agent and each health outcome will also be integrated. Study results will be
extracted and presented in evidence tables or another appropriate format by organ/system.
2)	In evaluating reasonably available data, determine whether particular human receptor
groups may have greater susceptibility to the chemical's hazard(s) than the general
population.
Reasonably available human health hazard data will be evaluated to ascertain whether some
human receptor groups may have greater susceptibility than the general population to 1,3-
butadiene hazard(s). Susceptibility of particular human receptor groups to 1,3-butadiene will be
determined by evaluating information on factors that influence susceptibility.
EPA has reviewed some sources containing hazard information associated with PESS and
lifestages such as pregnant women and infants. Pregnancy (i.e., gestation) and childhood are
potential susceptible lifestages for 1,3-butadiene exposure. EPA plans to review the current state
of the literature in order to potentially quantify these differences for risk evaluation purposes.
3)	Conduct hazard identification (the qualitative process of identifying non-cancer and cancer
endpoints) and dose-response assessment (the quantitative relationship between hazard
and exposure) for identified human health hazard endpoints.
Human health hazards from acute and chronic exposures will be identified by evaluating the
human and animal data that meet the systematic review data quality criteria described in the
systematic review documentation that EPA plans to publish prior to finalizing the scope
document. Hazards identified by studies meeting data quality criteria will be grouped by routes
of exposure relevant to humans (e.g., oral, dermal, inhalation) and by cancer and noncancer
endpoints.
Dose-response assessment will be performed in accordance with EPA guidance (U.S. EPA.
2.012a. 2011. 1994). Dose-response analyses may be used if the data meet data quality criteria
and if additional information on the identified hazard endpoints are not available or would not
alter the analysis.
The cancer mode of action (MOA) determines how cancer risks can be quantitatively evaluated.
If cancer hazard is determined to be applicable to 1,3-butadiene, EPA plans to evaluate
information on genotoxicity and the mode of action for all cancer endpoints to determine the
appropriate approach for quantitative cancer assessment in accordance with the U.S. EPA
Guidelines for Carcinogen Risk Assessment (U.S. EPA. 2005).
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4)	Derive points of departure (PODs) where appropriate; conduct benchmark dose modeling
depending on the reasonably available data. Adjust the PODs as appropriate to conform
(e.g., adjust for duration of exposure) to the specific exposure scenarios evaluated.
Hazard data will be evaluated to determine the type of dose-response modeling that is applicable.
Where modeling is feasible, a set of dose-response models that are consistent with a variety of
potentially underlying biological processes will be applied to empirically model the dose-
response relationships in the range of the observed data consistent with EPA's Benchmark Dose
Technical Guidance Document. Where dose-response modeling is not feasible, NOAELs or
LOAELs will be identified. Non-quantitative data will also be evaluated for contribution to
weight of the scientific evidence or for evaluation of qualitative endpoints that are not
appropriate for dose-response assessment.
EPA plans to evaluate whether the available PBPK and empirical kinetic models are adequate for
route-to-route and interspecies extrapolation of the POD, or for extrapolation of the POD to
standard exposure durations (e.g., lifetime continuous exposure). If application of the PBPK
model is not possible, oral PODs may be adjusted by BW3'4 scaling in accordance with
(2011). and inhalation PODs may be adjusted by exposure duration and chemical properties in
accordance with U.S. EPA. (1994).
5)	Evaluate the weight of the scientific evidence of human health hazard data.
During risk evaluation, EPA plans to evaluate and integrate the human health hazard evidence
identified in the literature inventory under acute and chronic exposure conditions using the
methods described in the systematic review documentation that EPA plans to publish prior to
finalizing the scope document.
6)	Consider the route(s) of exposure (oral, inhalation, dermal), available route-to-route
extrapolation approaches, reasonably available biomonitoring data and available
approaches to correlate internal and external exposures to integrate exposure and hazard
assessment.
At this stage of review, EPA believes there will be sufficient data to conduct a dose-response
analysis and/or benchmark dose modeling for the oral route of exposure. EPA plans to also
evaluate any potential human health hazards following dermal and inhalation exposure to 1,3-
butadiene, which could be important for the worker, consumer, and general population risk
analyses. Reasonably available data will be assessed to determine whether or not a POD can be
identified for the dermal and inhalation routes. This may include using route-to-route
extrapolation methods, where appropriate and depending on the nature of available data.
If sufficient toxicity studies are not identified in the literature search to assess risks from dermal
and inhalation exposures, then a route-to-route extrapolation from oral toxicity studies would be
needed to assess systemic risks from dermal or inhalation exposures. Without an adequate PBPK
model, the approaches described in EPA guidance document Risk Assessment Guidance for
Superfund Volume I: Human Health Evaluation Manual (Part E, Supplemental Guidance for
Dermal Risk Assessment) (U.S. EPA. 2004) could be applied to extrapolate from oral to dermal
exposure. These approaches may be able to further inform the relative importance of dermal
exposures compared with other routes of exposure. Similar methodology may also be used for
assessing inhalation exposures
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2.7.4 Summary of Risk Approaches for Characterization
Risk characterization is an integral component of the risk assessment process for both environmental and
human health risks. EPA plans to derive the risk characterization in accordance with EPA's Risk
Characterization Handbook (U.S. EPA. 2000). As defined in EPA's Risk Characterization Policy, "the
risk characterization integrates information from the preceding components of the risk evaluation and
synthesizes an overall conclusion about risk that is complete, informative and useful for decision
makers." Risk characterization is considered to be a conscious and deliberate process to bring all
important considerations about risk, not only the likelihood of the risk but also the strengths and
limitations of the assessment, and a description of how others have assessed the risk into an integrated
picture.
The level of information contained in each risk characterization varies according to the type of
assessment for which the characterization is written. Regardless of the level of complexity or
information, the risk characterization for TSCA risk evaluations will be prepared in a manner that is
transparent, clear, consistent, and reasonable (U.S. EPA. 2000) and consistent with the requirements of
the Procedures for Chemical Risk Evaluation Under the Amended Toxic Substances Control Act (82 F R
6). For instance, in the risk characterization summary, EPA plans to further carry out the
requirements under TSCA section 26; for example, by identifying and assessing uncertainty and
variability in each step of the risk evaluation, discussing considerations of data quality such as the
reliability, relevance and whether the methods utilized were reasonable and consistent, explaining any
assumptions used, and discussing information generated from independent peer review.
EPA plans to be guided by EPA's Information Quality Guidelines (U.S. EPA. 2002) as it provides
guidance for presenting risk information. Consistent with those guidelines, EPA plans to identify in the
risk characterization the following: (1) Each population addressed by an estimate of applicable risk
effects; (2) The expected risk or central estimate of risk for the PESS affected; (3) Each appropriate
upper-bound or lower-bound estimate of risk; (4) Each significant uncertainty identified in the process
of the assessment of risk effects and the studies that would assist in resolving the uncertainty; and (5)
Peer reviewed studies known to the Agency that support, are directly relevant to, or fail to support any
estimate of risk effects and the methodology used to reconcile inconsistencies in the scientific
information.
2.8 Peer Review
Peer review will be conducted in accordance with EPA's regulatory procedures for chemical risk
evaluations, including using EPA's Peer Review Handbook and other methods consistent with section
26 of TSCA (See 40 CFR 702.45). As explained in the preamble to the Risk Evaluation Rule, the
purpose of peer review is for the independent review of the science underlying the risk assessment (See
82 Fed. Reg. 33726, 33744 (July 12, 2017). Peer review will therefore address aspects of the underlying
science as outlined in the charge to the peer review panel such as hazard assessment, assessment of
dose-response, exposure assessment, and risk characterization. The draft risk evaluation for 1,3-
butadiene will be peer reviewed.
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U.S. EPA (U.S. Environmental Protection Agency). (2013). 1986-2002 inventory update reporting rule
data (non-confidential production volume in pounds). Washington, DC: Washington, DC. U.S.
Environmental Protection Agency, Office of Pollution Prevention and Toxics. HERO ID: 6114854
U.S. EPA (U.S. Environmental Protection Agency). (2013). ChemSTEER user guide - Chemical
screening tool for exposures and environmental releases. Washington, D.C.
https://www.epa.gov/sites/production/files/2015-05/documents/user_guide.pdf. HERO ID: 3809033
U.S. EPA (U.S. Environmental Protection Agency). (2015). Science policy council peer review
handbook [EPA Report] (4th ed.). (EPA/100/B-15/001). Washington, DC: U.S. Environmental
Protection Agency, Science Policy Council. HERO ID: 3350604
U.S. EPA (U.S. Environmental Protection Agency). (2016). Hydraulic fracturing for oil and gas:
Impacts from the hydraulic fracturing water cycle on drinking water resources in the United States.
EPA-600-R-16-236Fb. December 2016.
https://cfpub.epa.gov/ncea/hfstudy/recordisplay.cfm?deid=332990. HERO ID: 6171032
U.S. EPA (U.S. Environmental Protection Agency). (2017a). Chemical data reporting (2012 and 2016
Public CDR database) [Database], Washington, DC: U.S. Environmental Protection Agency, Office of
Pollution Prevention and Toxics, http://www.epa.gov/cdr/. HERO ID: 6275311
U.S. EPA (U.S. Environmental Protection Agency). (2017). Federal Register: Procedures for chemical
risk evaluation under the amended toxic substances control act. Fed Reg 82: 33726-33753. HERO ID:
6302803
U.S. EPA (U.S. Environmental Protection Agency). (2017). Procedures for chemical risk evaluation
under the amended Toxic Substances Control Act. Final Rule Federal Registrar 82: 33726-33753. Fed
Reg 82. HERO ID: 6128248
U.S. EPA (U.S. Environmental Protection Agency). (2018). 40 CFR 702.41: Procedures for Chemical
Substance Risk Evaluations: Evaluation requirements. Washington, DC.
https://www.govinfo.gOv/content/pkg/CFR-2018-title40-vol33/xml/CFR-2018-title40-vol33-
part702.xml#seqnum702.41. HERO ID: 6302779
U.S. EPA (U.S. Environmental Protection Agency). (2018). 40 CFR § 702.45: Procedures for Chemical
Substance Risk Evaluations: Peer review. (Code of Federal Regulations Title 40 Section 702.45).
Washington, DC. https://www.govinfo.gov/content/pkg/CFR-2018-title40-vol33/xml/CFR-2018-title40-
vol33-part702.xml#seqnum702.45. HERO ID: 6302780
U.S. EPA (U.S. Environmental Protection Agency). (2018). Application of systematic review in TSCA
risk evaluation. Washington D.C.: U.S. Environmental Protection Agency, Office of Pollution
60

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Prevention and Toxics, https://www.epa.gov/sites/production/files/2018-
06/documents/final_application_of_sr_in_tsca_05-3l-18.pdf. HERO ID: 6307833
U.S. EPA (U.S. Environmental Protection Agency). (2018). Application of systematic review in TSCA
risk evaluations. (740-P1-8001). Washington, DC: U.S. Environmental Protection Agency, Office of
Chemical Safety and Pollution Prevention, https://www.epa.gov/sites/production/files/2018-
06/documents/final_application_of_sr_in_tsca_05-3l-18.pdf. HERO ID: 4532281
U.S. EPA (U.S. Environmental Protection Agency). (2019a). Proposed designation of 1,3-butadiene
(CASRN 106-99-0) as a high-priority substance for risk evaluation. U.S. Environmental Protection
Agency, Office of Chemical Safety and Pollution Prevention. HERO ID: 6307835
U.S. EPA (U.S. Environmental Protection Agency). (2019b). Chemical Data Reporting (2012 and 2016
CBI CDR database). Washington, DC. U.S. Environmental Protection Agency, Office of Pollution
Prevention and Toxics. Retrieved: April 25, 2019.
U.S. EPA (U.S. Environmental Protection Agency). (2019). 40 CFR 704.3: Definitions. (Code of
Federal Regulations Title 40 Section 704.3). Washington, DC.
https://www.govinfo.gov/app/details/CFR-2019-title40-vol33/CFR-2019-title40-vol33-sec704-3. HERO
ID: 6307823
U.S. EPA (U.S. Environmental Protection Agency). (2019). 40 CFR § 302.4: Designation of hazardous
substances. (Code of Federal Regulations Title 40 Section 302.4).
https://www.govinfo.gov/app/details/CFR-2019-title40-vol30/CFR-2019-title40-vol30-sec302-4. HERO
ID:6305426
U.S. EPA (U.S. Environmental Protection Agency). (2019). 40 CFR § 372.65: Chemicals and chemical
categories to which this part applies. (Code of Federal Regulations Title 40 Section 372.65).
Washington, DC. https://www.govinfo.gov/app/details/CFR-2019-title40-vol30/CFR-2019-title40-
vol30-sec372-65. HERO ID: 3808937
U.S. EPA (U.S. Environmental Protection Agency). (2019). Envirofacts Toxics Release Inventory 2017
Updated Dataset (released April 2019) [Website], https://www.epa.gov/enviro/tri- customized-search.
HERO ID: 6127841
U.S. EPA (U.S. Environmental Protection Agency). (2019). National emission standards for hazardous
air pollutants (NESHAP). https://www.epa.gov/stationary-sources-air-pollution/national-emission-
standards-hazardous-air-pollutants-neshap-9. HERO ID: 6305207
U.S. EPA (U.S. Environmental Protection Agency). (2019). Proposed designation of 1,3-butadiene
(CASRN 106-99-0) as a high-priority substance for risk evaluation. U.S. Environmental Protection
Agency, Office of Chemical Safety and Pollution Prevention. HERO ID: 6307835
Watkinson, RJ; Somerville, HJ. (1976). The microbial utilization of butadiene. In Proceedings of the
Third International Biodegradation Symposium London. London: Applied Science Publishers. HERO
ID:5349224
Wilmarth, CM. (2019). Comment submitted by Catherine M. Wilmarth, Attorney, Alliance of
Automobile Manufacturers and Laurie Holmes, Senior Director, Environmental Policy, Motor &
Equipment Manufacturers Association (MEMA) regarding 1,3 Butadiene. (EPA-HQ-OPPT-2019-0131-
0022). Wilmarth, CM. https://www.regulations.gov/document?D=EPA-HQ-OPPT-2019-0131-0022.
HERO ID: 6307836
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APPENDICES
Appendix A LIST OF GRAY LITERATURE SOURCES
Table Apx A-l provides a list of gray literature sources that yielded results for 1,3-Butadiene.
Table Apx A-l Gray Literature Sources for 1,3-Butadiene
Source/
Agency
Source Name
Source Type
Source Category
AT SDR
ATSDR Tox Profile Updates and
Addendum s
Other US Agency
Resources
Assessment or
Related Document
AT SDR
ATSDR Toxicological Profiles
(original publication)
Other US Agency
Resources
Assessment or
Related Document
Australian
Governme
nt
Departmen
t of Health
NICNAS Assessments (human health.
Tier I, 11 or 111)
International
Resources
Assessment or
Related Document



CAL EPA
Technical Support Documents for
regulations: Cancer Potency
Information
Other US Agency
Resources
Assessment or
Related Document
CAL EPA
Technical Support Documents for
regulations: Reference Exposure
Levels (RELs)
Other US Agency
Resources
Assessment or
Related Document
ECHA
European Union Risk Assessment
Report
International
Resources
Assessment or
Related Document
ECHA
ECHA Documents
International
Resources
Assessment or
Related Document
Env
Canada
Priority Substances List Assessment
Report; State of Science Report,
Environment Canada Assessment
International
Resources
Assessment or
Related Document
EPA
Office of Water: STORET and WQX
US EPA
Resources
Database
EPA
Office of Air: TRI
US EPA
Resources
Database
EPA
Office of Air: AQS, Annual
US EPA
Resources
Database
62

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Source/
Vacuo
Source Nstnic
Source Type
Source Category
EPA
TSCA. Hazard Characterizations
US EPA
Resources
Assessment or
Related Document
EPA
IRIS Summary
US EPA
Resources
Assessment or
Related Document
EPA
Office of Air: National Emissions
Inventory (NEI) Data (2014, 201 1,
2008)
US EPA
Resources
Database
EPA
Other EPA: Misc sources
US EPA
Resources
General Search
EPA
EPA: AP-42
US EPA
Resources
Regulatory
Document or List
EPA
TRI: Envirofacts Toxics Release
Inventory 2017 Updated Data set
US EPA
Resources
Database
EPA
Chemical Data Reporting (2012 and
2016 non-CBI CDR database)
US EPA
Resources
Database
EPA
Chemical Data Reporting (2012 and
2016 CBI CDR database)
US EPA
Resources
Database
EPA
EPA: Generic Scenario
US EPA
Resources
Assessment or
Related Document
EPA
EPA Discharge Monitoring Report
Data
US EPA
Resources
Database
EPA
EPA Ambient Monitoring Technology
Information Center - Air Toxics Data
US EPA
Resources
Database
EPA
IRIS Tox Review
US EPA
Resources
Assessment or
Related Document
EPA
Office of Water: CFRs
US EPA
Resources
Regulatory
Document or List
EPA
Office of Air: CFRs and Dockets
US EPA
Resources
Regulatory
Document or List
I ARC
I ARC Monograph
International
Resources
Assessment or
Related Document
Japan
Japanese Ministry of the Environment
Assessments - Environmental Risk
International
Resources
Regulatory
Document or List
63

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Source/
Vacuo
Source Nstnic
Source Type
Source Category

Assessments (Class I Designated
Chemical Substances Summary Table)


KOECT
Kirk-Othmer Encyclopedia of
Chemical Technology Journal Article
Other Resource
Encyclopedia
NIOSH
CDC NIOSH - Occupational Health
Guideline Documents
Other US Agency
Resources
Assessment or
Related Document
NIOSH
CDC NIOSH - Pocket Guides
Other US Agency
Resources
Database
NIOSH
CDC NIOSH - Health Hazard
Evaluations (HHEs)
Other US Agency
Resources
Assessment or
Related Document
NIOSH
CDC NIOSH - Workplace Survey
Reports
Other US Agency
Resources
Assessment or
Related Document
NIOSH
CDC NIOSH - Publications and
Products
Other US Agency
Resources
Assessment or
Related Document
NLM
National Library of Medicine's
Hazardous Substance Databank
Other US Agency
Resources
Database
NLM
National Library of Medicine's
HazMap
Other US Agency
Resources
Database
NTP
OHAT Monographs
Other US Agency
Resources
Assessment or
Related Document
NTP
RoC Monographs
Other US Agency
Resources
Assessment or
Related Document
NTP
Technical Reports
Other US Agency
Resources
Assessment or
Related Document
OECD
OECD Emission Scenario Documents
International
Resources
Assessment or
Related Document
OECD
OECD: General Site
International
Resources
General Search
OSHA
U.S. OSHA Chemical Exposure
Health Data (CEHD) program data
[ERG]
Other US Agency
Resources
Database
TERA
Toxicology Excellence for Risk
Assessment
Other Resources
Assessment or
Related Document
64

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Appendix B PHYSICAL AND CHEMICAL PROPERTIES OF 1,3-
BUTADIENE
This appendix provides p-chem information and data found in preliminary data gathering for 1,3-
butadiene. Table Apx B-l summarizes the p-chem property values preliminarily selected for use in the
risk evaluation from among the range of reported values collected as of March 2020. This table differs
from that presented in the Proposed Designation of 1.3-Butadiene fCASRN 106-99-0) as a High-Priority
Substance for Risk Evaluation (U.S. EPA 2019a) and may be updated as EPA collects additional
information through systematic review methods. All p-chem property values that were extracted and
evaluated as of March 2020 are presented in the supplemental file Data Extraction and Data Evaluation
Tables for Physical Chemical Property Studies (EPA-HO-OPPT-2Q18-0451).
Table Apx B-l Physical and Chemical Properties of 1,3-Butadiene
Properly or Kmlpoinl
Value"
Reference
Data Quality
Kill in«
Molecular formula
C4H6
NA
NA
Molecular weight
54.09 g/mol
NA
NA
Physical state
Colorless gas
Rumble, 2018
High
Physical properties
Colorless, mildly
aromatic or gasoline-
like odor
NLM, 2003
High
Melting point
-108.966°C
O'Neil, 2013
High
Boiling point
-4.5 C at 760 mm Hg
O'Neil, 2013
High
Density
0.6149 g/cm3 at 25°C
and >1 atm
Rumble, 2018
High
Vapor pressure
2110 mm Hg
U.S. EPA, 2019
High
Vapor density
1.87 (air = 1)
NLM, 2003
High
Water solubility
735 rng/L at 20°C
NLM, 2003
High
Log Octanol/water partition
coefficient (Log Kow)
1.99 at 25°C
Rumble, 2018
High
Henry's Law constant
0.204 atm-nrVmol. at
25°C
Rumble, 2018
High
65

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Propcrlv or Kmlpoinl
\ Slllll"1
Ucfcroncc
Dsilsi Qusililv
K;i( in«
Flash point
-76.111°C
RSC, 2019
High
Auto flammability
420°C
Rumble, 2018
High
Viscosity
0.00754 cP at 20°C
NLM, 2003
High
Refractive index
1.4292
Rumble, 2018
High
Dielectric constant
2.050
Rumble, 2018
High
a Measured unless otherwise noted.
NA = Not applicable
66

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Appendix C ENVIRONMENTAL FATE AND TRANSPORT
PROPERTRIES
Table Apx C-l provides the environmental fate characteristics that EPA identified and considered in
developing the scope for 1,3-butadiene.
Table Apx C-l. Environmental Fate Characteristics of 1,3-Butadiene
Properly or
K ml point
Value
Reference
Direct
Photodegradati on
Absorbs at wavelengths >290 nm, and
therefore, may be susceptible to direct
photolysis by sunlight
PubChem (2020)
The primary pathway of destruction of
1,3-butadiene is likely to occur by photo-
initiated bimolecular processes rather than
direct photochemical degradation
DR (2.012); Kooczvnski et al.
(1972)

ti/2 = 3.7 hours (based on a 12-hour day
with 1.5 x 106 OH/cm3 and hydroxyl
radical reaction rate constant of 6.93 x 10"
11 cm3/molecule-sec at 25 °C)
PubChem (2020)

ti/2 = 5.6 hours (based on a 12-hour day
with 5 x 105 molecules OH/cm3 and
hydroxyl radical reaction rate constant of
6.93 x 10"11 cm3/molecule-sec at 25 °C)
AT SDR (2012) citing Atkinson
(1989) and Baker et al. (2005)

Major products formed from the reaction
include acrolein and formaldehyde

Indirect
Photodegradati on
ti/2 = 1.4-1.7 days (based on a 12-hour day
with 7 x 1011 molecules ozone/cm3 and an
ozone reaction rate constant of 6.7 x 10"18
cm3/molecule-sec at 25 °C)
Major products formed from the reaction of
1,3-butadiene with ozone are acrolein,
formaldehyde, acetylene, ethylene, and
formic anhydride
PubChem (2020); AT SDR (2012)
citing Atkinson and Carter (1984)

ti/2 = 14.9 hours (based on a 12-hour day
with 2.4 x 108 nitrate molecules/cm3 and a
nitrate radical reaction rate constant of
5.4 x 10"14 cm3/molecule-sec at 22 °C)
PubChem (2020); AT SDR (2012)
citing Atkinson et al. (1984)

Acrolein was identified as the major
product of this reaction

67

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Hydrolysis
Not expected to hydrolyze due to lack of
hydrolysable functional groups
EOH2W2)
Metabolic byproducts of 1,3-butadiene can
be hydrolyzed rapidly
DR (2012) citing Kirman
(2010)
Biodegradation
0-4%/28 days (based on OECD 301C
study with 1-drop of sludge/L)b
NITE (2
Biodegradation of 1,3-butadiene in water
and soil proceeds through oxidation to
form 3,4-epoxy-l-butene, a potent
electrophile (with pure cultures)
DR (2012) citing Hou et al.
(1979); Patel et al. (1982), and
Watkinson and Somerville (1976)
Wastewater
Treatment
97% total removal (0.02% by
biodegradation, 0.53% by sludge, 96% by
volatilization to air; estimated)13
I ? n \tioi;)
Bioconcentration
Factor
10 (estimated)0
l v l i \ , AM-)
Bioaccumulation
Factor
10 (estimated)0
l ? t
Soil Organic
Carbon:Water
Partition Coefficient
(Log Koc)
2.46
AT SDR (2012) citing Hansch et
al. (1995) and Lyman et al. (1990)
aMeasured unless otherwise noted
bOECD 301C may be an inappropriate test method for volatile substances if precautions are not taken
to prevent sample loss
CEPI Suite™ physical property inputs: Log Kow = 1.99, BP = -4.40 °C, MP = -108.90 °C, VP = 2110
mm Hg, WS = 735 mg/L SMILES C(C=C)=C
68

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Appendix D REGULATORY HISTORY
The chemical substance, 1,3-butadiene, is subject to federal and state laws and regulations in the United
States (TableApx D-land TableApx D-2). Regulatory actions by other governments, tribes and
international agreements applicable to 1,3-butadiene are listed in Table Apx_A-3.
D.l Federal Laws and Regulations
Table Apx D-l. Federal Laws and Regulations
Mat iitcs/Uegulal ions
Description of
Authority/Regulation
Description of Regulation
Toxic Substances Control Act
(TSCA) - Section 6(b)
EPA is directed to identify high-
priority chemical substances for
risk evaluation; and conduct risk
evaluations on at least 20 high
priority substances no later than
three and one-half years after the
date of enactment of the Frank R.
Lautenberg Chemical Safety for
the 21st Century Act.
1,3-Butadiene is one of the 20
chemicals EPA designated as a
High-Priority Substance for risk
evaluation under TSCA (84 FR
71924. December 30. 20191
Designation of 1,3-butadiene as
a high-priority substance
constitutes the initiation of the
risk evaluation on the chemical.
Toxic Substances Control Act
(TSCA) - Section 8(a)
The TSCA section 8(a) CDR Rule
requires manufacturers (including
importers) to give EPA basic
exposure-related information on
the types, quantities, and uses of
chemical substances produced
domestically and imported into the
United States.
1,3-Butadiene manufacturing
(including importing),
processing, and use information
is reported under the CDR rule
(76 FR 50816, August 16,
2011).
Toxic Substances Control Act
(TSCA) - Section 8(b)
EPA must compile, keep current,
and publish a list (the TSCA
Inventory) of each chemical
substance manufactured (including
imported) or processed in the
United States.
1,3-Butadiene was on the initial
TSCA Inventory and therefore
was not subject to EPA's new
chemicals review process under
TSCA section 5 (60 FR 16309,
March 29, 1995).
Toxic Substances Control Act
(TSCA) - Section 8(e)
Manufacturers (including
importers), processors, and
distributors must immediately
notify EPA if they obtain
information that supports the
conclusion that a chemical
substance or mixture presents a
substantial risk of injury to health
or the environment.
20 risk reports received for 1,3-
butadiene (2017, 2011, 2008-
2007, 2005, 2002-1997, 1995-
1994, 1992, 1990) (U.S. EPA,
ChemView. Accessed April 8,
2019).
69

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Emergency Planning and
Community Right-To-Know Act
(EPCRA)- Section 313
Requires annual reporting from
facilities in specific industry
sectors that employ 10 or more
full-time equivalent employees and
that manufacture, process or
otherwise use a TRI-listed
chemical in quantities above
threshold levels. A facility that
meets reporting requirements must
submit a reporting form for each
chemical for which it triggered
reporting, providing data across a
variety of categories, including
activities and uses of the chemical,
releases and other waste
management (e.g., quantities
recycled, treated, combusted) and
pollution prevention activities
(under section 6607 of the
Pollution Prevention Act). These
data include on- and off-site data as
well as multimedia data (i.e., air,
land and water).
1,3-Butadiene is a listed
substance subject to reporting
requirements under 40 CFR
372.65, effective as of January
01, 1987.
Clean Air Act (CAA) - Section
112(b)
Defines the original list of 189
hazardous air pollutants (HAPs).
Under 112(c) of the CAA, EPA
must identify and list source
categories that emit HAP and then
set emission standards for those
listed source categories under CAA
section 112(d). CAA section
112(b)(3)(A) specifies that any
person may petition the
Administrator to modify the list of
HAP by adding or deleting a
substance. Since 1990, EPA has
removed two pollutants from the
original list leaving 187 at present.
1,3-Butadiene is listed as a
HAP (42 U.S. Code section
7412).
Clean Air Act (CAA) - Section
112(d)
Directs EPA to establish, by rule,
NESHAPs for each category or
subcategory of listed major sources
and area sources of HAPs (listed
pursuant to Section 112(c)). For
major sources, the standards must
require the maximum degree of
emission reduction that EPA
EPA has established NESHAPs
for a number of source
categories that emit 1,3-
butadiene to air. (See
httDs://www.eoa.eov/stationarv-
sources-air-oollution/national-
emission-standards-hazardous-
air-oollutants-neshao-9)
70

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determines is achievable by each
particular source category. This is
generally referred to as maximum
achievable control technology
(MACT). For area sources, the
standards must require generally
achievable control technology
(GACT) though may require
MACT.

Clean Air Act (CAA) - Section
183(e)
Section 183(e) requires EPA to list
the categories of consumer and
commercial products that account
for at least 80 percent of all VOC
emissions in areas that violate the
National Ambient Air Quality
Standards (NAAQS) for ozone and
to issue standards for these
categories that require "best
available controls." In lieu of
regulations, EPA may issue control
techniques guidelines if the
guidelines are determined to be
substantially as effective as
regulations.
1,3-Butadiene is listed under
the National Volatile Organic
Compound Emission Standards
for Aerosol Coatings (40 CFR
part 59, subpart E). 1,3-
Butadiene has a reactivity
factor of 13.58 g 03/g VOC.
Safe Drinking Water Act
(SDWA) - Section 1412(b)
Every 5 years, EPA must publish a
list of contaminants that: (1) are
currently unregulated, (2) are
known or anticipated to occur in
public water systems (PWSs) and
(3) may require regulations under
SDWA. EPA must also determine
whether to regulate at least five
contaminants from the list every 5
years.
1,3-Butadiene was identified on
both the Third (2009) and
Fourth (2016) Contaminant
Candidate Lists (CCL) (74 FR
51850, October 8, 2009) (81 FR
81099, November 17, 2016).
Safe Drinking Water Act
(SDWA) - Section 1445(a)
Every 5 years, EPA must issue a
new list of no more than 30
unregulated contaminants to be
monitored by PWSs. The data
obtained must be entered into the
National Drinking Water
Contaminant Occurrence Database.
1,3-Butadiene was identified in
the Third Unregulated
Contaminant Monitoring Rule
(UCMR3), issued in 2012 (77
FR 26071, May 2, 2012).
Comprehensive Environmental
Authorizes EPA to promulgate
regulations designating as
hazardous substances those
substances which, when released
1,3-Butadiene is a hazardous
substance under CERCLA.
Releases of 1,3-butadiene in
71

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Response, Compensation and
Liability Act (CERCLA) -
Sections 102(a) and 103
into the environment, may present
substantial danger to the public
health or welfare or the
environment.
EPA must also promulgate
regulations establishing the
quantity of any hazardous
substance the release of which
must be reported under Section
103.
Section 103 requires persons in
charge of vessels or facilities to
report to the National Response
Center if they have knowledge of a
release of a hazardous substance
above the reportable quantity
threshold.
excess of 10 pounds must be
reported (40 CFR 302.4).
Superfund Amendments and
Reauthorization Act (SARA) -
Requires the Agency to revise the
hazardous ranking system and
update the National Priorities List
of hazardous waste sites, increases
state and citizen involvement in the
superfund program and provides
new enforcement authorities and
settlement tools.
1,3-Butadiene is listed on
SARA, an amendment to
CERCLA and the CERCLA
Priority List of Hazardous
Substances. This list includes
substances most commonly
found at facilities on the
CERCLA National Priorities
List (NPL) that have been
deemed to pose the greatest
threat to public health.
Occupational Safety and Health
Act (OSHA)
Requires employers to provide
their workers with a place of
employment free from recognized
hazards to safety and health, such
as exposure to toxic chemicals,
excessive noise levels, mechanical
dangers, heat or cold stress or
unsanitary conditions (29 U.S.C
section 651 et seq.).
Under the Act, OSHA can issue
occupational safety and health
standards including such
provisions as Permissible Exposure
Limits (PELs), exposure
monitoring, engineering and
OSHA established a PEL for
1,3-butadiene of 1 ppm / 5 ppm
short-term exposure limit
(STEL) as an 8-hour, TWA (29
CFR 1910.1051).
72

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administrative control measures,
and respiratory protection.
D.2 State Laws and Regulations
Table Apx D-2. State Laws and Regulations
Stale Actions
Description of Action
State Air Regulations
Allowable Ambient Levels: New Hampshire (Env-A 1400: Regulated Toxic
Air Pollutants). Rhode Island (Air Pollution Regulation No. 22).
State PELs
California (PEL of 1 ppm and a STEL of 5) (Cal Code Regs. Title 8, §
5155)
Hawaii PEL: 1 ppm (Hawaii Administrative Rules section 12-60-50).
State Right-to-Know
Acts
Massachusetts (105 Code Mass. Regs. § 670.000 Appendix A), New Jersey
(N.J.A.C. 7:1G) and Pennsylvania (P.L. 734, No. 159 and 34 Pa. Code §
323).
Chemicals of High
Concern to Children
Two states have adopted reporting laws for chemicals in children's products
containing 1,3-butadiene, including Maine (38 MRSA Chapter 16-D) and
Minnesota (Toxic Free Kids Act Minn. Stat. 116.9401 to 116.9407).
Other
California listed 1,3-butadiene on Proposition 65 in 1998 due to cancer, and
in 2004 due to developmental toxicity and female/male reproductive
toxicity. (Cal Code Regs. Title 27, § 27001).
1,3-Butadiene is listed as a Candidate Chemical under California's Safer
Consumer Products Program established under Health and Safety Code §
25252 and 25253 (California, Candidate Chemicals List. Accessed April 15,
2019).
California lists 1,3-butadiene as a designated priority chemical for
biomonitoring under criteria established by California SB 1379
(Biomonitoring California, Priority Chemicals, February 2019).
1,3-Butadiene is on the MA Toxic Use Reduction Act (TURA) list of 2019
(301 CMR 41.00).
73

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D.3 International Laws and Regulations
Tahle_Apx D-3. Regulatory Actions hv other Governments. Tribes, and International Agreements
Country/Tribe/
Organization
Requirements and Restrictions
Canada
1,3-Butadiene is on the Canadian List of Toxic Substances (CEPA 1999
Schedule 1).
Other regulations include:
Canada's National Pollutant Release Inventory (NPRI) Part 1A as a VOC.
European Union
1,3-Butadiene is registered for use in the EU with no restrictions.
CoRAP (Final)
1,3-Butadiene was evaluated under the 2014 Community rolling action plan
(CoRAP) under regulation European Commission (EC) Nol907/2006 -
REACH (Registration, Evaluation, Authorisation and Restriction of
Chemicals) ECHA database. Accessed April 10, 2019.
Australia
1,3-Butadiene was assessed under Human Health Tier II of the Inventory
Multi-Tiered Assessment and Prioritisation (IMAP). Uses reported include:
•	Producing synthetic rubber (used to manufacture automotive tyres and tyre
products);
•	Producing plastics such as acrylics, high impact polystyrene and
acrylonitrile butadiene styrene (ABS) resin plastics, nylon and neoprene;
•	Producing resins;
•	Processing petroleum;
•	As a chemical intermediate in producing some fungicides; and
•	In manufacturing latex adhesives and paints.
(NICNAS, 2013, Human Health Tier II assessment for 1,3-butadiene.
Accessed April 16, 2019).
Japan
1,3-Butadiene is regulated in Japan under the following legislation:
Act on the Evaluation of Chemical Substances and Regulation of Their
Manufacture, etc. (Chemical Substances Control Law; CSCL)
Act on Confirmation, etc. of Release Amounts of Specific Chemical
Substances in the Environment and Promotion of Improvements to the
Management Thereof
Industrial Safety and Health Act (ISHA)
Air Pollution Control Law
(Accessed April 10, 2019.)
Basel Convention
Solid Plastic Waste is listed as a category of waste under the Basel
Convention. Although the United States is not currently a party to the Basel
Convention, this treaty still affects U.S. importers and exporters.
74

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Australia, Austria,	Occupational exposure limits for 1,3-butadiene (GESTIS International limit
Belgium, Canada,	values for chemical agents (Occupational exposure limits, OELs) database.
Denmark, European (Accessed April 16, 2019.)
Union, Finland, France,
Germany, Hungary,
Ireland, Latvia, New
Zealand, People's
Republic of China,
Poland, Romania,
Singapore, South Korea,
Spain, Sweden,
Switzerland, The
Netherlands, United
Kingdom
75

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Appendix E PROCESS, RELEASE AND OCCUPATIONAL
EXPOSURE INFORMATION
This appendix provides information and data found in preliminary data gathering for 1,3-butadiene.
E.l Process Information
Process-related information potentially relevant to the risk evaluation may include process diagrams,
descriptions and equipment. Such information may inform potential release sources and worker
exposure activities. EPA plans to consider this information in combination with available monitoring
data and estimation methods and models, as appropriate, to quantify occupational exposure and releases
for the various conditions of use in the risk evaluation.
E.l.l Manufacture (Including Import)
E.l.1.1 Domestic Manufacture
1,3 Butadiene can be produced by three processes: dehydrogenation of n-butane, oxydehydrogenation of
n-butenes, and in the process of the steam cracking of hydrocarbon streams for ethylene production. The
most common method is as a co-product during ethylene production (Sun, 2002). The process can use a
variety of hydrocarbon feedstocks, the heavier fractions generally giving a higher 1,3-butadiene
yield/amount of ethylene produced (Miller, 1978)
In the production process, the hydrocarbon feedstock is pre-heated and cracked in the presence of steam.
The product then passes to a pyrolysis/quench system and additional refinery steps and a mixed C4-
hydrocarbon stream is obtained. Figure Apx E-l is provided as an example process flow diagram of the
1,3-butadiene manufacturing process. The 1,3-butadiene content in the 'crude butadiene' can be as high
as 75% (ACC, 2019b). 1,3-Butadiene cannot normally be obtained from the mixed C4-stream by simple
distillation and so an extractive distillation process is often used. In this process, a polar solvent (e.g.,
furfural, acetonitrile, cuprous ammonium acetate, dimethylformamide, a furfural-methoxypropionitrile
system, dimethylacetamide or n-m ethyl pyrrol i done) is added in order to change the relative volatilities
of the components of the mixture (Miller, 1978; Peterson et al., 1980; IARC, 1986).
76

-------
FigureApx E-l. Process Flow Diagram of Manufacture of 1,3-butadiene via Steam Cracking of Hydrocarbons CEP A. 1996)
77

-------
E.1.1.2 Import
According to (Sun, 2002), 1,3-butadiene is primarily shipped in pressurized containers via railroads or
tankers. Other forms of transport include pipeline and barge (NTP, 1999). Uses of 1,3-butadiene are
covered by other conditions of use including, but not limited to: processing as a reactant, and to form
polymers for rubber and plastics manufacturing, formulated into processing aids and coatings,
incorporated into plastic and rubber articles, and used as a laboratory chemical.
E.1.2 Processing and Distribution
Based on the reported industrial processing operations in the 2016 CDR, 1,3-butadiene may be
incorporated into a variety of formulations, products and articles, or used industrially as a chemical
intermediate (U.S. EPA, 2019). The main use being as a monomer to produce plastic and rubber
products. Some industrial or commercial products may also be repackaged into appropriately-sized
containers to meet specific customer demands (U.S. EPA, 2019).
E.l.2.1 Reactant or Intermediate
Polymerization of Butadiene
Processing as a reactant includes the polymerization of butadiene with itself or with other monomers
(Sun, 2002). Some of the common polymers derived from the use of 1,3-butadiene as a monomer
feedstock are:
•	Polybutadiene
•	Styrene-butadiene rubber
•	Styrene-butadiene latex
•	Acrylonitrile-butadiene-styrene polymer
The general process at polymerization sites is unloading of 1,3-butadiene, a washing or purification step
to remove polymerization inhibitors, then the different monomers are added to the reactor. After
completion of reaction, the content of unreacted monomer may vary depending on the reactions and
additives used. Typically, this may be followed with a butadiene monomer recovery system to recycle
1,3 butadiene back to feed into the reactor. Polymer production can be done either via emulsion
polymerization or solution polymerization depending on the end product use. The final polymer
products may be packaged to sale to downstream users (EPA, 1996). This polymerization product is
incorporated into various rubber and plastic articles as discussed below.
Chemical Intermediate
1,3-Butadiene has also been noted as a chemical intermediate for
•	Ethylidene norbornene (EPA, 1996)
•	Trans-1,4-hexadiene (EPA, 1996)
•	Chioroprene (EPA, 1996)
•	Sulfolane (EPA, 1996)
•	Adiponitrile (EPA, 1996)
•	in petrochemical manufacturing operations, including fuels (U.S. EPA, 2019).
E.l.2.2 Incorporated into a Formulation, Mixture or Reaction Product
Incorporation into a formulation, mixture or reaction product refers to the process of mixing or blending
of several raw materials to obtain a single product or preparation. 1,3-Butatiene is used as processing
aids and butadiene polymers are used in several petrochemical manufacturing operations, adhesives,
lubricants and in formulated paints and coatings (U.S. EPA, 2019).
78

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E. 1.2.3 Incorporated into an Article
Incorporation into an article typically refers to a process in which a chemical becomes an integral
component of an article (as defined at 40 CFR 704.3) for distribution in commerce. Exact process
operations involved in the incorporation of 1.3-butadiene-containing formulations or reaction products
are dependent on the article. EPA identified the following processing activities that incorporate 1,3-
butadiene and 1,3-butadiene formulations or reaction products into articles.
Plastics and Rubber Product Manufacturing
1,3-Butadiene is used as a monomer or co-monomer in the manufacture of synthetic rubbers as
described earlier. These synthetic rubbers and latex are used to manufacture tires, other rubber
components and plastic materials (U.S. EPA, 2019).
In plastic manufacturing, the final plastic article is produced in a conversion process that forms the
compounded plastic into the finished products (U.S. EPA, 2014; OECD, 2009). The converting process
is different depending on whether the plastic is a thermoplastic or a thermosetting material (OECD,
2009). Thermoplastics converting involves the melting of the plastic material, forming it into a new
shape and then cooling it (U.S. EPA, 2014; OECD, 2009). The converting of thermoplastics may
involve extrusion, injection molding, blow molding, rotational molding or thermoforming (U.S. EPA,
2014; OECD, 2009).
Conversion of thermosetting materials involves using heat and pressure to promote curing, typically
through cross-linking (OECD, 2009). The primary conversion process for thermosetting materials is
compression molding; however, fiber reinforced thermosetting plastics are converted using hand layup,
spray molding and filament winding (OECD, 2009). After the forming process, finishing operations
such as filing, grinding, sanding, polishing, painting, bonding, coating and engraving are performed to
complete the process (U.S. EPA, 2014).
K. 1.2.4 Repackaging
Typical repackaging sites receive the chemical in bulk containers and transfer the chemical from the
bulk container into another smaller container in preparation for distribution in commerce
K. 1.2.5 Recycling
Recovery and recycling of unreacted 1,3-butadiene from the various synthetic rubber manufacturing
operations is common. 1,3-Butadiene and other monomers (such as styrene) are recovered and reused in
rubber manufacturing to the extent possible (ECB, 2002).
E.1.3 Other Uses
Other Industrial Uses
Based on information identified in Use Report: 1,3-Butadiene, a variety of other industrial uses may exist
for may exist for chemicals, synthetic rubbers, and thermoplastics derived from 1,3-butadiene, including:
adhesives and sealants and laboratory chemicals. There are unconfirmed uses of 1,3-butadiene in fabric,
textile, and leather products. More information on these uses will be gathered through expanded
literature searches in subsequent phases of the risk evaluation process.
Other Commercial/Consumer Uses
Based on information identified in High Priority Chemical: Use Report: 1,3-Butadiene, a variety of
other commercial and consumer uses may exist for chemicals, synthetic rubbers, and thermoplastics
derived from 1,3-butadiene, including: paints and coatings, lubricants, and automotive care products.
79

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There are unconfirmed uses of 1,3-butadiene in propellants/blowing agents. Similar to the "Other"
industrial uses, more information on these uses will be gathered through expanded literature searches in
subsequent phases of the risk evaluation process.
E.1.4 Disposal
1,3-Butadiene is not listed as a hazardous waste under RCRA. Incineration is the recommended waste
management method for 1,3-butadiene (HSDB, 2009). TRI data indicate 1,3-butadiene may be land
disposed, deep well injected, or discharged to water following pretreatment (TRI, 2017).
E.2 Preliminary Occupational Exposure Data
EPA presents below an example of occupational exposure-related information obtained from
preliminary data gathering. EPA plans to consider this information and data in combination with other
data and methods for use in the risk evaluation.
Table Apx E-l summarizes NIOSH Health Hazard Evaluations identified during EPA's preliminary data
gathering.
Table Apx E-l. Summary of NIOSH HHEs with Monitoring for 1,3-Butadienea
Year of Publication
Ueporl Number
I'acilily Description
1990
HETA-90-198-L2060
Polymer manufacturing
1980
HE-80-188-797
Plastic products manufacturing
1980
HE-79-36-656
Plastic helmet manufacturing
1979
HE-78-110-585
Plastic aircraft parts manufacturing
1977
HE-77-1-426
Rubber manufacturing
1976
HE-74-120-260
Rubber tire manufacturing
1973
HE-72-86-38
Rubber hose manufacturing
a Table includes HHEs identified to date
Table Apx E-2 summarizes OSHA CEHD identified during EPA's preliminary data gathering.
Table Apx E-2. Summary of Industry Sectors with 1,3-Butadiene Monitoring Samples Available
from OSHA Inspections Conducted Between 2010 and 2019	
NAK'S
NAICS Description
Number of Data
Points
No NAICS code
reported

16
236220
Commercial and Institutional Building
Construction
2
324110
Petroleum Refineries
4
325212
Synthetic Rubber Manufacturing
1
80

-------
NAK'S
NAICS Description
Number of l);il;i
Points
326121
Unlaminated Plastics Profile Shape
Manufacturing
3
326122
Plastics Pipe and Pipe Fitting Manufacturing
1
326199
All Other Plastics Product Manufacturing
13
326212
Tire Retreading
14
326220
Rubber and Plastics Hoses and Belting
Manufacturing
15
326291
Rubber Product Manufacturing for Mechanical
Use
8
332323
Ornamental and Architectural Metal Work
Manufacturing
8
333220
Plastics and Rubber Industry Machinery
Manufacturing
4
337215
Showcase, Partition, Shelving, and Locker
Manufacturing
9
453998
All Other Miscellaneous Store Retailers (except
Tobacco Stores)
2
611310
Colleges, Universities, and Professional Schools
17
926150
Regulation, Licensing, and Inspection of
Miscellaneous Commercial Sectors
3

-------
Appendix F SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR INDUSTRIAL
AND COMMERCIAL ACTIVITIES AND USES
Table Apx F-
1. Worker and Occupational Non-User Exposure <
Conceptual
Model Supporting Table
l.ili-( >ik-
Slum-
(;ik-»iir\

Sii'iiiiriii
l".\|)OSlllV
Pill hw ;i\
I'ApilMIIV
Kuiik-
Ki-ivplur
I'hilis In
l".\ ill u iik-
Kiiliniiiilc




Liquid
Contact
Dermal
Worker
Ycs
1,3-Butadiene is expected
to be handle as liquid
under pressure8. EPA
plans to evaluate dermal
exposure.




Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation exposure.
Manufacturing
Domestic
manufacturin
g
Domestic
manufacturing
Manufacturing of
1,3-butadiene
Liquid
( oniacl
Dermal
<>\l
\o
Dermal e\posnre In OM
is noi e\|xvled lor ilns
coiidilion of use as ihe>
are noi e\|xvled lo
direclh handle llie
chemical.




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation exposure.




Mist
Dermal
Inhalation
Workers.
()\l
\o
Misi ueneralioii noi
e\pecled diirnm
maiiiiracliirniu.
8 EPA expects the process to be enclosed to avoid exposure to air that can cause formation of polymeric peroxides as well as based on its volatility (Sun, 2002; EPA,
1996), potential exposure to workers from loading and sampling activities could occur. However, review of preliminary data sources suggest exposure by dermal contact
may be limited for these processes, information collected through systematic review methods and public comments will help inform this exposure pathway.
82

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l.ik-( \ik-
Slum-

Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
Ki-ivplnr
I'hilis In
l".\ ill 11 ilk'
Kiilioiiiilc




Liquid
Contact
Dermal
Worker
Yes
Dermal exposure may
occur if there is
repackaging. EPA plans
to evaluate dermal
exposure.




Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation exposure.
Manufacturing
Importing
Importing
Repackaging of
import containers
l.l(|llld
( miiacl
Dermal
()\l
\o
Dermal e\posiire In ()\l
is imi e\pecled fur llns
condition of use as ihe>
are noi e\pecled in
direclh handle llie
chemical




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation route.




\lls|
Dermal
Inhalation
Workers.
()\l
\o
Misi uciieralion nol
e\pecled durum impori
83

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ ;il u iik-
Kiilioiiiilc
Processing
Processing as
a reactant
Intermediate in:
Adhesive
manufacturing; All
other basic organic
chemical
manufacturing;
Organic fiber
manufacturing;
Petrochemical
manufacturing;
Petroleum refineries;
Plastic material and
resin manufacturing;
Synthetic rubber
manufacturing;
Wholesale and retail
trade; Other:
Monomer used in
polymerization
process in: Plastic
material and resin
manufacturing;
Manufacturing
synthetic rubber and
plastics;
Plasticizers in: Plastic
material and resin
manufacturing;
Solvents (which
become part of
product formulation
or mixture) in:
Synthetic rubber
manufacturing;
Other: Fuel binder for
Processing of 1,3-
butadiene as a
reactant or
monomer
(polymerization)
Liquid
Contact
Dermal
Worker
Ycs
Workers may have dermal
exposure during
unloading and sampling,
EPA plans to evaluate
dermal pathway.


Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.



l.u|iiid
( niilacl
Dermal
()\l
\n
Dermal e\pnMiiv h> ()M
is uni e\pecled I'm' ilns
coiidilKiii ill' use as ihc>
are noi c\|xvlcd In
tliivvllv handle I lie
chemical.
84

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ ill 11 ilk'
Kiilioiiiilc


solid rocket fuels in:
Aerospace

Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
\1isi
Dermal
Inhalation
Workers.
<)\l
\o
\lisi ueueraliou nui
e\pecled durum
processum as a rcaclanl
Processing
Processing -
incorporation
into
formulation,
mixture, or
reaction
product
Processing aids, not
otherwise listed in:
Petrochemical
manufacturing;
Processing aids, not
otherwise listed in:
Adhesive
manufacturing, paints
and coatings
manufacturing,
petroleum lubricating
oil and grease
manufacturing, and
all other chemical
product and
preparation
manufacturing
Processing into
formulations,
mixtures, or
reaction product
Liquid
Contact
Dermal
Worker
Yes
Dermal exposure to
liquids containing 1,3-
butadiene may occur for
this exposure scenario.
EPA plans to evaluate
dermal pathway
Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation route.
Liquid
( oniacl
Dermal
()\l
\o
Dermal exposure h> < )M
is mki e\peeled lor ilns
eoiidilion ill' use as ihe>
are noi e\pecled in
direclls handle llie
chemical
Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation route.
85

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ il III illl'
Kiilioiiiilc




\lls|
Dermal
Inhalation
Workers.
()\l
\o
\1isi ueneralion noi
e\pecled dnriim
processiim I'orniiilalioii
ope nil Kins




Liquid
Contact
Dermal
Worker
Yes
Dermal exposure to
liquids containing 1,3-
butadiene may occur for
this exposure scenario.
EPA plans to evaluate
dermal pathway




Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation route.
Processing
Processing -
incorporation
into article
Other: Polymer in:
Rubber product
manufacturing
Plastics and
Rubber product
manufacturing
Liquid
( oniacl
Dermal
<>\l
\o
Dermal e\posnre h\ OM
is noi e\pecled lor ilns
condition of use as ihe>
are not c\pecled lo
direclh handle llie
chemical




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation route.




\lls|
Dermal
Inhalation
Workers.
()\l
\o
Misi ueiieralioii noi
e\pecled durum
processnm operations
Processing
Repackaging
Intermediate in:
Wholesale and retail
trade
Repackaging
(same exposure scenario
as Import)
Liquid
Contact
Dermal
Worker
Yes
Dermal exposure may
occur if there is
repackaging. EPA plans
to evaluate dermal
exposure.
86

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
I'iilllWiiv
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ ill u iik-
Rationale




Vapor
Inhalation
Worker
Ycs
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation route




Liquid
( ouiacl
Dermal
<>\l
\o
Dermal e\posure In ()\l
is noi e\pecled lor this
condition of use as ihe>
are uoi e\|xvled lo
direclls handle llie
chemical.




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.




\lls|
Dermal
Inhalation
Workers.
()\l
No
Misi ueueraliou uoi
e\pecled durum
repackauum
Distribution in
commerce
Distribution i
n commerce
Distribution in
commerce
Distribution
Liquid
Contact,
Vapor
Dermal/
Inhalation
Worker,
ONU
Yes
EPA plans to analyze
activities resulting in
exposures associated with
distribution in commerce
(e.g. loading, unloading)
throughout the various
lifecycle stages and
conditions of use (e.g.
manufacturing,
processing, industrial use)
rather than as a single
distribution scenario.




Liquid
Contact
Dermal
Worker
Yes
Dermal exposure may
occur for this condition of
use, EPA plans to
evaluate dermal exposure
Processing
Recycling
Recycling
Recycling of 1,3-
butadiene
Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway




Liquid
( ouiacl
Dermal
<>\l
\o
Dermal exposure h\ ()M
is uoi e\peeled lor iliis
condition ol' use as ihe\
87

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
Ki-ivplnr
I'hilis In
l".\ ill u iik-
Kiilioiiiilc








are noi e\pecled lo








direclK handle llie








chemical








1,3-Butadiene is \olalile




Vapor
Inhalation
ONU
Ycs
at room temperature, EPA
plans to evaluate the
inhalation palhuas





Dermal
Inhalation
Workers.
()\l

Mm ueiieralioii noi




\lls|
No
e\pecled durum
processiim rec\clnm








Dermal exposure to




Liquid
Contact
Dermal
Worker
Yes
liquids containing 1,3-
butadiene may occur for
this exposure scenario.
EPA plans to evaluate
dermal exposure








1,3-Butadiene is volatile




Vapor
Inhalation
Worker
Yes
at room temperature, EPA
plans to evaluate the

Processing
aids, specific
to petroleum
production

Use of 1,3-
butadiene in
hydraulic
fracturing




inhalation exposure.
Industrial Uses
Hydraulic fracturing
Liquid
( oniacl
Dermal
<>\l
\o
Dermal e\posuic In OM
is noi e\pecled lor iliis
condilion of use as ihe>
are noi e\pecled lo
direclK handle llie
chemical.








1,3-Butadiene is volatile




Vapor
Inhalation
ONU
Yes
at room temperature, EPA
plans to evaluate the
inhalation pathway.





Dermal
Inhalation
Workers.
()\l

Mm ueiieralioii noi




\lls|
No
e\pecled durum






processiim rec\clnm
Industrial
/Commercial
Uses
Adhesives
Adhesives and
Use of rubber
adhesives and
sealants
Liquid
Contact
Dermal
Worker
Yes
Dermal exposure may
occur for this condition of
use. EPA plans to
evaluate dermal exposure.
and sealants
sealants
Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
88

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l';illl\\;i\
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ il III illl'
Kiilioiiiilc




Liquid
(onlacl
Dermal
()\l
\o
Dermal c\posnre In ()\l
is iioi e\pecled lor this
coiidilion of use as lhe>
are noi e\pecled In
direclk handle llie
chemical




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is \olalile
at room temperature, EPA
plans to evaluate the
inhalation pathway.




Mist
Dermal/
Inhalation
Workers
Yes
EPA plans to evaluate
mist generation for this
scenario.




Mist
Inhalation
ONU
Yes
EPA plans to evaluate
mist generation for this
scenario.




\1is|
Dermal
()\l
\o
Dermal e\posure In OM
is inn e\pecled fur ilns
condition of use as ihe>
are noi c\pecled Id
direclh handle llie
chemical




Liquid
Contact
Dermal
Workers
Yes
Dermal exposure may
occur for this condition of
use, EPA plans to
evaluate dermal exposure
Commercial
Uses
Fuel and
Related
Products
Fuel and Related
Products
Use of fuel and
fuel related
products
Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.



Liquid
( onlacl
Dermal
<>\l
\o
Dermal e\posure In OM
is noi e\pecled lor ilns
condition of use as ihe>
are noi e\pecled lo
direclh handle llie
chemical
89

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
Ki-ivplnr
I'hilis In
l".\ ill 11 illl'
Kiilioiiiilc




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
Commercial
Uses
Plastic and
rubber
products not
covered
elsewhere;
Plastic and rubber
products not covered
elsewhere, including
rubber tires;
Use of finished
plastic and rubber
products not
covered elsewhere
(e.g. tires)
Liquid
Contact
Dermal
Worker.
<)\l s
\o
I'rodncls co\ ered under
lliis e\posnre scenario are
expected lo he solid
articles u here dermal
exposure to 1. Mnitadiene
is not expected
Vapor
Inhalation
Worker
Yes
1,3-Liuladiene is \ olalile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
\lisi
Dermal
Inhalation
Workers.
()\l
\o
Mist ueiieratioii not
expected durum plastic
and rubber products
niaiiiil'acliiriim
Commercial
Uses
Automotive
care products;
Lubricant and
lubricant
additives
Automotive care
products;
Lubricants additive
Use of other
products developed
from butadiene-
based polymers
Liquid
Dermal
Worker
Yes
Dermal exposure nun
occur for this condition of
use, EPA plans to
evaluate dermal exposure
Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathwas
Liquid
Contact
Dermal
()\l
\o
Dermal e\posnre h\ OM
is not e\pected lor this
condition of use as the>
are not e\pected lo
dircclK handle the
chemical.
Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
\lls|
Dermal
Inhalation
Workers.
()\l
\o
Mist ueiieration not
e\pected diirnm plastic
90

-------
l.ik-( \ik-
Slum-

Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l';illl\\;i\
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ ill 11 illl'
Kiilioiiiilc








and rubber prnducls
il i;i i ill l;icl 11 l'i i iu




Liquid
Contact
Dermal
Worker
Yes
Dermal exposure may
occur for this condition of
use, EPA plans to
evaluate dermal exposure




Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.



Spray coating
Liquid
( nniacl
Dermal
<>\l
\n
Dermal e\pnsure In OM
is unl e\pecled I'm' llns
condition of use as ihe>
are nul e\pecled Id
direclK handle llie
chemical.
Commercial
Uses
Paints and
Coatings
Paints and Coatings
application; and
Other paint and
coating
Vapor
Inhalation
ONU
Yes
1,3-Butadiene is \ olalile
at room temperature, EPA
plans to evaluate the
inhalation pathway.



applications (e.g.,
roll, dip)
Mist
Dermal/
Inhalation
Workers
Yes
EPA plans to evaluate
mist generation for this
scenario.




\lls|
Dermal
()\l
\n
Dermal e\pnsiire h\ < )\l
is mki expected I'nr llns
coiidilion ol' use as ihe>
are nol e\pecled in
direclls handle llie
chemical




Mist
Inhalation
ONU
Yes
EPA plans to evaluate
mist generation for this
scenario.
Commercial
Uses
Other Use
Laboratory
chemicals;
Laboratory Use
Liquid
Contact
Dermal
Workers
Yes
Dermal exposure may
occur for this condition of
use, EPA plans to
evaluate dermal exposure
91

-------
l.ik-( \ik-
Slum-
C;ik-»iir\
Sul)i:ili-»or\
Sii'iiiiriii
l".\|)OSlllV
l>;illl\\;i\
l".\|)OSlllV
Rullk-
ki-ivplor
I'hilis In
l".\ ill u iik-
Kiilioiiiilc




Vapor
Inhalation
Workers
Ycs
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway




Liquid
( oniacl
Dermal
()\l
\o
Dermal e\posnre h> ()\l
is noi e\pecled lor ilns
condition of use as thc>
are not c\pcclcd lo
dircclK handle llie
chemical.




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway




\lls|
Dermal
Inhalation
Workers.
<>\l
\o
Misi ueneralion noi
c\pcclcd lioni wasie
haiidhnu




Liquid
Contact
Dermal
Worker
Yes
Dermal exposure is
expected for this
condition of use

Waste
Handling,
Treatment
and Disposal
Disposal of 1,3-
butadiene wastes
Worker handling of
wastes
Vapor
Inhalation
Worker
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
Disposal
Liquid
( oniacl
Dermal
()\l
\o
Dermal e\posnre In OM
is noi c\pcclcd lor ilns
condition of use as ihe>
are noi c\pcclcd lo
dircclK handle llie
chemical




Vapor
Inhalation
ONU
Yes
1,3-Butadiene is volatile
at room temperature, EPA
plans to evaluate the
inhalation pathway.
92

-------
l.ik-( \ik-
C;ik-»iir\
Sul)i:ili-»or\
ki-li-;isi-/l".\|)osiiiv
Sii'iiiiriii
l".\|)OSlllV
l".\|)OSlllV
Rullk-
Ki-ivplnr
I'hilis In
l".\ il III ilk'
Kiilioiiiilc




\lls|
Dcnniil
Wol'ka's.
()\l
\n
\1ls| UCIICnilKill IK
-------
Appendix G SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR CONSUMER
ACTIVITIES AND USES
Table Apx G-l. Consumer Exposure Conceptual Model Supporting Table
l .ile ( >cle
S(;i»e

Siibciik'jion
Ki'k'.isi* from
SOIIIVO
l'l\|)OSIIIV
Kniili'
Km'plor
Pliiiis In
l'.\ illllilH*
K;ilinn;ik'
Consumer
Automotive Care
Automotive Care
Direct contact
through
application or
use of products
using butadiene-
based polymers
Liquid
Contact
Dermal
Consumers
Yes
Dermal exposure may occur for this
condition of use. EPA plans to evaluate
dermal exposure.
Use
Products
Products
Long-term
emission/mass-
transfer through
application or
use of products
using butadiene-
based polymers
Vapor
Inhalation
Consumers
and
Bystanders
Yes
1,3-Butadiene is volatile at room
temperature, EPA plans to evaluate the
inhalation pathway.
Consumer
Use
Plastic and
Rubber Products
Plastic and
rubber products
not covered
elsewhere,
including rubber
tires
Direct contact
through
application or
use of products
using butadiene-
based polymers
Liquid
Contact
Dermal
Consumers
Yes
Dermal exposure may occur for this
condition of use. EPA plans to evaluate
dermal exposure.
Long-term
emission/mass-
transfer through
application or
use of products
using butadiene-
based polymers
Vapor
Inhalation
Consumers
and
Bystanders
Yes
1,3-Butadiene is volatile at room
temperature, EPA plans to evaluate the
inhalation pathway.
94

-------
l.il'c ( \clc
Si;i»o

Suhciik'iion
Kck'sisi* from
SOIIIVC
Mxposuiv
Kniilc
Km'plnr
I'lilllS lo
Kiilioiiiilo
Consumer
Handling of
Disposal and
Waste


Direct contact
through
application or
use of products
using butadiene-
based polymers
Liquid
Contact
Dermal
Consumers
Yes
Dermal exposure may occur for this
condition of use, dermal exposure will
be further analyzed.
Wastewater,
Liquid wastes
and solid wastes
Wastewater,
Liquid wastes
and solid wastes
Long-term
emission/mass-
transfer through
application or
use of products
using butadiene-
based polymers
Vapor
Inhalation
Consumers
and
Bystanders
Yes
1,3-Butadiene is volatile at room
temperature, EPA plans to evaluate the
inhalation pathway.
95

-------
Appendix H SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR
ENVIRONMENTAL RELEASES AND WASTES
Table Apx H-l. General Population and Environmental Exposure Conceptual Model Supporting Table
Life
( >clo
Slsijic
C.iU'Korics
Kok'iisc
l'l\|)OMIIV
Pillh\\ ;¦> /
Media
I'1\|)umiiv Koiiles
Keeeplor/
Population
I'liins lo
KMilualo''
Kiilioiiiilo
\ll
1 Emissions lo \ 11"
1 Emissions lo \11"
Near I'aeilils
anihieui air
concent nil ions
1111 in la 1 iii 11
(leneral
l\ipiilaliiiii
VI
1. '-I iiiladiene is a 11 \P
lieeause sialiniiar\ snnree
releases nl' 1. ^-huiadieiie in
amhieiil air are under ilie
jurisdiction ol I lie ( \ \
11 id i reel
depusiiiiin lo
uearln bodies of
\x;iler'and mhI
ealelimeiils
()ral. Dermal
(leneral
l\ipiilaliiiii
VI
Tl'.l)
\i|iialie and
1 erresinal
Receptors
VI
Wastewater or Liquid
Wastes
Industrial pre-
treatment and
wastewater treatment,
orPOTW
Direct release
into surface
water and
indirect
partitioning to
sediment
TBD
Aquatic and
Terrestrial
Receptors
Yes
This chemical may be
released to surface water
9 The exposure pathways, exposure routes and hazards plans to evaluate are subject to change in the final scope, in light of comments received on this draft scope and
other reasonably available information. EPA continues to consider whether and how other EPA-administered statutes and any associated regulatory programs address the
presence of 1,3-butadiene in exposure pathways falling under the jurisdiction of these EPA statutes.
96

-------
Life
( \ck
Slsijic
( ;i(OK»tries
Kok'iisc
l'l\|)OMIIV
Pillh\\ ;¦> /
Modiii
r.\|)(isurc Ronlos
Km'plor/
Population
PlilllS lo
K\;ilii;ik'''
Kiilioiiiilo



Direct release







into surface







water and







partitioning to
sediment and
bioaccumulation
Oral
Inhalation
General
Population
Yes




into edible







aquatic species







Drinking Water
via Surface or
Ground Water
Oral
Dermal and
Inhalation (e.g.
showering)
General
Population
No
The drinking water
exposure pathway for 1.3-
buladicne is currently
addressed in the SDWA
regulatory analytical
process for public water
svstcms.



Biosolids:
application to
soil and/or
migration to
groundwater
and/or surface
water
Oral (e.g. ingestion
of soil)
Inhalation
General
Population
Yes
Although 1,3-butadiene is a
volatile chemical and not
expected to sorb onto
biosolids, EPA plans to



TBD
Terrestrial
receptors
Yes
analyze this pathway.
However, it is expected to
be a minor pathway of
exposure to the general
population and terrestrial
species.



Mmialiiiii lo
Oral
Dermal
(icncral
Kipiilalkin
VI



Underground
injection
ummiduakT.
Inhalalioii

1.'-liiilailieiie is released in


pole i il i;i 1
surface driiikiim
\x;iler
1131)
\qnalic and
Terrestrial
kecepinrs
\n
( lass 1 I iiderui'iiimd
liiieclkiii Wells

Solid and Liquid
Wastes
Municipal landfill
and other land
disposal
Leachate to soil,
ground water
and/or
Oral (e.g., ingestion)
Dermal
Inhalation
General
Population
Yes
Based, on TRI data, this
chemical is expected to be
97

-------
Life
( \ck
Slsijic
( ;i(OK»tries
Kok'iisc
I'1\|)osiiiv
P;il h \\ ;¦> /
Modiii
I'1\|)umiiv Koiiles
Km'plor/
Population
I'liins lo
Kiilioiiiilo



mitigation to
surface water
TBD
Aquatic and
Terrestrial
Receptors
Yes
released to municipal
landfills.
98

-------