EPA Document# EPA-740-D-20-007
April 2020
FPA United Statcs Office of Chemical Safety and
!¦¦¦ Environmental Protection Agency Pollution Prevention
Draft Scope of the Risk Evaluation for
fraws-l,2-Dichloroethylene
CASRN 156-60-5
April 2020
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TABLE OF CONTENTS
ACKNOWLEDGEMENTS 6
ABBREVIATIONS AND ACRONYMS 7
EXECUTIVE SUMMARY 10
1 INTRODUCTION 13
2 SCOPE OF THE EVALUATION 13
2.1 Reasonably Available Information 13
2.1.1 Search of Gray Literature 14
2.1.2 Search of Literature from Publicly Available Databases (Peer-reviewed Literature) 14
2.1.3 Search of TSCA Submissions 19
2.2 Conditions of Use 20
2.2.1 Categories and Subcategories of Conditions of Use Included in the Scope of the Risk
Evaluation 20
2.2.2 Activities Excluded from the Scope of the Risk Evaluation 24
2.2.3 Production Volume 24
2.2.4 Overview of Conditions of Use and Lifecycle Diagram 24
2.3 Exposures 26
2.3.1 Physical and Chemical Properties 26
2.3.2 Environmental Fate and Transport 26
2.3.3 Releases to the Environment 26
2.3.4 Environmental Exposures 28
2.3.5 Occupational Exposures 28
2.3.6 Consumer Exposures 29
2.3.7 General Population Exposures 29
2.4 Hazards (Effects) 30
2.4.1 Environmental Hazards 30
2.4.2 Human Health Hazards 30
2.5 Potentially Exposed or Susceptible Subpopulations 30
2.6 C onceptual Model s 31
2.6.1 Conceptual Model for Industrial and Commercial Activities and Uses 31
2.6.2 Conceptual Model for Consumer Activities and Uses 33
2.6.3 Conceptual Model for Environmental Releases and Wastes: Potential Exposures and
Hazards (Regulatory Overlay) 35
2.6.3.1 Drinking Water Pathway 37
2.6.3.2 Ambient Water Pathway 37
2.6.3.3 Disposal and Soil Pathways 37
2.6.4 Conceptual Model for Environmental Releases and Wastes: Potential Exposures and
Hazards 39
2.7 Analysis Plan 41
2.7.1 Physical and Chemical Properties and Environmental Fate 41
2.7.2 Exposure 42
2.7.2.1 Environmental Releases 42
2.7.2.2 Environmental Exposures 44
2.7.2.3 Occupational Exposures 45
2.7.2.4 Consumer Exposures 46
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2.7.2.5 General Population 48
2.7.3 Hazards (Effects) 50
2.7.3.1 Environmental Hazards 50
2.7.3.2 Human Health Hazards 51
2.7.4 Summary of Risk Approaches for Characterization 53
2.8 Peer Review 54
REFERENCES 55
APPENDICES 62
Appendix A LIST OF GRAY LITERATURE SOURCES 62
Appendix B PHYSICAL AND CHEMICAL PROPERTIES OF trans-1,2-
DICHLOROETHYLENE 66
Appendix C ENVIRONMENTAL FATE AND TRANSPORT PROPERTIES OF trans-1,2-
DICHLOROETHYLENE 68
Appendix D REGULATORY HISTORY 70
D.l Federal Laws and Regulations 70
D.2 State Laws and Regulations .76
D.3 International Laws and Regulations .77
Appendix E PROCESS, RELEASE AND OCCUPATIONAL EXPOSURE INFORMATION.. 78
E.l Process Information................ ......78
E. 1.1.1 Manufacture 78
E.l. 1.2 Import 78
E. 1.2 Processing and Distribution 78
E. 1.2.1 Processing as a Reactant or Intermediate 78
E. 1.2.2 Incorporation into Formulation, Mixture, or Reaction Product 78
E. 1.2.3 Incorporation into Articles 79
E.l.3 Uses 79
E.l.3.1 Batch Open-Top Vapor Degreasing 79
E.l.3.2 Batch Closed-Top Vapor Degreasing 80
E.l.3.3 Aerosol Degreasing 81
E. 1.3.4 Industrial and Commercial Cleaning and Furniture Care Products 82
E.l.3.5 Anti-Adhesive Agent 82
E.l.3.6 Lubricants and Greases 82
E.l.3.7 Adhesives and Sealants 82
E. 1.3.8 Refrigerant and Refrigeration System Flush 82
E.l.3.9 Processing Aids 83
E.l.3.10 Propellants and Blowing Agents 83
E.l.3.11 Laboratory Use 83
E.l.4 Disposal 83
E.2 Sources Containing Potentially Relevant Data or Information 84
Appendix F SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR INDUSTRIAL
AND COMMERCIAL ACTIVITIES AND USES 85
Appendix G SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR CONSUMER
ACTIVITIES AND USES 95
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Appendix II SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR
ENVIRONMENTAL RELEASES AND WASTES 96
LIST OF TABLES
Table 2-1. Results of Title Screening of Submissions to EPA under Various Sections of TSCAa 20
Table 2-2. Conditions of Use Included in the Scope of the Risk Evaluation 20
Table 2-3. Summary of 1,2-Dichloroethylene Production-Related Waste Managed in 2018 27
Table 2-4. Summary of Releases of 1,2-Dichloroethylene to the Environment During 2018 27
Table 2-5. Categories and Sources of Environmental Release Data 42
Table 2-6. Potential Sources of Occupational Exposure Data 45
LIST OF FIGURES
Figure 2-1. Gray Literature Tags by Discipline for trans- 1,2-Dichloroethylene 14
Figure 2-2. Peer-Reviewed Literature - Physical-Chemical Properties Search Results for trans- 1,2-
Dichloroethylene 15
Figure 2-3. Peer-Reviewed Literature - Fate and Transport Search Results for trans- 1,2-
Dichloroethylene 16
Figure 2-4. Peer-Reviewed Literature - Engineering Search Results for trans- 1,2-Dichloroethylene 17
Figure 2-5. Peer-Reviewed Literature - Exposure Search Results for trans- 1,2-Dichloroethylene 18
Figure 2-6. Peer-Reviewed Literature - Hazard Search Results for trans- 1,2-Dichloroethylene 19
Figure 2-7. trans- 1,2-Dichloroethylene Life Cycle Diagram 25
Figure 2-8. trans- 1,2-Dichloroethylene Occupational Exposure Conceptual Model for Industrial and
Commercial Activities and Uses: Worker and Occupational Non-User Exposures and
Hazards 32
Figure 2-9. trans- 1,2-Dichloroethylene Conceptual Model for Consumer Activities and Uses: Consumer
Exposures and Hazards 34
Figure 2-10. trans- 1,2-Dichloroethylene Conceptual Model for Environmental Releases and Wastes:
Environmental and General Population Exposures and Hazards (Regulatory Overlay) ..36
Figure 2-11. trans- 1,2-Dichloroethylene Conceptual Model for Environmental Releases and Wastes:
Environmental and General Population Exposures and Hazards 40
LIST OF APPENDIX TABLES
Table_Apx A-l. Gray Literature Sources for trans- 1,2-Dichloroethylene 62
TableApx C-l. Environmental Fate Properties of trans- 1,2-Dichloroethylene 68
Table_Apx D-l. Federal Laws and Regulations 70
Table_Apx D-2. State Laws and Regulations 76
Table Apx D-3. Regulatory Actions by other Governments, Tribes, and International Agreements 77
Table Apx F-l. Worker and Occupational Non-User Exposure Conceptual Model Supporting Table. 85
Table Apx G-l. Consumer Exposure Conceptual Model Supporting Table 95
Table Apx H-l. General Population and Environmental Exposure Conceptual Model Supporting Table
96
LIST OF APPENDIX FIGURES
Figure_Apx E-l. Open Top Vapor Degreaser 79
Figure_Apx E-2. Open Top Vapor Degreaser with Enclosure 80
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Figure_Apx E-3. Closed-Loop/Vacuum Vapor Degreaser 81
Figure_Apx E-4. Overview of Aerosol degreasing 82
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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 Abt Associates (Contract No. EP-W-16-009),
ERG (Contract No. EP-W-12-006), GDIT (Contract No. HHSN316201200013W), ICF (Contract
No.68HERC19D0003), SRC (Contract No. 68HERH19F0213), and Versar (Contract No. EP-W-17-
006). 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: J Q-QPPT-2018-0465.
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
ACGIH
ACS
ADME
AIA
AT SDR
AWQC
BAF
BCF
BMF
BOD
BP
BW34
CAA
CalEPA
CASRN
CBI
CDC
CDR
CEHD
CEM
CERCLA
CFC-113
CFCs
CFR
ChemSTEER
CHRIP
COC
CPCat
CPDat
CRC
CSCL
CWA
DCE
DMR
EC
ECHA
EPA
EPCRA
EPI
ERG
ESD
EU
FR
FYI
GDIT
American Conference of Governmental Industrial Hygienists
American Chemical Society
Absorption, Distribution, Metabolism, and Excretion
Aerospace Industries Association
Agency for Toxic Substances and Disease Registry
Ambient Water Quality Criteria
Bioaccumulation Factor
Bioconcentration Factor
Biomagnification factor
Biochemical Oxygen Demand
Boiling Point
Body Weight 3/4 Extrapolation
Clean Air Act
California Environmental Protection Agency
Chemical Abstracts Service Registry Number
Confidential Business Information
Centers for Diseases Control and Prevention
Chemical Data Reporting
Chemical Exposure Health Data
Consumer Exposure Model
Comprehensive Environmental Response, Compensation and Liability Act
1,1,2-Trichloro-1,2,2-trifluoroethane
Chi orofluorocarb ons
Code of Federal Regulations
Chemical Screening Tool for Occupational Exposures and Releases
Chemical Risk Information Platform
Concentration of Concern
Chemical and Product Categories
Consumer Product Database
Coordinating Research Council
Chemical Substances Control Law
Clean Water Act
1,2-Dichloroethylene
Discharge Monitoring Report
Engineering Control(s)
European Chemicals Agency
Environmental Protection Agency
Emergency Planning and Community Right-to-Know Act
Estimation Programs Interface
Eastern Research Group
Emission Scenario Document
European Union
Federal Register
For your information
General Dynamics Information Technology
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GESTIS
Substance Database contains information for the safe handling of hazardous substances
and other chemical substances at work
GS
Generic Scenario
HCFCs
Hydrochlorofluorocarbons
HERO
Health and Environmental Research Online
HFO
Hydrofluoroolefins
HHE
Health Hazard Evaluation
HMTA
Federal Hazardous Materials Transportation Act
HSDB
Hazardous Substances Data Bank
IBCs
Intermediate Bulk Containers
ICF
ICF is a global consulting services company
ICH
International Council for Harmonisation
IMAP
Inventory Multi-Tiered Assessment and Prioritisation (Australia)
IRIS
Integrated Risk Information System
ISHA
Industrial Safety and Health Act
IUPAC
International Union of Pure and Applied Chemistry
Koc
Organic Carbon: Water Partition Coefficient
Kow
Octanol: Water Partition Coefficient
KOECT
Kirk-Othmer Encyclopedia of Chemical Technology
LCso
50% Lethal Concentration
LCx
Lethal Concentration
LOAELs
Lowest Observed Adverse Effect Level
LOEC
Lowest Observed Effect Concentration
MACT
Maximum Achievable Control Technology
MCL
Maximum Contaminant Level
MCLG
Maximum Contaminant Level Goal
MITI
Ministry of International Trade and Industry
MOA
Mode of Action
MP
Melting Point
MSW
Municipal Solid Waste
NEI
National Emissions Inventory
NEWMOA
Northeast Waste Management Officials' Association
NHANES
National Health and Nutrition Examination Survey
NICNAS
National Industrial Chemicals Notification and Assessment Scheme (Australia)
NIOSH
National Institute for Occupational Safety and Health
NIST
National Institute of Standards and Technology
NITE
National Institute of Technology and Evaluation
NLM
National Library of Medicine
NOAELs
No Observed Adverse Effect Level
NOEC
No Observed Effect Concentration
NPDES
National Pollutant Discharge Elimination System
NPDWR
National Primary Drinking Water Regulation
NPL
National Priorities List
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)
OELs
Occupational Exposure Limits
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ONU
Occupational Non-User
OPPT
Office of Pollution Prevention and Toxics
OSHA
Occupational Safety and Health Administration
OTVDs
Open Top Vapor Degreasers
OW
EPA's Office of Water
P-chem
Phy si cal -chemi cal
PBPK
Physiologically Based Pharmacokinetic
PBT
Persistent Bioaccumulation, and Toxic
PECO
Population, Exposure, Comparator, Outcome
PEL
Permissible Exposure Limit
PESS
Potentially Exposed or Susceptible Subpopulation
PODs
Points of Departure
POTW
Publicly Owned Treatment Works
PPE
Personal Protective Equipment
QC
Quality Control
RCRA
Resource Conservation and Recovery Act
REACH
Registration, Evaluation, Authorisation and Restriction of Chemicals (European Union)
REL
Recommended Exposure Limit
RIVM
Dutch National Institute for Public Health and the Environment
RQs
Risk Quotients
SARA
Superfund Amendments and Reauthorization Act
SDS
Safety Data Sheet
SDWA
Safe Drinking Water Act
SNAP
Significant New Alternatives Policy
SRC
SRC Inc., formerly Syracuse Research Corporation
STORET
Storage and Retrieval for Water Quality Data; EPA's repository of water quality
monitoring data
TBD
To be determined
TCCR
Transparent, Clear, Consistent and Reasonable
TDCE
trans-1,2-Di chloroethy 1 ene
TERA
Toxicology Excellence for Risk Assessment
TIAB
Title and Abstract
TK
Toxicokinetics
TLV
Threshold Limit Value
TMF
Trophic Magnification Factors
TRI
Toxics Release Inventory
TSCA
Toxic Substances Control Act
TTO
Total Toxic Organics
TURA
Toxic Use Reduction Act
TWA
Time-weighted average
UCMR
Unregulated Contaminants Monitoring Rule
UIC
Underground Injection Control
USGS
United States Geological Survey
VP
Vapor Pressure
WHO
World Health Organization
WQX
Water Quality Exchange
WS
Water Solubility
WWT
Wastewater Treatment
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EXECUTIVE SUMMARY
In December 2019, EPA designated trans-1,2-dichloroethy 1 ene (CASRN 156-60-5) as a high priority
substance for risk evaluation following the prioritization process as required by section 6(b) of the Toxic
Substances Control Act (TSCA) and implementing regulations (40 CFR Part 702) (Docket ID: EPA-
HQ-OPPT-2018-0465). 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 Part 702.41(c)(7). The draft scope for ^raws-l,2-dichloroethylene includes the
following information: the conditions of use, potentially exposed or susceptible subpopulations (PESS)
that EPA plans to consider in this risk evaluation, along with a description of the reasonably available
information, hazards, exposures, conceptual models, 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. trans-\, 2-Dichloroethylene (CASRN 156-60-5) is a highly flammable, colorless
liquid with a sharp, harsh odor. It is a synthetic chemical with no known natural sources, and it is used to
produce solvents and in chemical mixtures, trans-l,2-Dichloroethylene is a highly water-soluble,
volatile liquid. It is not expected to hydrolyze. Its Henry's law constant and vapor pressure indicate that
it will tend to volatilize rather than persist in surface water or soil, trans-l,2-Dichloroethylene is not
expected to persist in air due to reactions with photochemically produced hydroxyl radicals, nitrate
radicals, and ozone. It is not readily biodegradable in aerobic aquatic environments and is expected to
persist in anaerobic environments such as subsurface, groundwater, or enclosed pipes where
volatilization is inhibited. It has low potential to bioaccumulate.
Reasonably Available Information. EPA leveraged the data and information sources already described
in the document supporting the High-Priority Substance designation for trans-1, 2-dichloroethylene 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 to date
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 is applying
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 trans-1, 2-
dichloroethylene.
Conditions of Use. EPA plans to evaluate manufacturing, including importing; processing; distribution
in commerce; industrial, commercial and consumer uses; and disposal of trans-1, 2-dichloroethylene in
the risk evaluation, trans-1, 2-dichloroethylene 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
products, and incorporated into articles. The identified processing activities also include the repackaging
and recycling of trans-1, 2-dichloroethylene. Several industrial and commercial uses were identified that
ranged from use as solvent for cleaning and degreasing to use as a component in a refrigerant blend.
Only one consumer use was reported, for use in aerosol degreasers. EPA identified these conditions of
use from information reported to EPA through Chemical Data Reporting (CDR) and Toxics Release
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Inventory (TRI) reporting, published literature, and consultation with stakeholders both for uses
currently in production and uses whose production may have ceased. Section 2.2.1 provides details
about the conditions of use within the scope of the risk evaluation.
Conceptual Models. The conceptual models for trans-1, 2-dichloroethylene 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 trans-1,2-
dichloroethylene 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 trans-l,2-dichloroethylene that
EPA plans to consider in risk evaluation. Exposures for trans-l,2-dichloroethylene are discussed
in Section 2.3. trans-1,2-Dichloroethylene is subject to reporting to TRI program and EPA
anticipates using TRI information as reasonably available information to inform trans-1,2-
dichloroethylene's environmental release assessment. For the 2018 reporting year, 18 facilities
reported to EPA releases of trans-l,2-dichloroethylene to air and via land disposal. Additional
information obtained through the results of systematic review searches will also inform expected
exposures.
EPA's plan as to environmental exposure pathways in the draft scope document considers
whether and how other EPA-administered statutes and regulatory programs address the presence
of trans-l, 2-dichloroethylene 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
exposures (pathways and routes), receptors and hazards associated with the conditions of use of
trans-l,2-dichloroethylene 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 exposure pathways associated with industrial and commercial conditions
of use: For industrial and commercial uses of trans-l, 2-dichloroethylene, EPA expects to
analyze exposure to liquids for workers via the dermal route. In addition, EPA expects to
analyze exposure to vapor and/or mist for workers and occupational non-users via the
inhalation route.
- Consumer and bystander exposure pathways associated with consumer conditions of use:
EPA plans to evaluate the inhalation and dermal exposure to trans-l,2-dichloroethylene
when consumers are handling cleaning and degreasing products.
General population pathways: EPA plans to evaluate exposure to trans-l,2-
dichloroethylene via groundwater, and ambient air for the general population.
Environmental exposures: EPA plans to evaluate exposure to trans-l,2-dichloroethylene
for aquatic and terrestrial receptors.
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- Receptors andPESS: EPA plans to evaluate children, women of reproductive age
(including, but not limited to, pregnant women), workers, and occupational non-users and
consumers as receptors and PESS in the risk evaluation.
Hazards. Hazards for trans-1,2-dichloroethylene 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 trans- 1,2-dichloroethylene as part of the prioritization
process. EPA identified environmental hazard information during the prioritization process and
information identified through systematic review methods and public comments may identify additional
environmental hazards that warrant inclusion in the environmental hazard assessment in the risk
evaluation. Environmental hazard effects were identified for aquatic and terrestrial organisms.
EPA will use systematic review methods to evaluate the epidemiological and toxicological literature for
trans- 1,2-dichloroethylene. 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 of the potential human health hazards for trans-\,l-
dichloroethylene identified during prioritization. The broad health effect categories include
immunological and irritation effects.
Analysis Plan. The analysis plan for trans- 1,2-dichloroethylene is presented in Section 2.7. The analysis
plan outlines the general science 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 trans- 1,2-dichloroethylene 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
trans- 1,2-dichloroethylene, 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 trans- 1,2-dichloroethylene 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 Part 702.451
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1 INTRODUCTION
This document presents for comment the draft scope of the risk evaluation to be conducted for trans-1,2-
dichloroethylene 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) and 40 CFR Part 702. Subpart A require the Environmental Protection Agency (EPA) to
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 the EPA publish the scope of the risk
evaluation to be conducted, including the hazards, exposures, conditions of use and potentially exposed
or susceptible subpopulations 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 (84 FR 71924). as required by TSCA § 6(b)(2)(B). trans-1,2-
Dichloroethylene 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 trans- ] ,2-dichloroethylene. EPA leveraged the data and
information sources already identified in the documents supporting the chemical substance's high-
priority substance designations. 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. Gray literature, which is defined as the broad category of data/information sources not found in
standard, peer-reviewed literature databases;
2. Databases containing publicly available, peer-reviewed literature; and
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
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
702.331.
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process. The search and screening process was conducted based on EPA's general expectations for the
planning, execution and assessment activities outlined in the Application of Systematic Review in TSCA
Risk Evaluations document (U.S. EPA, 2018a). EPA will publish supplemental documentation on the
systematic review methods supporting the trans-] ,2-dichloroethylene 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 trans-1,2-
dichloroethylene upon publication of the supplemental documentation of those methods.
2.1.1 Search of Gray Literature
EPA surveyed the gray literature2 and identified 123 search results relevant to EPA's risk assessment
needs for trans-1,2-dichloroethylene. Appendix A lists the gray literature sources that yielded 123
discrete data or information sources relevant to trans-] ,2-dichloroethylene. 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.
Gray Literature Tags by Discipline
38/123
Phvsical.Chcmieal
Human. Health. Hazard
39/123
12/123
Environmental. I Iazard
79/123
Engineering
0 25 50 75 100
Percent Tagged (%)
Figure 2-1. Gray Literature Tags by Discipline for fra«s-l,2-Dichloroethylene
The percentages across disciplines do not add up to 100%, as each source may provide data or information for various topic
areas (or disciplines). TDCE = /ra«.v- 1.2-dichlorocthvlcnc.
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
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.
14
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occupational exposure), exposure (environmental, general population and consumer) and environmental
and human health hazards of trans-1,2-dichloroethylene. 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 through Figure 2-6. "TIAB" in these figures refer to "title and abstract" screening.
Note that 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.
Point
Melting Point
Water Solublity
log KOW
Henry's Law Constant
Vapor Pressure
Vapor Density
Density
Viscosity
Retrieved for Full-text
Review
Included for Data
Extraction and Data
Evaluation
Dielectric Constant
Refractive Index
Total for TIAB:
P-Chem
Supplemental Information
Exclusion
Exclusion
Figure 2-2. Peer-Reviewed Literature - Physical-Chemical Properties Search Results for trans-1,2-
Dichloroethylene
15
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Bioconcentration
Retrieved for Full-text
Review
Sorption
Volatilization
Total for TIAB:
Fate
Wastewater Treatment
267
Exclusion
Other
Figure 2-3. Peer-Reviewed Literature - Fate and Transport Search Results for trans-1,2-
Dichloroethylene
-------
General Facility Estimate
Included
Oceapa.ti.oBal Exposure
423
347
Figure 2-4. Peer-Reviewed Literature - Engineering Search Results for fra«s-l,2-Dichloroethylene
17
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Unique HERO IDs (395) 1 ~[ Excluded (100) 1
ambient air (33)
aquatic species (6)
biosolids/siudge (10)
I ground water (84)
[consumer uses and/or products (2)
Supplemental (102) m drinking water (33)
dietary (4)
PECO relevant (148)
epidemiological/biomonitoring study (6)
Included (193)
Unclear (45)
indoor air (10)
sediment (23)
soil (46)
surface water (58)
terrestrial species 5)
Figure 2-5. Peer-Reviewed Literature - Exposure Search Results for trans- 1,2-Dichloroethylene
18
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J Human Health Model
Ecotoxicofogtcal Mode!
Reteievucl for Full-text
R«¥ISW
iPK
Case Report Series
9283
37 ?4
Ccrfeiwro? Abstract
r—~~—
F»eid Study
244
PECQ-rtXevaiif isomer
Susceptible Population
Figure 2-6. Peer-Reviewed Literature - Hazard Search Results for fra«s-l,2-Dichloroethylene
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, as amended by the Frank R. Lautenberg Chemical Safety for the 21st Century
Act. EPA screened a total of 63 submissions using inclusion/exclusion criteria specific to individual
disciplines. EPA identified 60 submissions that met the inclusion criteria in these statements and
identified 2 submissions with supplemental data. EPA excluded one submission because the report was
identified as an environmental impact statement for proposed equipment.
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.
19
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Table 2-1. Results of Title Screening of Submissions to EPA under Various Sections of TSCA a
Discipline
Included
Supplemental h
Physicochemical Properties
0
0
Environmental Fate and Transport
3
0
Environmental and General Population Exposure
57
0
Occupational Exposure/Release Information
3
0
Environmental Hazard
0
0
Human Health Hazard
1
2
a Individual submissions may be relevant to multiple disciplines.
b Included submissions may contain supplemental data for other disciplines, which will be identified at full-text review.
2.2 Conditions of Use
As described in the Proposed Designation of trans-1,2-dichloroethylene (CASRN156-60-5) 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 use or significant changes in conditions of use of the
chemical substance. EPA also consulted a variety of other sources to identify uses of trans-1,2-
dichloroethylene, including: published literature, company websites, and government and commercial
trade databases and publications. To identify formulated products containing trans-1,2-dichloroethylene,
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. SDSs were cross-checked
with company websites to make sure that each product SDS was current. In addition, EPA incorporated
communications with companies, industry groups, environmental organizations, and public comments to
supplement the 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 trans-1,2-dichloroethylene, EPA identified those categories or
subcategories of use activities for trans- } ,2-dichloroethylene 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 EPA plans to include in the scope of the risk evaluation. EPA is
looking for more information to confirm the reports of trans-1,2-dichloroethy 1 ene used for inspection
penetrant and pipe repair that are not currently included as conditions of use.
Table 2-2. Conditions of Use Included in the Scope of the Risk Evaluation
Lilc-Cyclc Stage
Category
Subcategory
Ueference
Manufacturing
Domestic
manufacture/Import
Domestic Manufacture
U.S. EPA (2019)
20
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l.ifc-Cvck' Stsigo
CiiU'gorv
Suhcsi logon
Uol'omico
Manufacturing
Import
Import
U.S. EPA (2019)
Processing
Processing as a
reactant
Plating agents and surface
treating agents
U.S. EPA (2019)
Processing
Processing as a
reactant
Intermediate in chemical
product and preparation
manufacturing
Dreher (2014); Axiall
(2016)
Processing
Processing -
incorporation into
formulation, mixture
or reaction product
Solvents (for cleaning or
degreasing)
U.S. EPA (2019)
Processing
Processing -
incorporation into
formulation, mixture
or reaction product
Solvents (which become part of
product formulation or mixture)
U.S. EPA (2019)
Processing
Processing -
incorporation into
formulation, mixture
or reaction product
Adhesives and sealant
chemicals
Wilsonart (2017)
Processing
Processing -
incorporation into
formulation, mixture
or reaction product
Foam blowing additive
Axiall (2016)
Processing
Processing -
incorporation into
formulation, mixture
or reaction product
Carrier solvent in adhesives,
coatings, inks, lubricants, and
silicones.
EP A-HO-OPPT-2.018-
0
Uh
1
O
o
o
;o
Processing
Incorporation into
articles
Propellant and blowing agent in
plastics product manufacturing;
flexible polyurethane foam
manufacturing
U.S. EPA (2019)
Processing
Repackaging
Repackaging
U.S. EPA (2019)
Processing
Recycling
Recycling
U.S. EPA (2019)
Distribution in
commerce
Distribution in
commerce
Distribution in commerce
Industrial/commercial
use
Solvents (for cleaning
or degreasing)
Vapor degreaser
EP A-HO-OPPT-2018-
0465-0006
Industrial/commercial
use
Solvents (for cleaning
or degreasing)
Aerosol spray cleaner/degreaser
EP A-HO-OPPT-2018-
0 1 > 000?, \ f \ \iQz.
OPPT-2018-0465-
0006.
21
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l.ifc-Cvck' Stsigo
CiiU'gorv
Suhcsi logon
Uol'omico
OPPT-2018-0465-
0009
Industrial/commercial
use
Solvents (for cleaning
or degreasing)
Flux remover (liquid and
aerosol)3
ACL Staticide (2016)
Commercial use
Solvents (for cleaning
or degreasing)
Refrigerant flush
Ace (2015)
Industrial/commercial
use
Cleaning and
furnishing care
products
Spot cleaner; stain remover
U.S. EPA (2019)
Industrial/commercial
use
Functional fluids
(open systems)
Smoothing fluid in additive
manufacturing
Microcare (2018)
Industrial/commercial
use
Anti-adhesive agent
Mold release
EP A-HO-OPPT-2018-
0465-0006
Industrial/commercial
use
Solvents (which
become part of product
formulation or
mixture)
Urethane coatings
Miller-Stephenson
(2016 a,b)
Industrial/commercial
use
Lubricants and greases
Liquid and spray lubricants and
greases, and penetrating
lubricants
EP A-HO-OPPT-2018-
0465-0006
Industrial/commercial
use
Adhesives and sealants
Solvent-based adhesives and
sealants; adhesive accelerant
Wilsonart (2017);
Permabond (2018).
Industrial/commercial
use
Functional fluids
(closed systems)
Refrigerant
U.S. EPA (2016)
Industrial/commercial
use
Functional fluids
(closed systems)
Pharmaceutical and medicine
manufacturing
Dreher (2014); ICH
(2016)
Industrial/commercial
use
Processing aids
Extraction solvent for
thermoplastics
Dreher (2014)
Commercial use
Propellants and
blowing agents
Polyurethane foam building
insulation
Demilec (2017a);
Demilec (2017b);
Covestro LLC. (2016)
Industrial/commercial
use
Other uses
Laboratory chemicals
Thermo Fisher
Scientific (2018)
Consumer use
Solvents (for cleaning
or degreasing)
Aerosol degreaser
CRC Industries Inc.
(2017)
Consumer use
Propellants and
blowing agents
Polyurethane foam building
insulation
Demilec (2017a);
Demilec (2017b);
Covestro LLC. (2016)
3 Flux removal can be done by vapor degreasing, which is listed above separately as a COU.
22
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l.ifc-Cvck' Stsigo
CiiU'gorv
Suhcsi logon
Uol'omico
Consumer use
Cleaning and
furnishing care
products
Spot cleaner; stain remover
Albatross USA Inc
(2020)
Consumer use
Adhesives and sealants
Solvent-based; adhesive
accelerant
Permabond (2018).
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.
23
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2.2.2 Activities Excluded from the Scope of the Risk Evaluation
As explained in the final rule for 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 potentially exposed or susceptible subpopulations 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 33736, 33729; July 20, 2017). As a result, EPA does
not plan to include in this scope or in the risk evaluation activities that the Agency has concluded do not
constitute conditions of use.
No conditions of use were excluded for trans- ] ,2-dichloroethylene.
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 ^ra«5-l,2-dichloroethylene in 2015 was between 1 million and 10 million pounds (U.S. EPA
2017). EPA also uses pre-2015 CDR production volume information, as detailed in the Proposed
Desismation of trans-1,2-dichloroethylene (CASRN156-60-5) as a Hieh-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
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 industrial,
commercial and consumer uses). The production volume of trans-1,2-dichloroethy 1 ene in 2015 is
included in the lifecycle diagram, as reported to EPA during the 2016 CDR reporting period, as a range
between 1 million and 10 million pounds (U.S. EPA, 2019b).
-------
MFG/IMPORT
PROCESSING
INDUSTRIAL, COMMERCIAL, CONSUMER USES
RELEASES and WASTE DISPOSAL
Manufacture
(Including
Import)
(l-10Mlb)
Processing as a Reactant
(Plating agents and surface treating
agents)
Incorporation into Formulation,
Mixture, or Reaction Product
(Solvents (for cleaning or degreasing),
solvents (which become part of product
formulation or mixture), adhesives and
sealant chemicals, carrier solvent in
adhesives, coatings, inks, lubricants and
silicones)
Incorporation into Article
(Propellants and blowing agents for
plastics product manufacturing)
Repackaging
4
Solvents (for cleaning or degreasing)
e.g.. Vapor degreaser1, aerosol spray
cleaner degreaser1-2, flux remover1
Cleaning and Furniture Care Products1,
Anti-adhesive Agent1
Solvents (which become part of product
formulation or mixture)1
Lubricants and Greases1
Adhesives and Sealants1,2
Functional Fluids (Qosed or Open
Systems)1
Pi'ocessing aids1
Propellants and Blowing Agents
e.g., Polyurethane foam building insulation 1,2
Other Use: Laboratory Chemicals1
Recycling
Disposal
~
~
~
Manufacture (Including Import)
Processing
Uses:
1. Industrial and/or commercial
2. Consumer
Figure 2-7. *rfl«s-l,2-Dichloroethylene 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 § 14. There may be additional activities and uses not shown in the diagram that are claimed CBI.
25
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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 trans-1,2-
dichloroethylene. 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
take into account, where relevant, the duration, intensity (concentration), frequency and number of
exposures in characterizing exposures to trans-1,2-dichloroethylene.
2.3.1 Physical and Chemical Properties
Consideration of 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 trans-1,2-Dichloroethylene (CASRN 156-1 ra
High-Priority Substance for Risk Evaluation (U.S. EPA (2019)) to support the development of the risk
evaluation for trans-] ,2-dichloroethylene. The values for the physical and chemical properties(Appendix
B) may be updated as EPA identifies 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 trans-] ,2-dichloroethylene. EPA plans to use the environmental fate
characteristics described in the Proposed Designation of trans-1,2-DicMoroethylene (CASRN 156-60-5)
as a High-Priority Substance for Risk Evaluation (U.S. EPA (2019)) to support the development of the
risk evaluation for trans-] ,2-dichloroethylene. The values for the environmental fate properties
(Appendix C) may be updated as EPA identifies additional information through systematic review
methods.
2.3.3 Releases to the Environment
Releases to the environment from conditions of use (e.g., 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 and/or
assumptions and models.
A source of information that EPA plans to consider in evaluating exposure are data reported to the TRI
program. EPA's TRI database contains information on chemical waste management activities that are
disclosed by industrial and federal facilities, including quantities released into the environment (i.e., to
air, water, and land), treated, burned for energy recovery, recycled, or transferred off-site to other
facilities for these purposes.
Under the Emergency Planning and Community Right-to-Know Act (EPCRA) Section 313, 1,2-
dichloroethylene (CASRN 540-59-0) is a TRI-reportable substance effective as of January 01, 1987 (40
CFR 372.65). For TRI reporting4, facilities in covered sectors in the United States are required to
disclose releases and other waste management quantities of 1,2-dichloroethylene as CASRN 540-59-0 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.
4 For TRI reporting criteria see https://www.epa.gov/toxics-release-inventore-tri-prograin/basics-tri-reporting
26
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Facilities reporting 1,2-dichloroethylene releases and waste management quantities are not required to
differentiate between the cis- and trans- isomers; as such there is no way to differentiate between the
isomers from reported TRI data. However, since the relative percentages of commercial forms of 1,2-
dichloroethylene tend to be 60% cis- isomer:40% /ram-isomer, one can roughly estimate the specific
quantities of each isomer that comprise mass quantities reported to TRI for 1,2-dichloroethylene.
Table 2-3 provides production-related waste management data for 1,2-dichloroethylene (two isomers or
mixture of two) reported by facilities to EPA for reporting year 2018.5 As shown in the table,
18 facilities reported a total of nearly 10 million pounds of 1,2-dichloroethylene waste managed. Nearly
90% of the total production-related waste quantities reported for the chemical was treated. Compared to
the other waste management quantities reported, very little of 1,2-dichloroethylene (less than 0.13%)
was disposed of or otherwise released to the environment during 2018.
Table 2-3. Summary of 1,2-Dichloroethylene Production-Related Waste Managed in 2018
Year
Number of
Facilities
Recycled
diis)
Recovered for
F.nergv
(lbs)'
Treated
(lbs)
Released
(lbs)"-1""
Total Production
Related Waste
(lbs)
2018
18
421,620
590,821
8,934,334
12,611
9,959,385
Data source: U.S. EPA, 2018a (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 1,2-dichloroethylene released or disposed of to the
environment during 2018.5 There were zero pounds reported as released to water via surface water
discharges, and a total of 9,477 pounds released to air, mostly as fugitive emissions. Very little of 1,2-
dichloroethylene was disposed of to land. The 3,102 pounds classified as "other releases" were sent off
site to waste brokers for disposal, accounting for roughly Vi of total releases.
Table 2-4. Summary of Releases of 1,2-Dichloroethylene to the Environment During 2018
Nil in her
ol
l-'sieililies
Air Kt
Sisick Air
Kelesises
(Ills)
¦lesises
l-"ii;ii(i\e
Air
Kelesises
(Ills)
\\ siler
Kelesises
(Ihs)
(hiss 1
1 nder-
liroinnl
Injection
(Ihs)
.siihI l)is|)o>
KCKA
Subtitle ('
l.siiKHills
(Ihs)
Sll
All oilier
1 -Sill(1
Dispossil
(lhsf'
Oilier
Kelesises
(Ihs)'1
lolsil
Kelesises
(Ihs)
Totals
18
1,806
7,671
0
4
3
24
3,102
12,611
9,477
31
Data source: U.S. EPA, 2018a (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 production-related waste managed shown in Table 2-3 excludes any quantities reported as
catastrophic or one-time releases (TRI Form R, section 8 data), release quantities shown in Table 2-4
5 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.
27
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include both production-related and non-production-related quantities for 2018. In the case of 1,2-
dichloroethylene the total release quantities shown in the two tables are the same, but for other TRI
chemicals they may differ slightly and may further reflect differences in TRI calculation methods for
reported release range estimates (U.S. EPA. 2017d).
EPA plans to review these data in conducting the exposure assessment component of the risk evaluation
for trans-1,2-dichloroethylene.
2.3.4 Environmental Exposures
The manufacturing, processing, distribution, use and disposal of trans-1,2-dichloroethylene 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 available environmental exposure data in biota in the
risk evaluation. Monitoring data were identified in the EPA's data search for trans-1,2-di chl oroethyl ene
and can be used in the exposure assessment. Relevant and reliable monitoring studies provide(s)
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 available environmental monitoring data in the risk evaluation. USGS's Monitoring
Data - National Water Quality Monitoring Council has identified trans-1,2-dichloroethylene in air,
ground water, sediment, soil, surface water and biota (e.g., fish tissue concentrations) (USGS 1991a-g).
In the United States, the California Environmental Protection Agency (CalEPA) has measured trans-1,2-
dichloroethylene in surface water at levels of 0.43-1,307 ppb and in groundwater at levels of 0.25-
500,000 ppb (CalEPA. 2006). A source of trans-1,2-dichloroethylene is anaerobic biodegradation of
chlorinated solvents, and these are present at detectable levels in landfill gases (A.TSDR 1996).
Disposal and leaching of chlorinated solvent waste may lead to levels of trans-1,2-dichloroethylene in
soil and sediment via the migration of trans-1,2-di chl oroethylene from groundwater.
2.3.5 Occupational Exposures
EPA plans to analyze worker activities where there is a potential for exposure under the various
conditions of use described in Section 2.2.1. In addition, EPA plans to analyze exposure to occupational
non-users, i.e., workers who do not directly handle the chemical but perform work in an area where the
chemical is present. When data and information are available to support the analysis, EPA also plans 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 conditions of use within the scope of the risk evaluation for trans- 1,2-
di chl oroethyl ene will be analyzed, including but not limited to:
• Unloading and transferring trans- 1,2-di chl oroethylene to and from storage containers to process
vessels;
• Handling, transporting and disposing of waste containing trans- 1,2-di chl oroethylene;
• Cleaning and maintaining equipment;
• Sampling chemicals, formulations or products containing trans- 1,2-di chl oroethylene for quality
control;
• Repackaging chemicals, formulations or products containing £ra«s-l,2-dichloroethylene.
/raws-1,2-Di chloroethylene has a vapor pressure of 331 mmHg at 25°C (see Appendix B), hence,
inhalation exposure is a significant route of exposure for workers and occupational non-users (ONUs) in
28
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occupational exposure scenarios where trans-1, 2-dichloroethy 1 ene is used and handled in open systems
or where there is potential for mist generation. The extent of exposure could vary from facility to facility
depending on many factors including but not limited to EC, type of facility, and facility design, trans-
1,2-Dichloroethylene has an Occupational Safety and Health Administration (OSHA) Permissible
Exposure Limit (PEL)6 of 200 ppm or 790 mg/m3 over an 8-hour workday, time weighted average
(TWA). This chemical also has a National Institute for Occupational Safety and Health (NIOSH)
Recommended Exposure Limit (REL)7 of 200 ppm (790 mg/m3) TWA. The American Conference of
Governmental Industrial Hygienists (ACGIH) sets the Threshold Limit Value (TLV) at 200 ppm TWA.
EPA plans to analyze worker exposure to liquids via the dermal route. EPA does not plan to analyze
dermal exposure for occupational non-users because they do not directly handle trans-1,2-
dichloroethylene. EPA generally does not evaluate occupational exposures through the oral route
because oral exposure is typically incidental in nature.
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.
2.3.6 Consumer Exposures
No conditions of use information for trans-l, 2-di chl oroethylene was found in the 2012 or 2016 CDR.
One material safety data sheet indicated that trans-l, 2-di chl oroethylene is solvents for cleaning and or
degreasing, particularly as an aerosol degreaser (CRC Industries Inc. (2017)). Additional conditions of
use include cleaning and furnishing care products such as spot cleaners and stain removers, as well as
adhesives and sealants which may be solvent-based or adhesive accelerants (Albatross USA Inc (2020),
Permabond (2018)). Off-gassing of trans-l, 2-di chl oroethylene from polyurethane foam and building
insulation is a potential source of exposure to trans-l, 2-di chl oroethylene. In addition, the Consumer
Product Database (CPDat) indicated that trans-l, 2-di chl oroethylene in used as a consumer product in in
cleaners, propellants, and solvents.
Consumers using or disposing of aerosol degreasing products, cleaning and furnishing care products, or
adhesives and sealants, may be exposed to ^m«5-l,2-dichloroethylene through direct liquid contact
which may lead to a dermal exposure. In addition, due to its high volatility at room temperature trans-
1,2-di chl oroethylene may expose consumers via a vapor pathway which may lead to inhalation
exposure. Bystanders present during the consumer use or disposal of solvents used for cleaning and or
degreasing, cleaning and furnishing care products, adhesives and sealants, or polyurethane foam
building insulation, may also be exposed to ^m«5-l,2-dichloroethylene via vapors leading to inhalation
exposures. The vapor to inhalation exposure route is particularly noteworthy for trans-1,2-
di chl oroethylene as known products are supplied as aerosols.
2.3.7 General Population Exposures
Releases of trans-l, 2-di chl oroethylene from certain conditions of use, such as manufacturing, disposal,
or waste treatment activities, may result in general population exposures via drinking water ingestion,
6 OSHA, 2009. Occupational Safety and Health Administration (OSHA) Permissible Exposure Limits (PELs).
https://www.osha.gov/dsg/an.notated-peis/tablez-l.htmi
7 NIOSH, 2005. NIOSH Pocket Guide to Chemical Hazards, https://www.cdc.gov/niosli/npg/npgdcas.ht.mi
29
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dermal contact, and inhalation from air releases. The general population that lives in urban areas may be
exposed to low levels (0.013-0.076 ppb) of /raws-1,2-di chl oroethylene via air (ATSDR 1996). In
addition, the general population may also be exposed to low levels of trans-1,2-dichloroethylene in U.S.
drinking water supplies. Community systems that rely on groundwater supplies may have a higher
possibility of exposure to trans-1,2-dichloroethylene (ATSDR 1996). There is a lack of available data to
quantify general population exposure to trans-1, 2-dichloroethy 1 ene by oral and dermal routes (ATSDR
2016. CalEPA. 2006).
The OECD monitoring database has identified human biomonitoring data for trans-l, 2-di chl oroethylene
(OECD 2018). However, blood concentrations of ^ra«5-l,2-dichloroethylene were below the limit of
detection in 2,754 individuals who participated in the National Health and Nutrition Examination Survey
(NHANES) 2011-2012 subsample of the U.S. population (CDC, 2018)
2.4 Hazards (Effects)
2.4.1 Environmental Hazards
As described in the Promised Designation of trans-1,2-Dichloroethylene fCASRiS W-5> as a High-
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 trans-1,2-dichloroethylene. 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 trans-1,2-dich\oroethylene exposure.
2.4.2 Human Health Hazards
As described in the Proposed Designation of trans-1,2-Dichloroethylene fCASRA L _ 5 0-5) as a High-
Priority Substance for Risk Evaluation (U.S. EPA 2019a), EPA considered reasonably available
information from peer-reviewed assessments and databases to identify potential human health hazards
for *ra«s-l,2-dichl oroethylene. EPA plans to evaluate all of the potential human health hazards for
trans-l, 2-di chl oroethylene 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
absorption, distribution, metabolism, and excretion (ADME). 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 trans-1,2-
dichloroethylene risk evaluation.
2.5 Potentially Exposed or Susceptible Subpopulations
TSCA requires the 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 elderlyGeneral population is "the total of individuals inhabiting an area or making up
a whole group" and refers here to the U.S. general population (i__S
30
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During the Prioritization process, EPA identified the following potentially exposed or susceptible
subpopulations based on CDR information and studies reporting developmental and reproductive
effects: women of reproductive age (e.g., pregnant women per TSCA statute), workers and consumers
(U.S. EPA 2019). EPA plans to evaluate these potentially exposed or susceptible subpopulations in the
risk evaluation.
In developing exposure scenarios, EPA plans to analyze available data to ascertain whether some human
receptor groups may be exposed via exposure pathways that may be distinct to a particular
subpopulation or life stage and whether some human receptor groups may have higher exposure via
identified pathways of exposure due to unique characteristics (e.g., activities, duration or location of
exposure) when compared with the general population (U.S. EPA. 2006a). 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 transA ,2-dichloroethylene.
Pathways and routes of exposure associated with workers and occupational non-users 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 trans-1,2-dichloroethy 1 ene that EPA plans to include in the risk evaluation. There
is potential for exposures to workers and/or occupational non-users via inhalation routes and exposures
to workers via dermal routes. It is expected that inhalation exposure to vapors is the most likely
exposure route. In addition, workers at waste management facilities may be exposed via inhalation or
dermal routes from wastewater treatment, incineration or via other disposal methods. 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. For
each condition of use identified in Table 2-2, an initial determination was made as to whether or not
each combination of exposure pathway, route, and receptor will be further analyzed in the risk
evaluation. The results of that analysis along with the supporting rationale are presented in Appendix F.
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INDUSTRIAL AND COMMERCIAL EXPOSURE PATHWAY EXPOSURE ROUTE RECEPTORS HAZARDS
ACTTVTnES / USES
Manufacturing (incl.
Import)
Liquid Contact
Dermal
Workers
Processing:
- Processing as a reactant
- Incorporation into
formulation, mixture, or
reaction product
- Incorporation into
articles
- Repackaging
Hazards Potentially
Associated with Acute and or
Chronic Exposures
Occupational Non-
Solvents (for cleaning and
degreasing)
Fugitive Emissions
Cleaning and Furniture
Care Products
Anti-adhesive Agent
Solvents (which become
part of product
formulation or mixture)
Lubricants and Greases
Adhesives and Sealants
Functional Fluids
Processing aids
Propellants and Blowing
Agents
Other Use
Waste Handling.
Treatment and"
Disposal
Wastewater, Liquid Wastes and Solid Wastes
(See Environmental Release Conceptual _l4fc>e
Figure 2-8. fra«s-l,2-Dichloroethylene Occupational Exposure Conceptual Model for Industrial and Commercial Activities and Uses:
Worker and Occupational Non-User 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 irans-\.2-
dichloroethylene.
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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 trans-] ,2-dichloroethylene. EPA expects
inhalation to be the primary route of exposure and plans to analyze inhalation exposures to trans-1,2-
dichloroethylene vapor for consumers and bystanders. Aerosol application of solvents for cleaning and
degreasing, cleaning and furnishing care products, and adhesives and sealants may result in an inhalation
of mist for consumers and bystanders. Off-gassing of trans- ] ,2-dichloroethylene from polyurethane
foam insulation may also result in inhalation exposures to consumers and bystanders. There is potential
for dermal exposures to trans-] ,2-dichloroethylene via direct contact with liquid during consumer uses.
Bystanders are not expected to have direct dermal contact to trans-1,2-dichloroethy 1 ene. EPA plans to
analyze direct dermal contact with liquid trans-1,2-dichloroethylene for consumers using cleaning and
furnishing care products, solvents for cleaning and degreasing, and adhesives and sealants. The
supporting rationale for consumer pathways that are in scope for trans-1,2-dichloroethylene are included
in Appendix G.
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c o\si \ii r w f i\ rin s i:M'osi Ri i xrosi ki:
I si's P \ I'HYN AVs KOI n > IOK& HAZARDS
Solvents for Cleaning
and Decreasing
~* Ccmsiuners
Contact
Hazards Potentially
Associated wWi
Acute and/or Chronic
Consumer Handling
of Disposal and Waste
Wastewater, Liquid Wanes and Solid
~> Wastes (See Environmental Releases
Conceptual Models)
Figure 2-9. fra«s-l,2-Dichloroethylene Conceptual Model for Consumer Activities and Uses: Consumer Exposures and Hazards
The conceptual model presents the exposure pathways, exposure routes and hazards to human receptors from consumer activities and uses of ;ra/?.v-1.2-dichlorocthvlcne.
Note:
a) Receptors include potentially exposed or susceptible subpopulations (see Section 2.5).
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2.6.3 Conceptual Model for Environmental Releases and Wastes: Potential Exposures
and Hazards (Regulatory Overlay)
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 lrans-\ ,2-dichloroethylenewithin
the scope of the risk evaluation. It also discusses those pathways that may be addressed pursuant to other
Federal laws.
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 trans-1,2-
dichloroethylene 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 trans-1,2- dichloroethylene. 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 2.6.3.3.
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RELEASES AND WASTES FROM
INDUSTRIAL / COMMERCIAL /
CONSUMER USES
EXPOSURE PATHWAYS
EXPOSURE
ROUTES
RECEPTORS
CWA-AWQC
SDWA
Indirect discharge
POTW
Oral
RCRA-HazList
I .and
Disposal
Hazards Potentially
Associated with
Acute and/or Chronic
Exposures
General
Population
Dermal
Ground
Water
Soil
Inhalation
Fugitive Emissions
Air
IJ nderground
Injection
Emissions to Air
Off-site Waste
Transfer
Recycling, Other
Treatment
Water, Sediment
Drinking
Water
Hazardous and
Municipal Waste
Landfill
Industrial Pre-
l'reatment or
Industrial WWT
Wastewater or
Liquid Wastes
Solid Wastes
Hazardous and
Municipal Waste
Incinerators
Figure 2-10. f/Y/M.v-l,2-Dichloroethylene 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 and environmental receptors from releases and wastes from industrial,
commercial, and consumer uses of Iran.s-L2-dichIoroeItiylene including 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 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. Inhalation from drinking water may occur via showering
b) Receptors include potentially exposed or susceptible subpopulations (see Section 2.5).
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2.6.3.1 Drinking Water Pathway
EPA has promulgated National Primary Drinking Water Regulations (NPDWRs) under the Safe
Drinking Water Act for trans-1,2- Dichloroethylene. EPA has set an enforceable Maximum
Contaminant Level (MCL) as close as feasible to a health based, non-enforceable Maximum
Contaminant Level Goal (MCLG). Feasibility refers to both the ability to treat water to meet the MCL
and the ability to monitor water quality at the MCL, SDWA Section 1412(b)(4)(D), and public water
systems are required to monitor for the regulated chemical based on a standardized monitoring schedule
to ensure compliance with the MCL. The MCL for trans-1,2- Dichloroethylene in water is 100 ppb.
The drinking water exposure pathway for trans-1,2-dichloroethylene is currently addressed in the
SDWA regulatory analytical process for public water systems. EPA's Office of Water and Office of
Pollution Prevention and Toxics will continue to work together providing understanding and analysis of
the SDWA regulatory analytical processes and to exchange information related to toxicity and
occurrence data on chemicals undergoing risk evaluation under TSCA.
2.6.3.2 Ambient Water Pathway
EPA develops recommended water quality criteria under section 304(a) of the CWA for pollutants in
surface water that are protective of aquatic life or human health designated uses. EPA has developed
recommended water quality criteria for protection of human health for trans-1,2- Dichloroethylene
which are available for possible adoption into state water quality standards and are available for possible
use by NPDES permitting authorities in deriving effluent limits to meet state narrative criteria. As such,
EPA's OW and OPPT will continue to work together providing understanding and analysis of the CWA
water quality criteria development process and to exchange information related to toxicity of chemicals
undergoing risk evaluation under TSCA. EPA may update its CWA section 304(a) water quality criteria
for trans-] ,2-dichloroethylene in the future under the CWA.
EPA has developed CWA section 304(a) recommended human health criteria for 122 chemicals and
aquatic life criteria for 47 chemicals. A subset of these chemicals is identified as "priority pollutants"
(103 human health and 27 aquatic life), including o-dichlorobenzene. For pollutants with recommended
human health criteria, EPA regulations require that state criteria contain sufficient parameters and
constituents to protect designated uses. Once states adopt criteria as water quality standards, the CWA
requires that National Pollutant Discharge Elimination System (NPDES) discharge permits include
effluent limits as stringent as necessary to meet standards CWA section 301(b)(1)(C). This permit
issuance process accounts for risk in accordance with the applicable ambient water exposure pathway
(human health or aquatic life as applicable) for the designated water use and, therefore, can the risk from
the pathway can be considered assessed and managed.
EPA has not developed CWA section 304(a) recommended water quality criteria for the protection of
aquatic life for trans-1,2-dichloroethylene, so there are no national recommended criteria for this use
available for adoption into state water quality standards and available for use in NPDES permits. EPA
may publish CWA section 304(a) aquatic life criteria for trans-1,2-dichloroethylene in the future if it is
identified as a priority under the CWA.
2.6.3.3 Disposal and Soil Pathways
Trans-1,2- Dichloroethylene is included on the list of hazardous wastes pursuant to RCRA 3001 (40
CFR §§ 261.33) as a listed waste on the U079, F024, F025 lists. The general standard in section RCRA
3004(a) for the technical criteria that govern the management (treatment, storage, and disposal) of
hazardous waste are those "necessary to protect human health and the environment," RCRA 3004(a).
The regulatory criteria for identifying "characteristic" hazardous wastes and for "listing" a waste as
37
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hazardous also relate solely to the potential risks to human health or the environment (40 CFR §§
261.11, 261.21-261.24). RCRA statutory criteria for identifying hazardous wastes require EPA to
"tak[e] into account toxicity, persistence, and degradability in nature, potential for accumulation in
tissue, and other related factors such as flammability, corrosiveness, and other hazardous
characteristics." Subtitle C controls cover not only hazardous wastes that are landfilled, but also
hazardous wastes that are incinerated (subject to joint control under RCRA Subtitle C and the Clean Air
Act (CAA) hazardous waste combustion Maximum Achievable Control Technology (MACT)) or
injected into Underground Injection Control (UIC) Class I hazardous waste wells (subject to joint
control under Subtitle C and the Safe Drinking Water Act (SDWA)).
Emissions to ambient air from municipal and industrial waste incineration and energy recovery units that
form combustion by-products from incineration treatment of trans- 1,2-dichloroethylene wastes may be
subject to regulations, as would trans-1,2-dichloroethylene burned for energy recovery.
TRI reporting in 2018 indicated 4 pounds released to underground injection to Class I wells.
Environmental disposal of trans- 1,2-dichloroethylene injected into Class I hazardous waste well types
fall under the jurisdiction of RCRA and SDWA and disposal of trans- 1,2-dichloroethylene via
underground injection is not likely to result in environmental and general population exposures.
EPA has identified releases to land that go to RCRA Subtitle C hazardous waste landfills. Based on
2018 reporting, TRI land disposal includes Subtitle C landfills (3 pounds) with an additional amount
transferred to "other landfills" both on-site and off-site (24 pounds reported in 2018). Design standards
for Subtitle C landfills require double liner, double leachate collection and removal systems, leak
detection system, run on, runoff, and wind dispersal controls, and a construction quality assurance
program. They are also subject to closure and post-closure care requirements including installing and
maintaining a final cover, continuing operation of the leachate collection and removal system until
leachate is no longer detected, maintaining and monitoring the leak detection and groundwater
monitoring system. Bulk liquids may not be disposed in Subtitle C landfills. Subtitle C landfill operators
are required to implement an analysis and testing program to ensure adequate knowledge of waste being
managed, and to train personnel on routine and emergency operations at the facility. Hazardous waste
being disposed in Subtitle C landfills must also meet RCRA waste treatment standards before disposal.
Given these controls, general population exposure in groundwater from Subtitle C landfill leachate is not
expected to be a significant pathway.
trans- } ,2-Dichloroethylene is present in commercial and consumer products that may be disposed of in
landfills, such as Municipal Solid Waste (MSW) landfills. On-site releases RCRA Subtitle D municipal
solid waste landfills leading to exposures of the general population (including susceptible populations)
or terrestrial species from such releases are expected to be minimal based on current TRI releases (i.e.,
24 lb in 2018) for trans- 1,2-dichloroethylene. While permitted and managed by the individual states,
municipal solid waste (MSW) landfills are required by federal regulations to implement some of the
same requirements as Subtitle C landfills. MSW landfills generally must have a liner system with
leachate collection and conduct groundwater monitoring and corrective action when releases are
detected. MSW landfills are also subject to closure and post-closure care requirements and must have
financial assurance for funding of any needed corrective actions. MSW landfills have also been designed
to allow for the small amounts of hazardous waste generated by households and very small quantity
waste generators (less than 220 lb per month). Bulk liquids, such as free solvent, may not be disposed of
at MSW landfills.
38
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On-site releases to land from industrial non-hazardous and construction/demolition waste landfills may
occur for trans-1,2-dichloroethylene. Industrial non-hazardous and construction/demolition waste
landfills are primarily regulated under authorized state regulatory programs. States must also implement
limited federal regulatory requirements for siting, groundwater monitoring, and corrective action, and a
prohibition on open dumping and disposal of bulk liquids. States may also establish additional
requirements such as for liners, post-closure and financial assurance, but are not required to do so.
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 presents the exposure pathways, exposure routes and hazards to human and environmental
receptors from releases and wastes from industrial, commercial, and consumer uses of trans-1,2-
dichloroethylene 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 trans-1,2-dichloroethylene in exposure pathways falling under the jurisdiction of
these EPA statutes.
The diagram shown in Figure 2-11 includes releases from industrial, commercial and/or consumer uses
to water/sediment; biosolids and soil, via direct and indirect discharges to water, that may lead to
exposure to aquatic and terrestrial receptors, and to the general population and terrestrial species from
emissions to air. The supporting basis for environmental pathways considered for trans-1,2-
di chl oroethyl ene are included in Appendix H.
39
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RELEASES AND WASTES FROM INDUSTRIAL t EXPOSURE PATHWAYS EXPOSURE ROUTES REC EPTORS HAZARDS
COMMERCIAL/CONSUMER USES
Industrial Pre-
Treauncnt or
Industrial WWT
—~ Wafer, Sediment
Oral
I and
Disposal
Hazards Potentially
Associated with
Acute and'or Chronic
Exposures
General
Population
Dennal
Soil
CAA
RCRA
Air
CWA
Figure 2-11. rra«.v-l,2-I)ichloroeth\iene 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 and environmental receptors from releases and wastes from industrial,
commercial, and consumer uses of /r.v-1.2-dichIoroethv 1 cnc 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.
b) Receptors include potentially exposed or susceptible subpopulations (see Section 2.5).
40
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2.7 Analysis Plan
The analysis plan is based on EPA's knowledge of trans-1,2-dichloroethylene to date which includes a
partial, but not complete review of identified information as described in Section 2.1. EPA encourages
submission of additional existing data, such as full study reports or workplace monitoring from industry
sources, that may be relevant for further evaluating conditions of use, exposures, hazards and potentially
exposed or susceptible subpopulations during risk evaluation. Further, EPA may consider any relevant
CBI in the risk evaluation 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 available, EPA may update its analysis plan in the final scope
document. As discussed in the Application of Systematic Review in TSCA Risk Evaluations document
[EPA Document #740-P 1-8001], targeted supplemental searches during the analysis phase may be
necessary to identify additional information (e.g., commercial mixtures) for the risk evaluation of trans-
1,2-dichloroethylene.
2.7.1 Physical and Chemical Properties and Environmental Fate
EPA plans to analyze the physical and chemical (physical-chemical) properties and environmental fate
and transport of trans-1,2-dichloroethylene as follows:
1) Review reasonably available measured or estimated physical-chemical properties 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 physical-chemical properties (Appendix B) and fate endpoints
(Appendix C) listed in the Proposed Designation of trans-1,2-Dichloroethvlene (CASRN 156-60-
5) as a High-Priority Substance for Risk Evaluation (U.S. EPA, 2019). 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 physical-chemical
properties and environmental fate endpoints (e.g., persistence, bioaccumulation,
partitioning, transport) on exposure pathways and routes of exposure to human and
environmental receptors.
Measured data and, where necessary, model predictions of physical-chemical properties and
environmental fate endpoints will be used to characterize the persistence and movement of trans-
1,2-dichloroethylene within and across environmental media. The fate endpoints of interest
include volatilization, sorption to organic matter in soil and sediments, water solubility, aqueous
and atmospheric photolysis rates, aerobic and anaerobic biodegradation rates, and potential
bioconcentration and bioaccumulation. These endpoints will be used in exposure calculations.
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3) Conduct a weight-of-evidence evaluation of physical-chemical properties and
environmental fate data, including qualitative and quantitative sources of information.
During risk evaluation, EPA plans to evaluate and integrate the physical-chemical properties and
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.
2.7.2 Exposure
EPA plans to analyze exposure levels for surface water, sediment, soil, aquatic biota, and terrestrial
biota associated to exposure to trans-1,2-dichloroethylene. EPA has not yet determined the exposure
levels in these media or how they may be applied in the risk evaluation. Exposure scenarios are
combinations of sources (uses), exposure pathways, and exposed receptors. Draft release/exposure
scenarios corresponding to various conditions of use for trans-1,2-dichloroethylene are presented in
Appendix F, Appendix G, and Appendix H. 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
available monitoring data and modeling approaches.
2.7,2. J 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 as identified 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. Categories and Sources of Environmental Release Data
U.S. EPA TRI Data
U.S. EPA Generic Scenarios
OECD Emission Scenario Documents
Discharge Monitoring Report (DMR) surface water discharge data for trans-1,2-
dichloroethylene 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 TRI, and the data from this source is
summarized in Section 2.3.3. EPA plans to continue to review relevant data sources as identified
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.
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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 ChemSTEEl (
2013).
3) Review reasonably available measured or estimated release data for surrogate chemicals
that have similar uses and physical properties.
If surrogate data are identified, these data will be matched with applicable conditions of use for
potentially filling data gaps. Measured or estimated release data for other chlorinated solvents
may be considered as surrogates for trans-1,2-dichloroethylene.
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 April 2015
ESP on Use of Adhesives (OECD, 2015) and the September 2011 ESP on the Chemical
Industry (OECD, 201 1) may be useful. EPA intends to critically review these generic scenarios
and ESDs to determine their applicability to the conditions of use assessed.
EPA Generic Scenarios are available at the following: https://www.epa.gov/tsca-screening-
tools/using-predictive-methods-assess-exposure-and-fate-under-tsca#fate.
OECD Emission Scenario Documents are available at the following:
http://www.oecd.org/chemicalsafetv/risk-assessment/emissionscenariodocuments.htm
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 may further refine the mapping/grouping of release 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.
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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 plan 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 trans-1,2-
dichloroethylene:
1) Review available environmental and biological monitoring data for all media relevant to
environmental exposure.
For trans-} ,2-dichloroethylene, environmental media which will be analyzed include aquatic and
terrestrial species, sediment, soil, air and surface water.
2) Review reasonably available information on releases to determine how modeled estimates
of concentrations near industrial point sources compare with available monitoring data.
Available environmental exposure models that meet the TSCA Science Standards and that
estimate surface water, sediment, and soil concentrations will be analyzed and considered
alongside available surface 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 surface water, sediment, or soil, indirect release into surface 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.
Monitoring data or modeled estimates will be reviewed to determine how use patterns have
changed over recent years and will determine how representative environmental concentrations
are of ongoing use patterns.
Any studies which relate levels of trans-1,2-dichloroethy 1 ene 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).
Refine and finalize exposure scenarios for environmental receptors by considering combinations
of sources (use descriptors), exposure pathways including routes, and populations exposed. For
trans-1,2-dichloroethylene, the following are noteworthy considerations in constructing exposure
scenarios for environmental receptors:
Estimates of ambient air, surface water concentrations, sediment concentrations and
soil 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.
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Applicability of existing additional 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 occupational non-user exposures as follows:
1) Review reasonably available exposure monitoring data for specific condition(s) of use.
EPA plans to review exposure data including 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 not identified available monitoring data from OSHA and NIOSH for trans-1,2-
dichloroethylene. However, EPA has identified some data sources that may contain relevant
monitoring data for the various conditions of use. EPA plans to review these sources and extract
relevant data for consideration and analysis during risk evaluation.
EPA plans to consider the influence of applicable regulatory limits and recommended exposure
guidelines 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
1996 ATSDR Toxicological Profile for trans-1,2-dichloroethylene
2) Review reasonably available exposure data for surrogate chemicals that have uses,
volatility and chemical and physical properties similar to tram-1,2-dichloroethylene.
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 example,
methylene chloride is a volatile liquid used in various degreasing applications and may provide
surrogate data for these conditions of use.
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 emission scenario documents (ESDs) and EPA
generic scenarios (GSs) corresponding to some conditions of use. For example, the April 2015
ESP on Use of Adhesives (OECD, 2015) may be used to estimate occupational exposures. EPA
plans to critically review these generic scenarios and ESDs to determine their applicability to the
conditions of use assessed. EPA was not able to identify ESDs or GSs corresponding to several
conditions of use, including the use of trans-] ,2-dichloroethylene as a laboratory chemical. EPA
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plans to perform additional targeted research in order to better 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/OPPT, other government agencies, or 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 occupational non-users.
5) Consider and incorporate applicable engineering controls (EC) and/or personal protective
equipment into exposure scenarios.
EPA plans to review potentially relevant data sources on EC and personal protective equipment
as identified in Appendix E 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 Appendix F). EPA was not able to identify occupational scenarios corresponding to
some conditions of use (e.g. recycling, construction and demolition). EPA plans to perform
targeted research to understand those uses which may inform identification of occupational
exposure scenarios. EPA may further refine the mapping/grouping 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 documentation 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:
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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 trans-l ,2-dichloroethylene, the following are noteworthy considerations in constructing
consumer exposure scenarios:
Conditions of use and type of consumer products
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 available data.
Indoor exposure pathways expected to be relatively higher include inhalation of indoor air.
Indoor exposure pathways expected to be relatively lower include dermal contact liquids or
vapor. The data sources associated with these respective pathways have not 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,
indoor dust concentrations, or indoor dust surface loadings.
Indoor exposure models that estimate emissions from consumer products are available. These
models generally consider physical-chemical 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.
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 trans-1,2-dichloroethy 1 ene 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 trans A ,2-dichloroethylene 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
fra«s-l,2-dichloroethylene in specific media (e.g., dust or indoor air).
The availability of trans A,2-dichloroethylene 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 and dust levels and various indoor sources will be
analyzed.
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6) Review reasonably available population- or subpopulation-specific exposure factors and
activity patterns to determine if potentially exposed or susceptible subpopulations 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:
1) Refine and finalize exposure scenarios for general population by considering combinations
of sources and uses, exposure pathways including routes, and exposed populations.
For lrans- \ ,2-dichloroethylene, the following are noteworthy considerations in constructing
exposure scenarios for the general population:
Review reasonably available environmental and biological monitoring data for media to
which general population exposures are expected.
For exposure pathways where data are not available, review existing exposure models
that may be applicable in estimating exposure levels.
Consider and incorporate applicable media-specific regulations into exposure scenarios
or modeling.
Review 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 available.
Review reasonably available information on releases to determine how modeled
estimates of concentrations near industrial point sources compare with available
monitoring data.
Review reasonably available population- or subpopulation-specific exposure factors and
activity patterns to determine if potentially exposed or susceptible subpopulations need
be further defined.
Evaluate the weight of the scientific evidence of general population exposure data.
Map or group each condition of use to general population exposure assessment
scenario(s).
Environmental exposure pathways regulated by non-TSCA EPA laws and regulations
will be excluded from analysis
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,
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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 H. 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 available data and approaches. For example, EPA may
consider the co-location of TSCA industrial facilities with available monitoring data or modeled
estimates. EPA may compare modeled estimates for discrete outdoor and indoor sources/uses
that apply to unique receptor groups. If available, EPA plans to compare multiple scenario-
specific and background exposure doses estimated from media-specific concentrations and
exposure factors with available biomonitoring data. The forward-calculated and back-calculated
exposures could be compared to characterize the relative contribution from defined exposure
scenarios.
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 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 readily
available without a significant number of additional inputs or assumptions, and may be
qualitative, semi-quantitative, or quantitative. First-tier analyses were conducted during problem
formulation and are expected to continue during risk evaluation. 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 available, review existing exposure
models that may be applicable in estimating exposure levels.
For trans-1,2-dichloroethylene, media where exposure models will be considered for general
population exposure include models that estimate ambient air concentrations, surface water
concentrations, sediment concentrations, soil concentrations, and uptake from aquatic and
terrestrial environments into edible aquatic and terrestrial organisms.
3) Review available exposure modeled estimates. For example, existing models developed for
a previous fra«s-l,2-dichloroethylene chemical assessment may be applicable to the 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 trans-1,2-dichloroethy 1 ene general
population exposure scenario that is relevant to the OPPT's 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.
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4) Review reasonably available information on releases to determine how modeled estimates
of concentrations near industrial point sources compare with 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 available
monitoring data to determine representativeness.
5) Review reasonably available information about population- or subpopulation-specific
exposure factors and activity patterns to determine if potentially exposed or susceptible
subpopulations need to be further defined (e.g., early life and/or puberty as a potential
critical window of exposure).
For lrans-\ ,2-dichloroethylene, exposure scenarios that involve potentially exposed or
susceptible subpopulations will consider age-specific behaviors, activity patterns, and exposure
factors unique to those subpopulations. For example, children will have different intake rates for
dust, soil, and diet 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
EPA plans to conduct an environmental hazard assessment of trans-\,2-dichloroethylene 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 trans-1,2-dichloroethylene 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., analogue and read-across data) when characterizing the potential hazards of
trans A ,2-dichloroethylene 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.
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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 trans-1,2-dichloroethylene 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 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 trans-1,2-dichloroethylene conceptual model. These organisms may be exposed to trans-] ,2-
dichloroethylene via a number of environmental pathways (e.g., surface water, sediment, soil,
diet).
5) Conduct an environmental risk characterization of fra«s-l,2-Dichloroethylene.
EPA plans to conduct a risk characterization of trans-1,2-di chl oroethyl ene to identify if there are
risks to the aquatic and/or terrestrial environments from the measured and/or predicted
concentrations of trans- ] ,2-dichloroethylene 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; Barnthouse ct al.. 1982).
6) Consider a Persistent, Bioaccumulative, and Toxic (PBT) Assessment of trans-1,2-
dichloroethylene.
EPA plans to consider the persistence, bioaccumulation, and toxic (PBT) potential of trans-1,2-
di chl oroethyl ene after reviewing relevant physical-chemical properties and exposure pathways.
EPA plans to assess the available studies identified from the systematic review process relating
to bioaccumulation and bioconcentration (e.g., BAF, BCF) of trans-1,2-dichloroethylene. 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 trans-1,2-dichloroethylene 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:
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 trans-] ,2-dichloroethylene. 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
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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 trans-1,2-
dichloroethylene hazard(s). Susceptibility of particular human receptor groups to trans-1,2-
dichloroethylene will be determined by evaluating information on factors that influence
susceptibility.
EPA has reviewed some sources containing hazard information associated with susceptible
populations and lifestages such as pregnant women and infants. Pregnancy (i.e., gestation) and
childhood are potential susceptible lifestages for trans-1,2-dichloroethylene 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.
2012a. 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 trans-1,2-dichloroethylene, 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 ( 05).
4) Derive points of departure (PODs) where appropriate; conduct benchmark dose modeling
depending on the 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 the EPA's Benchmark
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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 U.S. EPA.
(201.0, 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, available biomonitoring data and available approaches to
correlate internal and external exposures to integrate exposure and hazard assessment.
Following systematic review, EPA plans to conduct a dose-response analysis and/or benchmark
dose modeling for the oral route of exposure based on the results. This may include using route-
to-route extrapolation methods where appropriate. EPA plans to also evaluate any potential
human health hazards following dermal and inhalation exposure to trans-1,2-dichloroethylene,
which could be important for worker, consumer, and general population risk analysis. Available
data will be assessed to determine whether or not a point of departure can be identified for the
dermal and inhalation routes.
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 the 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
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 the EPA's Risk
Characterization Handbook (U.S. EPA. 2000). As defined in the 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.
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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 (TCCR) (U.S. EPA. 2000). EPA plans to also present
information in this section consistent with approaches described in the Procedures for Chemical Risk
Evaluation Under the Amended Toxic Substances Control Act (82 FR 33726). For instance, in the risk
characterization summary, EPA plans to further carry out the obligations 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 also be guided by the EPA's Information Quality Guidelines ( 2002) as it provides
guidance for presenting risk information. Consistent with those guidelines, in the risk characterization,
EPA plans to also identify: (1) Each population addressed by an estimate of applicable risk effects; (2)
the expected risk or central estimate of risk for the potentially exposed or susceptible subpopulations
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 Risk Evaluation Rule, the purpose of peer review
is for the independent review of the science underlying the risk assessment. 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 trans-\,2-dichloroethylene will be peer reviewed.
54
-------
REFERENCES
3M Company. (2019a). 3M™ Novec™ Contact Cleaner Plus. Retrieved from
https://MiittiMedia.3ro ¦COM/Mws/roediawebser¥er?rowsId=SSSSSuLIn zu8100xm8tBm8mBov70kl7zHv
u91xtD7SSSSSS—
3M Company. (2019b). 3M™ Novec™ Electronic Degreaser Safety Data Sheet. Retrieved from
https://multimedia.3m.com/mws/mediawebserver?mwsId=SSSSSuUn zu8100xm8tBm8mZMv70kl7zH
vu91xtD 7SSSSSS--
3M Company. (2019c). 3M™ Novec™ Flux Remover. Retrieved from
https://MultiMedia.3M.coM/Mws/M.ediawebserver?MwsId=SSSSSuIJH zu8100xM8tBM.8M.9Pv70kl7zH.v
u9txtD 7SSSSSS—
Accel la Polyurethane Systems (2018). Premipour 202M. Retrieved from https ://premium spray. com/wp-
Ace (2015). Safety Data Sheet for: Ace Power Flush APF. Retreived from
https://atlanticcheMical.coM/docs/Msds/acepowerfliish.apf.Msds.pdf.
Ace (2015). Safety Data Sheet. APFA1, AFPA2 Power Flush II. April 2015. Retreived from
https://www.atlanticchemical.com/docs/msds/acepowerflushiiapfa.msds.pdf
ACL Staticide (2016). Safety Data Sheet for: Flux Remover Heavy Duty. Retreived from
https://www.aclstaticide.coM/assets/datasheets/862C df
Albatross (2017). S.P.I.F. II Cured Ink Remover (revised). Retrieved from https://s3.us-east-
2. aM azon aws. coM/atl as screen suppl v/Im ages/SD S/ Alb atross/ SD S - SED.pdf.
Allied High Tech Products Inc. (2018). Mold Release, Liquid, Hot and Cold, PTFE Safety Data Sheet.
Retrieved from
"lin(i~Cc df ^ ! ^ ~ """ 11
Allied, 2018. Allied High Tech Products. Safety Data Sheet. Mold Release, Liquid, Hot and Cold,
PTFE. June 2018.
and Cold. PTFEHUSlpdf
ATSDR (Agency for Toxic Substances and Disease Registry). (1996). Toxicological profile for 1,2-
dichloroethene [ATSDR Tox Profile], Atlanta, GA: U.S. Department of Health and Human Services,
Public Health Service, Agency for Toxic Substances and Disease Registry.
https://www.atsdr.cdc.gov/ToxProfiles/tp87.pdf
ATSDR (Agency for Toxic Substances and Disease Registry). (2019). Toxicological Profile for 1,1,2-
Trichloroethane: Draft for Public Comment. https://www.atsdr.cdc.gov/ToxProfiles/tpl48.pdf
Axiall. (2016). Product Stewardship Summary. Retrieved from
https://www.westlake.coM/sites/default/files/YersaTRA.NS%20SiiMM.arY%20EdLpdf
55
-------
Barrio-Lage, G; Parsons, FZ; Nassar, RS; Lorenzo, PA. (1986). Sequential dehalogenation of
chlorinated ethenes. Environmental Science and Technology 20: 96-99.
http://dx.doi.org/10.1021/es00143a013
CalEPA (California Office of Environmental Health Hazard Assessment). (2006). Public health goals
for chemicals in drinking water: Cis- and trans-1,2-dichloroethylene. California: California
Environmental Protection Agency, Office of Environmental Health Hazard Assessment, Pesticide and
Environmental Toxicology Branch.
https://oehha.ca.gov/media/downloads/water/chemicals/phg/phgcistrans030306.pdf
Callahan, M.A. et al. (1979). Water related fate of 129 priority pollutants. Vol II. Washington DC:
USEPA, Of Plan Stds, Off Water Waste Manag. USEPA 440/4-79-029b.
CDC (Centers for Diseases Control and Prevention). (2018). National Health and Nutrition Examination
Survey Data (NHANES) [Database], Atlanta, GA: CDC, National Center for Health Statistics. Retrieved
from https://www.cdc. gov/nchs/nhanes/index.htm
The Chemours Company FC LLC. (2019). Opteon™ XP30 (R-514A) Refrigerant. Retrieved from
https://3eonline.com/ImageServer/ImageViewer.aspx?id=3Q%2FfAR8ne%2FvPh6svVnSvmkS%2BBD
o80imbVocxRCMEgeF3flIsuNllDmv7zVWKoeDXddB5zxzJXIW7nbmF5mKrdg%3D%3D
Chu, W; Chan, KH. (2000). The prediction of partitioning coefficients for chemicals causing
environmental concern. Science of the Total Environment 248: 1-10.
Cook. Steve and Yadav. Saroi. ITW Contamination Control Electronics (2019). Comment .0-
QPPT-2018-0465-0003 on Initiation of Prioritization Under the Toxic Substances Control Act (TSCAV
Covestro (2016). Safety Data Sheet: Bay seal CC X. Retreived from https://www.idi-
insulation.com/wp-content/uploads/2016, rseal-CCX-SDS.pdf.
CRC Industries Inc. (2017). Heavy Duty Degreaser Safety Data Sheet. Retrieved from
https://docs.crcindustries.com/msds/10Q3364E.pdf
Demilec Inc. (2017a). Heatlok® XT B-side. Retrieved from
https://www.demilec.com/documents/Tech-Library/Heatlok-XT/High-Yield-XT-ENG-Updt/Heatlok-
XT-Hjgh-Yield-B-Side-SDS.pdf
Demilec Inc. (2017b). Eco-Pur 352. Safety Data Sheet - B Side.
https://www.demilec.com/es/sites/dem.ilec.com.es/files/2019-10/Eco-l Side SDS 19.pdf
Demilec Inc. (2017c). Safety Data Sheet. Heatlok Soy. May 2017.
https://www.demilec.com/sites/demilec.com/files/2019-
10/Heatlok%20 Soy%20200%20Plus%20High%20R%20B -Side%20 SD S. pdf
Durkee, J. (2014). Cleaning with solvents: Methods and machinery. In Cleaning with solvents: Methods
and machinery. Oxford, UK: Elsevier Inc.
https://www.sciencedirect.com/book/9780323225205/cleaning-with-solvents-methods-and-machinery
56
-------
Fisher Scientific. (2018). trans-1,2-Dichloroethy 1 ene, stabilized. Retrieved from
https://www.fishersci.com/shop/msdsproxv?productName=AC406840250&productDescription=TRAN
M
Fogel, MM; Taddeo, AR; Fogel, S. (1986). Biodegradation of chlorinated ethenes by a methane-
utilizing mixed culture. Applied and Environmental Microbiology 51: 720-724.
Goodman, MT, EC; Atkinson, R; Winer, AM. (1986). A study of the atmospheric reactions of
chloroethenes with OH radicals. Abstracts of papers of the American Chemical Society, Washington,
DC.
HSDB (Hazardous Substances Data Bank). (2018). trans-1,2-dichloroethylene CASRN: 156-60-5. U.S.
Department of Health and Human Services, National Institutes of Health, National Library of Medicine.
http://toxnet.nlm.nih.gov/cgi- bin/sis/search2/r?dbs+hsdb:@term+@DOCNO+6361Hyde, David,
Aerospace Industries Association (AIA) (2019). Comment EPA-HQ-QPPT-2018-0465-0006 on
Initiation of Prioritization. Under the Toxic Substances Control Act (TSCAY
International Council for Harmonization of Technical Requirements for Pharmaceuticals for Human Use
(ICH) (2016). ICH Harmonised Guidelines for Residual Solvents Q3C(R6).
Kanegsberg, B; Kanegsberg, E. (2011). Handbook for critical cleaning, cleaning agents and systems
(2nd ed.). Boca Raton, FL: CRC Press.
Kirk-Othmer. (2004). Kirk-Othmer Encyclopedia of Chemical Technology.
Kwok, ESC; Atkinson, R. (1994). Estimation of hydroxyl radical reaction rate constants for gas- phase
organic compounds using a structure-reactivity relationship: An update. (CMA Contract No. ARC-8.0-
OR). Riverside, CA: University of California.
Mackay, D; Shiu, WY; Ma, KC; Lee, SC. (2006). Handbook of physical-chemical properties and
environmental fate for organic chemicals. Boca Raton, FL: CRC press.
Miller-Stephenson (2015). MS-143H. Retrieved from https://www.miller-stephenson.com/wp-
content/uploads/sds/143H.pdf.
Miller-Stephenson (2016a). MS-470C. Retrieved from https://www.miller-stephenson.com/wp-
Miller-Stephenson (2016b). Safety Data Sheet. ReleaSys 8900. Miller-Stephenson Chemical. August
2016. https://www.miller-stephenson.com/wp-content/uploads/2016/09/ReleaSys-8S pdf
Mudder, T. (1981). Development of empirical structure-biodegradability relationships and testing
protocol for slightly soluble and volatile priority pollutants. Dissertation Abstracts International, B: The
Sciences and Engineering 42: 1804.
Mudder, TI; Musterman, JL. (1982). Development of empirical structure biodegradability relationships
and biodegradability testing protocol for volatile and slightly soluble priority pollutants. In Abstracts of
Papers of the American Chemical Society. Kansas City, MO: ACS.Microcare (2018). Safety Data Sheet:
MicroCare SSF Smoothing Station Fluid Retrieved from https://precisioncleaners.mierocare.com/wp-
con.tent/uploads/2019/11/LJSA l-SSF-SDS 10028.pdf.
57
-------
National Center for Biotechnology Information (2019). PubChem Database, trans-1,2-Dichloroethylene,
CID=638186. Retrieved from https://piibchem.ncbi.nlm.nih.gOY/compoiincl/trans-dichloroethYlene.
NEWMOA (Northeast Waste Management Officials' Association). (2001). Pollution prevention
technology profile - Closed loop vapor degreasing. Boston, MA.
http://www.newmoa.org/prevention/p2tech/ProfileVaporDegreasing.pdf
NITE (National Institute of Technology and Evaluation). (2018). Japanese CHEmicals Collaborative
Knowledge database. Japan: Ministry of Health, Labour, and Welfare; Ministry of the Environment; and
National Institute of Technology and Evaluation.
https://www.nite.go.jp/chem/jcheck/template.action?ano=478 l&mno=2-0103&cno=l 56-60-
5&request_locale=en
OECD (Organisation for Economic Co-operation and Development). (2004). Emission Scenario
Document on Lubricants and Lubricant Additives. In OECD Series On Emission Scenario Documents.
(JT00174617). Paris, France.
OECD (Organisation for Economic Co-operation and Development). (2009). Emission Scenario
Document on Adhesive Formulation. (JT03263583). Paris, France.
OECD (Organisation for Economic Co-operation and Development). (2013). Emission Scenario
Document on the Industrial Use of Adhesives for Substrate Bonding. Paris, France.
OECD (Organisation for Economic Co-operation and Development). (2018). OECD Monitoring
Database [Database], http://oecd.org
Olaniran, AO; Pillay, D; Pillay, B. (2006). Biostimulation and bioaugmentation enhances aerobic
biodegradation of dichloroethenes. Chemosphere 63: 600-608.
http://dx.doi.org/ TO. 1016/i.chemosphere.2005.08.027
O'Neil, M.J. (ed.). (2013). The Merck Index - An Encyclopedia of Chemicals, Drugs, and Biologicals.
Cambridge, UK: Royal Society of Chemistry, 2013., p. 17.
Permabond Engineering Adhesives. (2018). Safety Data Sheet: Permabond ASC10.
web ap s. ell sworth. com.
Rainbow Technology Corporation (2019). Safety Datga Sheet (SDS): Clean & Lube 4410. Retrived
from https://rainbowtech.net/wp-content/upload! an-and-Lube-SDS.pdf.
Rumble, JR. (2018). CRC handbook of chemistry and physics. In JR Rumble (Ed.), (99th ed.). Boca
Raton, FL: CRC Press.
Snedecor, et al. (2004), Chloroethylenes. Kirk-Othmer Encyclopedia of Chemical Technology. New
York, NY: John Wiley & Sons.
https://doi.org/10.1002/0471238961.1520080519140504.a01.pub2Ullmann's. (2014). Chloroethanes and
Chloroethylenes.
ThermoFisher (2018). Safety Data Sheet, trans-1,2-Dichloroethylene, stabilized. January 2018.
https://www.fishersci.com/store/msds?partNumber=AC406840250&productDescription=TRANS-
l%2C2DICHLOROETHYLENE+25G&vendorId=VN00032119&countryCode=US&language=en
58
-------
Tomer, A; Kane, J. (2015). The great port mismatch. U.S. goods trade and international transportation.
The Global Cities Initiative. A joint project of Brookings and JPMorgon Chase.
https://www.brookings.edU/wp-content/uploads/2015/06/brgkssrvygcifreightnetworks.pdfU.S.
Department of Defense (DOD) (2020). Department of Defense Comments on Thirteen Draft Scoping
Documents for TSCA Risk Evaluations, March 2020.
Tuazon, EC; Atkinson, R; Winer, AM; Jr, PJ. (1984). A Study Of The Atmospheric Reactions Of 1,3-
Dichloropropene And Other Selected Organochlorine Compounds. Archives of Environmental
Contamination and Toxicology 13: 691-700. http://dx.doi.ore/10.1007/BF01055932
U.S. EPA (U.S. Environmental Protection Agency). (1996). EPA Unregulated Contaminant Monitoring
Rule (UCMR) [Database], Retrieved from https://www.epa.gov/dwucmr
(U.S. Environmental Protection Agency). (2001). Guide to Industrial Assessments for
Pollution Prevention and Energy Efficiency. Washington, DC: US Environmental Protection Agency,
Office of Research and Development.
https://www3.epa.gov/npdes/pubs/pretreatment industrial assessments.pdf
U.S. EPA (U.S. Environmental Protection Agency). (2004). Use of Additives in Foamed Plastics -
Generic Scenario for Estimating Occupational Exposures and Environmental Releases - Draft. June
2004. https://www.epa.gov/sites/production/files/2Q19-
06/scenarios documents for screening level exposure and release assessment.zip
U.S. EPA (U.S. Environmental Protection Agency). (2012a). Estimation Programs Interface Suite for
Microsoft Windows, v. 4.11. Available online at https://www.epa.gov/tsca-screening- tools/download-
epi-suitetm-estimation-program-interface-v411
U.S. EPA (U.S. Environmental Protection Agency). (2012b). PhysProp database: CASRN: 156- 60-5.
Washington, DC: U.S. Environmental Protection Agency, https://www.epa.gov/tsca- screening-
tools/epi-suitetm-estimation-program-interface
U.S. EPA (U.S. Environmental Protection Agency). (2014). TSCA Work Plan Chemical Risk
Assessment Methylene Chloride: Paint Stripping Use CASRN: 75-09-2. (740-R1-4003). Office of
Chemical Safety and Pollution Prevention, https://www.epa.
09/documents/dcm opptworkplanra final.pdf
(U.S. Environmental Protection Agency). (2016). Public database 2016 chemical data
reporting (May 2017 release). Washington, DC: US Environmental Protection Agency, Office of
Pollution Prevention and Toxics, https://www.epa.gov/chemical-data-reporting
U.S. EPA (U.S. Environmental Protection Agency). (2016). Protection of Stratospheric Ozone:
Determiantion 31 for Significant New Alternatives Policy Program. 81 FR 32241 (May 23, 2016).
U.S. EPA (U.S. Environmental Protection Agency) (2017). Chemical Data Reporting (2012 and 2016
Public CDR database). Washington, DC. U.S. Environmental Protection Agency, Office of Pollution
Prevention and Toxics. Retrieved from ChemView: June 2019. https://www.epa.gov/chemical-data-
reporting
U.S. EPA (U.S. Environmental Protection Agency). (2019). Non-Confidential Chemical Data Reporting
(CDR). Retrieved from https://www.epa.gov/chemical-data-reporting
59
-------
U.S. EPA (U.S. Environmental Protection Agency). (2020). TRI Explorer (2018 National Analysis
Dataset (released November 12, 2019)) [Internet database]. Retrieved from
https://enviro.epa.gov/triexplorer/, (January 17, 2020).
isuiting.U.S. EPA (U.S. Environmental Protection Agency). (2019). Proposed
Designation of trans-1,2-Dichloroethylene (CASRN 156-60-5) as a High-Priority Substance for Risk
Evaluation. Washington, DC. https://www.epa.gov/sites/production/files/2019-08/documents/trans-12-
dichloroethylene_156-60-5_high-priority_proposeddesignation_082319.pdf
(2004). The U.S. solvent cleaning industry and the transition to non ozone depleting substances.
https://www.epa.gOv/sites/production/files/2' 'documents/epasolventmarketreport.pdf
USGS (U.S. Geological Survey). (1991a). USGS Monitoring Data: National Water Quality Monitoring
Council [Database], Retrieved from https://www.waterqualitydata.us/portalExposure
USGS (U.S. Geological Survey). (1991b). USGS Monitoring Data: National Water Quality Monitoring
Council - Air [Database], Retrieved from
https://www.waterqualitydata.us/portal/#sampleMedia=Air&mimeType=csv
USGS (U.S. Geological Survey). (1991c). USGS Monitoring Data: National Water Quality Monitoring
Council - Groundwater [Database], Retrieved from
https://www.waterqualitydata.us/portal/#siteType=Aggregate%20groundwater%20use&sample
Media=Water&mimeType=csv&dataProfile=activityAll
USGS (U.S. Geological Survey). (1991d). USGS Monitoring Data: National Water Quality Monitoring
Council - Sediment [Database], Retrieved from
https://www.waterqualitydata.us/portal/#sampleMedia=Sediment&mimeType=csv
USGS (U.S. Geological Survey). (1991e). USGS Monitoring Data: National Water Quality Monitoring
Council - Soil [Database], Retrieved from
https://www.waterqualitydata.us/portal/#sampleMedia=Soil&mimeType=csv
USGS (U.S. Geological Survey). (1991f). USGS Monitoring Data: National Water Quality Monitoring
Council - Surface Water [Database], Retrieved from
https://www.waterqualitydata.us/portal/#siteType=Aggregate%20surface-water-
use&sampleMedia=Water&mimeType=csv
USGS (U.S. Geological Survey). (1991g). USGS Monitoring Data: National Water Quality Monitoring
Council - Tissue [Database], Retrieved from
https://www.waterqualitydata.us/portal/#sampleMedia=Tissue&mimeType=csv
http s: //com, ptox. epa. gov/dashb oard
Verschueren, K. (2001). Handbook of environmental data on organic chemicals. New York, NY: John
Wiley & Sons, Incorporated.
WHO (World Health Organization). (1996). 1,2-Dichloroethene in Drinking-water: Background
document for development of WHO Guidelines for Drinking-water Quality. WHO/SDE/WSH/03.04/21.
https://www.who.int/water sanitation health/water-qualitv/guidelines/chemicals chloroethene-
background.pdf
60
-------
Wilson, BH; Smith, GB; Rees, JF. (1986). Biotransformations of selected alkylbenzenes and
halogenated aliphatic hydrocarbons in methanogenic aquifer material: A microcosm study.
Environmental Science and Technology 20: 997-1002.
Wilsonart (2017). WA NF742/NF743 Canister Adhesive. Retrieved from
https://wilsonart.app.box.eom/s/mfxikd46oplsp38n9vlhciwm44a91a31
-------
APPENDICES
Appendix A LIST OF GRAY LITERATURE SOURCES
TableApx A-l. Gray Literature Sources for fra«s-l,2-Dichloroethylene
Source/ Agency
Source Name
Source Type
Source Category
AT SDR
ATSDR Tox Profile Updates and
Addendums
Other US
Agency
Resources
Assessment or
Related
Document
AT SDR
ATSDR Toxicological Profiles (original
publication)
Other US
Agency
Resources
Assessment or
Related
Document
CAL EPA
Technical Support Documents for
regulations: Soil Screening
Other US
Agency
Resources
Assessment or
Related
Document
CAL EPA
Technical Support Documents for
regulations: Drinking Water Public
Health Goals
Other US
Agency
Resources
Assessment or
Related
Document
CDC
CDC Biomonitoring Tables
Other US
Agency
Resources
Database
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
Env Canada
Chemicals at a Glance (fact sheets)
International
Resources
Assessment or
Related
Document
EPA
Office of Water: STORET and WQX
US EPA
Resources
Database
EPA
EPA Office of Water: Ambient Water
Quality Criteria documents
US EPA
Resources
Assessment or
Related
Document
62
-------
Source/Agency
Source Nstnie
Source Type
Source Category
EPA
TSCA Data Needs Assessments or
Problem Formulation
US EPA
Resources
Assessment or
Related
Document
EPA
TSCA Hazard Characterizations
US EPA
Resources
Assessment or
Related
Document
EPA
IRIS Tox Review
US EPA
Resources
Assessment or
Related
Document
EPA
IRIS Summary
US EPA
Resources
Assessment or
Related
Document
EPA
Other EPA: Misc sources
US EPA
Resources
General Search
EPA
EPA: AP-42
US EPA
Resources
Regulatory
Document or List
EPA
TR1: Envirofacts Toxics Release
Inventory 2017 Updated Dataset
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
Office of Water: CFRs
US EPA
Resources
Regulatory
Document or List
EPA
Office of Water: Drinking Water
Standards Health Effects Support
Documents
US EPA
Resources
Regulatory
Document or List
63
-------
Source/Agency
Source Nstnic
Source Type
Source Category
EPA
Office of Air: National Emissions
Inventory (NEI) - National Emissions
Inventory (NEI) Data (2014, 201 1, 2008)
US EPA
Resources
Database
EPA
Office of Air: CFRs and Dockets
US EPA
Resources
Regulatory
Document or List
Japan
Japanese Ministry of the Environment
Assessments - Environmental Risk
Assessments (Class I Designated
Chemical Substances Summary Table)
International
Resources
Regulatory
Document or List
KOECT
Kirk-Othmer Encyclopedia of Chemical
Technology Journal Article
Other
Resource
Encyclopedia
NIOSH
CDC NIOSH - Health Hazard
Evaluations (HHEs)
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
Additional NTP 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
RIVM
RIVM Reports: Risk Assessments
International
Resources
Assessment or
Related
Document
64
-------
Source/Agency
Source Nstnic
Source Type
Source Category
TERA
Toxicology Excellence for Risk
Assessment
Other
Resources
Assessment or
Related
Document
65
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Appendix B PHYSICAL AND CHEMICAL PROPERTIES OF trans-
1,2-DICHLOROETHYLENE
This appendix provides p-chem information and data found in preliminary data gathering for trans-1,2-
dichloroethylene. TableApx 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 trans-1,2-Dichloroethylene fCASRN 156-60-
5} as a Hish-Priority Substance for Risk Evaluation (U.S. EPA, 2019) 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-2018-0465).
Table Apx B-l. Physical and Chemical Properties of fra«s-l,2-Dichloroethylene
Properly or Kmlpoinl
Value51
Reference
Data Quality
Kill in»
Molecular formula
C2H2CI2
NA
NA
Molecular weight
96.94 g/mol
NA
NA
Physical state
Liquid
Rumble, 2018
High
Physical properties
Colorless, light liquid,
sweetish scent
NLM, 2018
High
Melting point
-49.8 C
Rumble, 2018
High
Boiling point
47.64°C
Rumble, 2018
High
Density
1.2565 g/cm3 at 20°C
O'Neil, 2013
High
Vapor pressure
33 1 mm Hg at 25°C
NLM, 2018
High
Vapor density
3.67 at 47.64°C
(at bp at 760 mm Hg)
NLM, 2018
High
Water solubility
5,300 mg/L at 25°C
Rumble, 2018
High
Log Octanol/water partition
coefficient (Log Kow)
2.09
O'Neil, 2013
High
Henry's Law constant
9.47><10"3 atm m Vmol
at 25°C
Rumble, 2018
High
Flash point
Not available
66
-------
Propcrlv or Kmlpoinl
\ Slllll"1
UeferciKT
Dsilsi Qusililv
K;i( in«
Auto flammability
Not available
Viscosity
0.317 cP at 25°C
Rumble, 2018
High
Refractive index
1.4454
Rumble, 2018
High
Dielectric constant
2.35
Elsevier, 2019
High
a Measured unless otherwise noted.
NA = Not applicable
67
-------
Appendix € ENVIRONMENTAL FATE AND TRANSPORT
PROPERTIES OF */yww-1,2-DICHLOROETHYLENE
TableApx C-l. Environmental Fate Properties of fra«s-l,2-Dichloroethylene
Properly or Kmlpoinl
Value"
Reference
Direct Photodegradation
UV absorption at <240 nm with minor
absorption between 290 and 380 nm;
direct photolysis is not expected to be an
important fate process
\ f SDR (1996); HSDB (2018)
Indirect
Photodegradati on
ti/2 = 5 days (based on-OH reaction rate
constant of 4.5 x 10"12 cm3/mol- second at
25 °C)
AT SDR (1996) citing Goodman
etal. (1986)
ti/2 = 44 days (based on ozone reaction
rate)
AT SDR (1996) citing Tuazon et
al. (1984)
ti/2 = 6.9 hours (based on OH reaction rate
constant of 2.34 x 10"12 cm3/mol -second
at 25 °C and 5 x 105 OH radicals/cm3)
HSDB(: citing Kwok and
Atkinson (1994)
ti/2 = 57 days (based on ozone reaction
rate of 2.0 x 10"19 cmVmol-second and 7
x 1011 ozone molecules/cm3 at 25 °C)
HSDB (2018) citing Kwok and
Atkinson (1994)
ti/2 = 310 days (based on nitrate reaction
rate of 1.07 x 10"16 cmVmol second at 25
°C and 2.4 x 108 nitrate radicals/cm3)
HSDB (2018) citing Kwok and
Atkinson, 1994
Hydrolysis
Stable; trans-1,2-dichloroethy 1 ene is not
expected to undergo hydrolysis based on
its chemical structure, which lacks
functional groups known to undergo
hydrolysis under environmental
conditions
HSDB (2018) citing Callahan et
al. (1979)
Biodegradation
(Aerobic)
Water: 0% after 28 days based on BOD
(Japanese MITI test)
NITE (2018); HSDB (2018)
Water: 0%/time not specified (river die-
away test and shake-flask test)
HSDB (2018) citing Mudder
(1981), Mudder and Musterman
(1982)
Water: 67%/7 days with 33% loss due to
volatilization in 10 days (enrichment
biodegradability screening test with
wastewater inoculum; test substance
concentration of 5 ppm)
HSDB (201S) citing Fogel et al.
(1986)
68
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Properly or K ml point
Vsiluo"
UcfomuT
Soil and water: Durban, KwaZulu-Natal,
South Africa
ti/2 = 21 days in soil A (52% sand, 26.5%
clay, 21.5%) silt, microbial concentration
6.5 x 105cfu/g)
ti/2 = 23 days in soil B (80.25%) sand,
8.25%o clay, 11.5%> silt, microbial
concentration 3.0 x 105 cfu/g)
HSDB (2018) citing Olaniran el
al. (2006)
ti/2 = 27 days in water A (pH 6.98,
microbial concentration 13.25 x 105
cfu/g)
ti/2 = 26 days in water B (pH 6.94,
microbial concentration 3.4 x 105 cfu/g)
Biodegradation
(Anaerobic)
18%o/40 weeks (serum bottle) vinyl
chloride was the primary degradation
product
HSDB (2018) citing Wilson et al.
(1986)
73%>/6 months (microcosms with
uncontaminated organic sediment from
the Everglades); vinyl chloride was the
degradation product
HSDB (2018) citing Barrio-Lage
et al. (1986)
Wastewater Treatment
ti/2 = 24 minutes by evaporation from
water (1 ppm aqueous solution with still
air, an average depth of 6.5 cm, at 25 °C)
90% evaporation after 83 minutes (1 ppm
solution at 25 °C)
HSDB (', citing Verschueren
(2001)
79%o total removal (0.04%> by
biodegradation, 0.90%> by sludge and 78%
by volatilization to air; estimated)13
U.S. EPA. (2012a)
Bioconcentration Factor
11 (estimated)13
U.S. EPA. (2012a)
Bioaccumulation Factor
13 (estimated)13
U.S. EPA. (2012a)
Soil Organic
Carbon:Water Partition
Coefficient (Log Koc)
1.77 (Koc = 59)
HSDB (2018) citing Chu and
Chan (2000); Mackay et al.
(2006)
a Measured unless otherwise noted
b EPI Suite™ physical property inputs: Log Kow = 2.09, BP = 48.7 °C, MP = -49.8 °C, VP = 331 mm Hg, WS = 4,520 mg/L,
SMILES C(=CC1)C1.
•OH = hydroxyl radical; MITI = Ministry of International Trade and Industry; BOD = biochemical oxygen demand
69
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Appendix D REGULATORY HISTORY
The chemical substance, trans-1,2-dichloroethylene (trans-DCE), is subject to federal and state laws and
regulations in the United States (TableApx D-l and TableApx D-2). Regulatory actions by other
governments, tribes and international agreements applicable to trans-1,2-dichloroethylene are listed in
Table Apx D-3.
D.l Federal Laws and Regulations
Table Apx D-l. Federal Laws and Regulations
Mat ulcs/Uegulal ions
Description of Aiilhorilv/Uegulalion
Description of Regulation
EPA Regulations
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.
Trans-DCE is one of the 20
chemicals EPA designated as a
High-Priority Substance for risk
evaluation under TSCA (84 FR
71924, December 30, 2019).
Designation of trans-DCE as
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.
Trans-DCE manufacturing
(including importing),
processing and use information
is reported under the CDR rule
( 16, 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.
Trans-DCE was on the initial
TSCA Inventory and therefore
was not subject to EPA's new
chemicals review process under
TSCA section 5 (6 9,
March 29, 1995).
Toxic Substances Control
Act (TSCA) - Section
8(d)
Provides EPA with authority to issue rules
requiring producers, importers, and (if
specified) processors of a chemical
substance or mixture to submit lists and/or
copies of ongoing and completed,
unpublished health and safety studies.
4 health and safety studies
received for trans-DCE (1994)
(U.S. EPA, ChemView.
Accessed April 18, 2019).
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Slsiliik's/Ucgiihilions
Description of Aiilhorily/Ucgiihilion
Description ol' Ucgnhilion
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.
Two risk reports received for
trans-DCE (1994; 2000) (U.S.
EPA, ChemView. Accessed
April 4, 2019).
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).
DCE (mixture of the cis & trans
isomers; CAS 540-59-0) is a
listed substance subject to
reporting requirements under 40
CFR 372.65 effective as of
January 01, 1987.
Clean Air Act (CAA) -
Section 612
Under Section 612 of the CAA, EPA's
Significant New Alternatives Policy
(SNAP) program reviews substitutes for
ozone-depleting substances within a
comparative risk framework. EPA
publishes lists of acceptable and
unacceptable alternatives. A determination
that an alternative is unacceptable, or
acceptable only with conditions, is made
through rulemaking.
Under the SNAP program, EPA
listed trans-DCE as an
acceptable substitute for methyl
chloroform and CFC-113 in
metals, electronics, and
precision cleaning and in
aerosol solvents (59 FR 44240,
August 26, 1994). Later, EPA
listed trans-DCE as an
acceptable substitute for methyl
chloroform and CFC-113 in
adhesives (61 FR 47012,
September 5, 1996). EPA also
listed Transcend™
Technologies, which contains
trans-DCE, when used as an
additive to other SNAP-
approved foam blowing agents,
in blends making up to 5% by
weight of the total foam
71
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Slsiliik's/Ucgiihilions
Description of Aiilhorily/Ucgiihilion
Description ol' Ucgnhilion
formulation, as a substitute for
CFCs and HCFCs in a number
of polyurethane foam end-uses
(71 FR 15589, March 29, 2006).
Most recently, EPA has also
listed the refrigerant blend
HF0-133 6mzz(Z)/
dichloroethylene blend
(74.7/25.3) (also known as R-
514A), which contains 25.3
percent trans-DCE by weight, as
acceptable for use in centrifugal
chillers and positive
displacement chillers (81 FR
32241, May 23, 2016).
Clean Water Act
(CWA) - Section
304(a)(1)
Requires EPA to develop and publish
ambient water quality criteria (AWQC)
reflecting the latest scientific knowledge on
the effects on human health that may be
expected from the presence of pollutants in
any body of water.
In 2015, EPA published updated
AWQC for trans-DCE,
including a recommendation of
100 (|ig/L) for "Human Health
for the consumption of Water +
Organism" and 4000 (|ig/L) for
"Human Health for the
consumption of Organism Only"
for states and authorized tribes
to consider when adopting
criteria into their water quality
standards \ :O-OW-2014-
0135-02491
Clean Water Act
(CWA) - Section 301,
304, 306, 307, and 402
Clean Water Act Section 307(a) establishes
a list of toxic pollutants or combination of
pollutants under the CWA. The statue
specifies a list of families of toxic
pollutants also listed in the Code of Federal
Regulations at 40 CFR Part 401.15. The
"priority pollutants" specified by those
families are listed in 40 CFR Part 423
Appendix A. These are pollutants for which
best available technology effluent
limitations must be established on either a
national basis through rules (Sections
301(b), 304(b), 307(b), 306) or on a case-
by-case best professional judgement basis
in NPDES permits, see Section
402(a)(1)(B). EPA identifies the best
Trans-DCE is designated as a
toxic pollutant under section
307(a)(1) of the CWA and as
such is subject to effluent
limitations.
Under CWA section 304, trans-
DCE is included in the list of
total toxic organics (TTO) (40
CFR 413.02(i)).
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Slsiliik's/Ucgiihilions
Description of Aiilhorily/Ucgiihilion
Description ol' Ucgnhilion
available technology that is economically
achievable for that industry after
considering statutorily prescribed factors
and sets regulatory requirements based on
the performance of that technology.
Safe Drinking Water Act
(SDWA) - Section 1412
Requires EPA to publish non-enforceable
maximum contaminant level goals
(MCLGs) for contaminants which 1. may
have an adverse effect on the health of
persons; 2. are known to occur or there is a
substantial likelihood that the contaminant
will occur in public water systems with a
frequency and at levels of public health
concern; and 3. in the sole judgement of the
Administrator, regulation of the
contaminant presents a meaningful
opportunity for health risk reductions for
persons served by public water systems.
When EPA publishes an MCLG, EPA must
also promulgate a National Primary
Drinking Water Regulation (NPDWR)
which includes either an enforceable
maximum contaminant level (MCL), or a
required treatment technique. Public water
systems are required to comply with
NPDWRs.
Trans-DCE is subject to
NPDWR under the SDW A with
a MCLG of 100 ppb and an
enforceable MCL of 100 ppb
(Section 1412).
Resource Conservation
and Recovery Act
(RCRA) - Section 3001
Directs EPA to develop and promulgate
criteria for identifying the characteristics of
hazardous waste, and for listing hazardous
waste, taking into account toxicity,
persistence, and degradability in nature,
potential for accumulation in tissue and
other related factors such as flammability,
corrosiveness, and other hazardous
characteristics.
Trans-DCE is included on the
list of hazardous wastes
pursuant to RCRA 3001.
RCRA Hazardous Waste Code:
U079, F024, and F025 (40 CFR
261.33).
Comprehensive
Environmental
Response, Compensation
and Liability Act
(CERCLA) - Sections
102(a) and 103
Authorizes EPA to promulgate regulations
designating as hazardous substances those
substances which, when released 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
Trans-DCE is a hazardous
substance under CERCLA.
Releases of trans-DCE in excess
of 1,000 pounds must be
reported (40 CFR 302.4).
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Mat ulcs/Uegulal ions
Description of AiilhorilY/Ucgulalion
Description of Regulation
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.
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.
Trans-DCE 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.
Other Federal Regulations
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 administrative
control measures, and respiratory
protection.
In 1971, OSHA issued
occupational safety and health
standards for DCE (mixture of
the cis & trans isomers; CAS
540-59-0) that included a PEL
of 200 ppm TWA, exposure
monitoring, control measures
and respiratory protection (29
CFR 1910.1000).
OSHA has recognized that
many of its PELs are outdated
and inadequate for ensuring the
protection of worker health.
Federal Hazardous
Materials Transportation
Act (HMTA)
Section 5103 of the Act directs the
Secretary of Transportation to:
• Designate material (including an
explosive, radioactive material,
infectious substance, flammable or
combustible liquid, solid or gas, toxic,
oxidizing or corrosive material, and
compressed gas) as hazardous when the
Secretary determines that transporting
the material in commerce may pose an
Trans-DCE is listed as a
hazardous material with regard
to transportation and is subject to
regulations prescribing
requirements applicable to the
shipment and transportation of
listed hazardous materials (70
FR 34381. June 14 2005Y
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Msiliilcs/Ucgiihilions
Description of Aiilhorhy/Ucgiihilion
Description of Ucgiihilion
unreasonable risk lo health and safely
or property.
• Issue regulations for the safe
transportation, including security, of
hazardous material in intrastate,
interstate and foreign commerce.
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D.2 State Laws and Regulations
TableApx 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 Drinking
Water Standards
and Guidelines
Arizona (14 Ariz. Admin. Register 2978, August 1, 2008), California (Cal
Code Regs. Title 26, § 22-64444), Delaware (Del. Admin. Code Title 16, §
4462), Connecticut (Conn. Agencies Regs. § 19-13-B102), Maine (10 144
Me. Code R. Chap. 231), Massachusetts (310 Code Mass. Regs. § 22.00),
Michigan (Mich. Admin. Code r.299.44 and r.299.49, 2017), Minnesota
(Minn R. Chap. 4720), New Jersey (7:10 N.J Admin. Code § 5.2),
Pennsylvania (25 Pa. Code § 109.202), Rhode Island (Rules and Regulations
Pertaining to Public Drinking Water R46-13-DWQ), Texas (30 Tex. Admin.
Code § 290.104).
State PELs
California PEL for DCE mixture (CAS 540-59-0) of 200 ppm (Cal Code
Regs. Title 8, § 5155). Hawaii PEL DCE mixture (CAS 540-59-0) of 200
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
Several states have adopted reporting laws for chemicals in children's
products containing trans-DCE, including Minnesota (Toxic Free Kids Act
Minn. Stat. 116.9401 to 116.9407).
Other
Trans-DCE 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 18,
2019).
California lists Trans-DCE as a designated priority chemical for
biomonitoring under criteria established by California SB 1379
(Biomonitoring California, Priority Chemicals, February 2019).
Trans-DCE is on the MA Toxic Use Reduction Act (TURA) list of 2019
(301 CMR 41.00).
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D.3 International Laws and Regulations
TableApx D-3. Regulatory Actions by other Governments, Tribes, and International
Agreements
Country/
Organization
Requirements and Restrictions
Canada
Trans-DCE is on the Domestic Substances List. (Government of Canada.
Managing substances in the environment. Substances search. Database
accessed April 12, 2019).
European Union
Trans-DCE is registered in the European Union under regulation (EC) No
1907/2006 - REACH (Registration, Evaluation, Authorization and Restriction of
Chemicals). (European Chemicals Agency (ECHA) database. Accessed April 12,
2019).
Australia
Trans-DCE was assessed under Human Health Tier I of the Inventory
Multi-Tiered Assessment and Prioritisation (IMAP). (National Industrial
Chemicals Notification and Assessment Scheme (NICNAS). Chemical
inventory. Database accessed April 12, 2019).
Japan
Trans-DCE 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
• Water Pollution Control Law
(National Institute of Technology and Evaluation [NITE] Chemical Risk
Information Platform [CHRIP], Accessed April 12, 2019).
Belgium, Canada,
Denmark, Finland,
Germany,
Switzerland
Occupational exposure limits for trans-DCE (GESTIS International limit
values for chemical agents (Occupational exposure limits, OELs)
database. Accessed April 18, 2019.
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Appendix E PROCESS, RELEASE AND OCCUPATIONAL
EXPOSURE INFORMATION
This appendix provides information and data found in preliminary data identification and evaluation for
trans-1,2-dichloroethylene.
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.
E.l.1.1 Manufacture
1,2-Dichloroethylene can be produced by direct chlorination of acetylene at 40 degrees C. It is often
produced as a by-product in the chlorination of chlorinated compounds and recycled as an intermediate
for the synthesis of more useful chlorinated ethylenes. 1,2-Dichloroethylene can also be formed by
continuous oxychlorination of ethylene by use of a cupric chloride-potassium chloride catalyst, as the
first step in the manufacture of vinyl chloride (Snedecor, et al., 2004).
E.l.1.2 Import
Commodity chemicals such as trans- 1,2-Dichloroethylene may be imported into the United States in
bulk via water, air, land, and intermodal shipments (Tomer, 2015). These shipments take the form of
oceangoing chemical tankers, railcars, tank trucks, and intermodal tank containers. Chemicals shipped in
bulk containers may be repackaged into smaller containers for resale, such as drums or bottles.
Domestically manufactured commodity chemicals may be shipped within the United States in liquid
cargo barges, railcars, tank trucks, tank containers, intermediate bulk containers (IBCs)/totes, and drums.
Both imported and domestically manufactured commodity chemicals may be repackaged by wholesalers
for resale; for example, repackaging bulk packaging into drums or bottles. The type and size of container
will vary depending on customer requirement. In some cases, QC samples may be taken at import and
repackaging sites for analyses. Some import facilities may only serve as storage and distribution
locations, and repackaging/sampling may not occur at all import facilities.
In the 2016 CDR, one company reported importing a formulation containing less than 1 percent trans-
1,2-dichloroethylene (U.S. EPA, 2016).
E.1.2 Processing and Distribution
E.l.2.1 Processing as a Reactant or Intermediate
Processing as a reactant or intermediate is the use of trans-1,2-dichloroethylene as a feedstock in the
production of another chemical via a chemical reaction in which trans- 1,2-dichloroethylene is consumed
to form the product. EPA has not identified specific process information for the processing of trans- 1,2-
dichloroethylene as a reactant but EPA plans to evaluate this condition of use during the risk evaluation.
E.l.2.2 Incorporation into Formulation, Mixture, or Reaction Product
Incorporation into formulation, mixture or reaction product refers to the process of mixing or blending
of several raw materials to obtain a product or mixture, trans- 1,2-Dichloroethylene can be incorporated
into solvents for cleaning or degreasing, adhesives and sealants, foam blowing additives, and as a carrier
solvent in other product formulations.
78
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Formation processes specific to trans-1,2-dichloroethylene were not identified; however, several OECD
ESDs provide general process descriptions for some of these types of products. For example, adhesive
formulation involves mixing together volatile and non-volatile chemical components in sealed, unsealed
or heated processes (OECD, 2009). Sealed processes are most common for adhesive formulation
because many adhesives are designed to set or react when exposed to ambient conditions (OECD, 2009).
Lubricant formulation typically involves the blending of two or more components, including liquid and
solid additives, together in a blending vessel (OECD, 2004).
Incorporation into an article typically refers to a process in which a chemical becomes an integral
component of an article that is distributed for industrial, trade, or consumer use. Exact process
operations involved in the incorporation of trans-1,2-dichloroethylene are dependent on the article. EPA
plans to evaluate the potential use of trans- ] ,2-dichloroethylene in this type of process during the risk
evaluation.
trans-],2-Dichloroethylene is a component in vapor degreasing formulations. Section E.1.3.1 and
Section E. 1.3.2 provide example process description for batch vapor degreasing systems.
In batch open top vapor degreasers (OTVDs), a vapor cleaning zone is created by heating the liquid
solvent in the OTVD causing it to volatilize. Workers manually load or unload fabricated parts directly
into or out of the vapor cleaning zone. The tank usually has chillers along the side of the tank to prevent
losses of the solvent to the air. However, these chillers are not able to eliminate emissions, and
throughout the degreasing process significant air emissions of the solvent can occur. These air emissions
can cause issues with both worker health and safety as well as environmental issues. Additionally, the
cost of replacing solvent lost to emissions can be expensive (NEWMOA, 2001). Figure_Apx E-l
illustrates a standard OTVD.
E.l.2.3 Incorporation into Articles
E.1.3 Uses
E.l.3.1 Batch Open-Top Vapor Degreasing
Condensing Coils
Vapor Zone
.Water Jacket
[ater Separator
O
Boiling sump
IX
Jf
Heat Source
Figure Apx E-l. Open Top Vapor Degreaser
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OTVDs with enclosures operate the same as standard OTVDs except that the OTVD is enclosed on all
sides during degreasing. The enclosure is opened and closed to add or remove parts to/from the machine,
and solvent is exposed to the air when the cover is open. Enclosed OTVDs may be vented directly to the
atmosphere or first vented to an external carbon filter and then to the atmosphere (U.S. EPA, ICF
Consulting, 2004). FigureApx E-2 illustrates an OTVD with an enclosure. The dotted lines in
FigureApx E-2 represent the optional carbon filter that may or may not be used with an enclosed
OTVD.
—I
Carbon Filter
-vent
Loading/
unloading
lock
Boiling su
Heat Sou
[
np-
ce-
Vapor Zone
¦s
z;
]
Wate
Condensing Coils
Jacket
er Separator
Figure Apx E-2. Open Top Vapor Degreaser with Enclosure
E.l.3.2 Batch Closed-Top Vapor Degreasing
In closed-loop degreasers, parts are placed into a basket, which is then placed into an airtight work
chamber. The door is closed, and solvent vapors are sprayed onto the parts. Solvent can also be
introduced to the parts as a liquid spray or liquid immersion. When cleaning is complete, vapors are
exhausted from the chamber and circulated over a cooling coil where the vapors are condensed and
recovered. The parts are dried by forced hot air. Air is circulated through the chamber and residual
solvent vapors are captured by carbon adsorption. The door is opened when the residual solvent vapor
concentration has reached a specified level (Kanegsberg, 2011). Figure Apx E-3 illustrates a standard
closed-loop vapor degreasing system.
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Vent
Solvent Abatement Loop
Refrigeration
Distillation
Solvent Sump
Electric Heat
Solvent Tank(s)
Working Chamber
Workload
FigureApx E-3. Closed-Loop/Vacuum Vapor Degreaser
Airless degreasing systems are also sealed, closed-loop systems, but remove air at some point of the
degreasing process. Removing air typically takes the form of drawing vacuum but could also include
purging air with nitrogen at some point of the process (in contrast to drawing vacuum, a nitrogen purge
operates at a slightly positive pressure). In airless degreasing systems with vacuum drying only, the
cleaning stage works similarly as with the airtight closed-loop degreaser. However, a vacuum is
generated during the drying stage, typically below 5 torr (5 mmHg). The vacuum dries the parts and a
vapor recovery system captures the vapors (Kanegsberg, 2011; NEWMOA, 2001; U.S. EPA, 2001).
Airless vacuum-to-vacuum degreasers are true "airless" systems because the entire cycle is operated
under vacuum. Typically, parts are placed into the chamber, the chamber sealed, and then vacuum
drawn within the chamber. The typical solvent cleaning process is a hot solvent vapor spray. The
introduction of vapors in the vacuum chamber raises the pressure in the chamber. The parts are dried by
again drawing vacuum in the chamber. Solvent vapors are recovered through compression and cooling.
An air purge then purges residual vapors over an optional carbon adsorber and through a vent. Air is
then introduced in the chamber to return the chamber to atmospheric pressure before the chamber is
opened (Durkee, 2014, NEWMOA, 2001). The general design of vacuum vapor degreasers and airless
vacuum degreasers is similar as illustrated in Figure Apx E-3 for closed-loop systems except that the
work chamber is under vacuum during various stages of the cleaning process.
E.l.3.3 Aerosol Degreasing
Aerosol degreasing is a process that uses an aerosolized solvent spray, typically applied from a
pressurized can, to remove residual contaminants from fabricated parts. A propellant is used to
aerosolize the formulation, allowing it to be sprayed onto substrates. The aerosol droplets bead up on the
fabricated part and then drip off, carrying away any contaminants and leaving behind a clean surface.
Similarly, aerosol lubricant products use an aerosolized spray to help free frozen parts by dissolving rust
and leave behind a residue to protect surfaces against rust and corrosion.
Figure Apx E-4 illustrates the typical process of using aerosol degreasing to clean components in
commercial settings. One example of a commercial setting with aerosol degreasing operations is repair
shops, where service items are cleaned to remove any contaminants that would otherwise compromise
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the service item's operation. Internal components may be cleaned in place or removed from the service
item, cleaned, and then re-installed once dry (U.S. EPA, 2014).
&& 0
FigureApx E-4. Overview of Aerosol degreasing
Aerosol degreasing may occur at either industrial facilities or at commercial repair shops to remove
contaminants on items being serviced. Aerosol degreasing products may also be purchased and used by
consumers for various applications.
E.l.3.4 Industrial and Commercial Cleaning and Furniture Care Products
In the 2016 CDR, one company reported commercial use in cleaning and furniture care products at a
concentration of at least 90 percent (U.S. EPA, 2016). EPA has not identified specific process
information for the use of cleaning and furnishing care products containing Wans-1,2-dichloroethy 1 ene
but EPA plans to evaluate this condition of use during the risk evaluation.
E.l.3.5 Anti-Adhesive Agent
Safety data sheets reported transA,2-dichloroethylene use in mold release agents, ranging from 25 to 80
percent in formulation (Allied, 2018; Miller-Stephenson, 2016 a, b). Separately, a product data sheet for
an aerosol cleaning aid and lubricant also indicated potential use as a mold release agent (Rainbow
Technology, undated); therefore, aerosol use is possible. EPA has not identified specific process
information for the use of mold release agents containing trans-1,2-di chl oroethy 1 ene but EPA plans to
evaluate this condition of use during the risk evaluation.
E.l.3.6 Lubricants and Greases
A safety data sheet reported use trans-],2-dichloroethylene in a cleaning aid and lubricant, between 15
and 40 percent concentration (Rainbow Technology, 2019). The product data sheet indicate that it is
used as a spray cleaner/degreaser in various applications (Rainbow Technology, undated). Therefore,
this use may be similar use in aerosol degreasing. EPA plans to evaluate the potential use of trans-1,2-
dichloroethylene in this type of process during the risk evaluation.
E.l.3.7 Adhesives and Sealants
trans-] ,2-Dichloroethylene-specific adhesive or sealant uses were not identified. The OECD ESD for
Use of Adhesives (OECD, 2013) provides general process descriptions and worker activities for
industrial adhesive uses, which may include application by spray, brush, or roll coating. EPA plans to
evaluate this condition of use during risk evaluation.
E.l.3.8 Refrigerant and Refrigeration System Flush
Safety data sheets report a refrigerant containing up to 25.3 percent trans-1,2-di chl oroethy 1 ene (Opteon,
2016) and an air conditioning or refrigeration system flush treatment containing between 50 and 60
percent trans-] ,2-dichloroethylene (Ace, 2015). EPA has not identified specific process information for
82
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the use of refrigerants and refrigeration system flush treatments containing trans-1,2-dichloroethylene
but will investigate during risk evaluation.
E.l.3.9 Processing Aids
trans-} ,2-Dichloroethylene has potential use as an extraction solvent for rubber, dyes, perfumes,
lacquers, and thermoplastics. EPA has not identified specific process information for the use of
processing aids containing trans-1,2-dichloroethylene but EPA plans to evaluate this condition of use
during risk evaluation.
E. 1.3.10 Propellants and Blowing Agents
Safety data sheets list trans-1,2-dichloroethy 1 ene as a component of polyurethane polyol formulation
between 1 and 5 percent concentration (Demilec, 2017a; Demilec, 2017b). The 2004 Draft Generic
Scenario for Use of Additives in Foamed Plastics indicates that workers may potentially be exposed
during transferring components from shipping containers, operation/supervision of the foam mix head or
dispenser, during foam production, and transfer or handling of newly foamed articles (U.S. EPA,
2004a). EPA has not identified specific process information for the use of trans-1,2-dichloroethylene,
EPA plans to evaluate this condition of use during risk evaluation.
E.l.3.11 Laboratory Use
A safety data sheet for trans-1,2-dichloroethylene (>95% percent purity) indicates recommended use as
a laboratory chemical (ThermoFisher, 2018). However, specific laboratory use activities are unknown.
EPA plans to investigate the laboratory use of trans-1,2-di chl oroethy 1 ene during risk evaluation.
E.1.4 Disposal
Each of the conditions of use of trans-1,2-di chl oroethy 1 ene may generate waste streams of the chemical
that are collected and transported to third-party sites for disposal, treatment, or recycling. Industrial sites
that treat or dispose onsite wastes that they themselves generate will be assessed in each condition of use
assessment. Similarly, point source discharges of trans- ] ,2-dichloroethylene to surface water will be
assessed in each condition of use (point source discharges are exempt as solid wastes under RCRA).
Wastes of trans-1,2-dichloroethylene that are generated during a condition of use and sent to a third-
party site for treatment, disposal, or recycling may include the following:
• Wastewater: trans-1,2-Di chl oroethy 1 ene may be contained in wastewater discharged to POTW
or other, non-public treatment works for treatment. Industrial wastewater containing trans-1,2-
dichloroethylene discharged to a POTW may be subject to EPA or authorized NPDES state
pretreatment programs. The assessment of wastewater discharges to POTWs and non-public
treatment works of trans-1,2-dichloroethylene will be included in each of the condition of use
assessments.
• Solid Wastes: Solid wastes are defined under RCRA as any material that is discarded by being:
abandoned; inherently waste-like; a discarded military munition; or recycled in certain ways
(certain instances of the generation and legitimate reclamation of secondary materials are
exempted as solid wastes under RCRA). Solid wastes may subsequently meet RCRA's definition
of hazardous waste by either being listed as a waste at 40 CFR §§ 261.30 to 261.35 or by
meeting waste-like characteristics as defined at 40 CFR §§ 261.20 to 261.24. Solid wastes that
are hazardous wastes are regulated under the more stringent requirements of Subtitle C of
RCRA, whereas non-hazardous solid wastes are regulated under the less stringent requirements
of Subtitle D of RCRA.
83
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trans- l ,2-Dichloroethylene is a U-listed hazardous waste under code U227 under RCRA;
therefore, discarded, unused pure and commercial grades of Trans-1,2-Dichloroethylene are
regulated as a hazardous waste under RCRA (40 CFR § 261.33(f)). Additionally, trans-1,2-
dichloroethylene is included in multiple waste codes under the F-list of non-specific source
wastes (40 CFR § 261.31(a)).
• Wastes Exempted as Solid Wastes under RCRA: Certain conditions of use of trans-1,2-
dichloroethylene may generate wastes of trans-1,2-dichloroethylene that are exempted as solid
wastes under 40 CFR § 261.4(a). For example, the generation and legitimate reclamation of
hazardous secondary materials of trans-1,2-dichloroethylene may be exempt as a solid waste.
E.2 Sources Containing Potentially Relevant Data or Information
EPA plans to consider available data and information related to worker exposure and environmental
releases as they are identified during systematic review. Based on a preliminary data identification and
evaluation, there are no OSHA Chemical Exposure and Health Data (CEHD) or NIOSH Health Hazard
Evaluations specific to trans- l ,2-dichloroethylene.
84
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Appendix F
SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR INDUSTRIAL
AND COMMERCIAL ACTIVITIES AND USES
Table Apx F-l. Worker and Occupational Non-User Ex
josure Conceptual Model Supporting Table
l.ili ( \ik-
Shim-
Ri-k'iisi- /
l!\|)iisu iv
Sivn;irin
l!\|)osinv
I".\|)IISIIIV
Rimk-
Ri'ivphir /
Piipiikiliun
Pkilis In
l!\ ;illl;iU-
R;ilioil;ik-
Manufacturing
Domestic
manufacture
Import
Domestic
manufacture
Import
Manufacture
of trans-DCE
Repackaging
of import
containers
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Processing
Processing as a
reactant
Plating agents and
surface treating
agents
Intermediate in
chemical product
and preparation
manufacturing
Manufacture
of plating
agents and
surface
treating agents
Manufacture
of chemical
products and
other chemical
preparations
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
85
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l.ili-( \ik-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisuiv
I!\|)iisuiv
Ri'i'i'plin* /
I'hilis In
K;iliiill;ik-
Shim-
l';illi\\;i\
Kiiuk-
Piipuhiliiin
l!\ ;i In ilk-
Solvents (for
cleaning or
degreasing)
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Processing -
incorporation into
Solvents (which
become part of
product formulation
or mixture)
Formulation
of mixture and
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Processing
formulation,
mixture or
reaction product
Adhesives and
sealant chemicals
Foam blowing
additive
products
containing
trans-DCE
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Carrier solvent in
adhesives, coatings,
inks, lubricants, and
silicones.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Processing
Incorporation into
articles
Propellant and
blowing agent in
plastics product
manufacturing;
flexible
polyurethane foam
manufacturing
Plastics
product and
flexible
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
polyurethane
foam
manufacturing
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
86
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l.ili- < \ik-
Shim-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisuiv
l';illi\\;i\
I!\|)iisuiv
Kiiuk-
Ri'i'i'plin* /
Piipuhiliiin
I'hilis In
l!\ ;illl;iU-
K;iliiill;ik-
Processing
Repackaging
Recycling
Repackaging
Recycling
Repackaging
to large and
small
containers
Recycling of
trans-1,2,-
dichloroethyle
ne or solvents
containing
trans-1,2,-
dichloroethyle
ne
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Distribution in
commerce
Distribution in
commerce
Distribution in
commerce
Distribution of
bulk
shipments of
tras-DCE and
formulated
products
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, commercial use,
disposal) rather than as a single distribution
scenario.
Industrial/
commercial
use
Solvents (for
cleaning or
degreasing)
Vapor degreaser
Use of vapor
degreaser
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure. Exposure will depend
on the specific type of degreasing system.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure. Exposure will depend
on the specific type of degreasing system.
87
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l.ili ( \ik-
Shim-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisiiiv
l';illi\\;i\
I!\|)iisiiiv
Kiiuk-
Ri'i'i'plin* /
Piipukiliiiii
I'hilis In
l!\ ;illl;iU-
K;iliiill;ik-
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Industrial/
commercial
use
Solvents (for
cleaning or
degreasing)
Aerosol spray
cleaner/degreaser
Use of aerosol
spray cleaner /
degreaser
Mist
Inhalation
Worker
Yes
Known products are supplied in aerosol
cans, therefore, spray application is
expected.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Liquid
Contact
Dermal
Worker
Yes
Workers may have dermal exposure to
liquids when applying products containing
trans-DCE.
Industrial/
commercial
use
Solvents (for
cleaning or
degreasing)
Application of
flux removers
to substrates
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Flux remover
(liquid and aerosol)
Mist
Inhalation
Worker
Yes
Mist generation is possible for aerosol
products that are spray-applied.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
88
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Life ( \ik-
(;ili-»ur\
Slll>i;ili-»iir\
Ki-li-:isi- /
l!\|)iisu n-
Siviiiiriii
I!\|)iisuiv
I!\|)iisuiv
Ki-ivplm- /
Philis In
K;ilinn;ili-
Si un-
l';illi\\;i\
Kiiuli-
I'lipilhlliiili
l!\ ;ilu:ili-
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
commercial
use
Solvents (for
Use of
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
cleaning or
degreasing)
Refrigerant flush
refrigerant
flush
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Industrial/
commercial
use
Cleaning and
furniture care
products
Spot cleaner; stain
remover
Use of spot
cleaner / stain
remover for
textile
Mist
Inhalation
Worker
Yes
Stain/ink remover is spray applied to
textiles, therefore, EPA plans to evaluate
exposure to mist.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
89
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l.ili ( \ik-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisiiiv
I!\|)iisiiiv
Ri'i'i'plin* /
I'hilis In
K;iliiill;ili-
Shim-
l';illi\\;i\
Kiiuk-
Piipuhiliiiii
l!\ ;illl;iU-
Liquid
Contact
Dermal
Worker
Yes
Workers may have incidental dermal
exposure to liquids during 3D printing.
Industrial/
commercial
use
Smoothing fluid in
additive
manufacturing
Additive
manufacturing
(3D printing)
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Functional fluids
(open systems)
Mist
Inhalation
Worker
No
Mist generation is expected to be negligible
during 3D printing.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Industrial/
commercial
use
Use of mold
release
products
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Anti-adhesive
agent
Mold release
Mist
Inhalation
Worker
Yes
Some known products are applied via
aerosol cans, therefore, spray application is
expected.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
90
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l.ili ( \ik-
Shim-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisiiiv
l';illi\\;i\
I!\|)iisiiiv
Kiiuk-
Ri'i'i'plin* /
Piipukiliiiii
I'hilis In
l!\ ;illl;iU-
K;iliiill;ik-
Industrial/
commercial
use
Solvents (which
become part of
product
formulation or
mixture)
Urethane coatings
Application of
urethane
coating
Liquid
Contact
Dermal
Worker
Yes
Workers may have dermal exposure to
liquids when applying products containing
trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Mist
Inhalation
Worker
Yes
Mist generation is possible for aerosol
products that are spray-applied.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure to vapor.
Industrial/
commercial
use
Lubricants and
greases
Liquid and spray
lubricants and
greases, and
penetrating
lubricants
Use of aerosol
degreaser/clea
ner
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Mist
Inhalation
Worker
Yes
Some known products are applied via
aerosol cans, therefore, spray application is
expected.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
91
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l.ili ( \ik-
Shim-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisiiiv
l';illi\\;i\
I!\|)iisiiiv
Kiiuk-
Ri'i'i'plin* /
Piipukiliiiii
I'hilis In
l!\ ;i In ilk-
K;ili
-------
l.ili ( \ik-
Shim-
(;iU-»ur\
Ri-k'iisi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisiiiv
l';illi\\;i\
I!\|)iisiiiv
Kiiuk-
Ri'i'i'plin* /
Piipukiliiiii
I'hilis In
l!\ ;illl;iU-
K;iliiill;ik-
Industrial/
commercial
use
Processing aids
Extraction solvent
for thermoplastics
Use of
processing
solvent in
industrial
applications
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Commercial
use
Propellants and
blowing agents
Polyurethane foam
building insulation
Application of
Polyurethane
Foam
Insulation
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Mist/Partic
ulate
Inhalation
Worker
Yes
Several polyurethane foam products are
designed to be spray-applied
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Industrial/
commercial
use
Other use
Laboratory
chemicals
Use of
laboratory
chemicals
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
93
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Life ( >ill-
Si ;i»i-
(;ili-»ur\
Slll>i;ili-»iir\
Ki-li-:isi- /
l!\|)iisu iv
Siviiiiriii
I!\|)iisuiv
l>;illi\\;i\
I!\|)iisuiv
Kiiuli-
Ri-ivpliir /
I'lipilhlliiili
I'lilllS III
l!\ ;ilu:ili'
K;ilinn;ili'
Liquid
Contact
Dermal
Worker
Yes
Workers are expected to routinely handle
liquids containing trans-DCE.
Worker
Vapor
Inhalation
Worker
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Disposal
Disposal
Disposal
handling of
wastes
Liquid
Contact
Dermal
ONU
No
Dermal exposure is expected to be primarily
to workers who directly handle the
chemical.
Vapor
Inhalation
ONU
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
94
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Appendix G SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR CONSUMER
ACTIVITIES AND USES
Table Apx G-l. Consumer Exposure Conceptual Model Supporting Table
Life ( .\clc
S(;i»c
Csili'Sion
Siibciileiion
Kck'sisi* from
sou ive
l'l\|)OSIIIV
Kniili'
Km*|)lor
Pliins In
Kill ioiiiilc
Liquid
Contact
Dermal
Consumers
Yes
Consumers can potentially handle liquids
containing trans-1,2-dichloroethylene.
Solvents (for
cleaning or
degreasing)
Aerosol spray
cleaner/degreaser
Use of aerosol spray
cleaner / degreaser
Vapor
Inhalation
Consumer,
Bystanders
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Mist
Inhalation
Consumer,
Bystanders
Yes
Known products are supplied in aerosol cans,
therefore, spray application is expected.
Cleaning and
furnishing care
products
Liquid
Contact
Dermal
Consumers
Yes
Consumers can potentially handle liquids
containing trans-1,2-dichloroethylene.
Consumer
Use;
Consumer
Spot cleaners; stain
removers
Use of spot cleaners;
stain removers
Vapor
Inhalation
Consumer,
Bystanders
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Reuse and
Recycling
Mist
Inhalation
Consumer,
Bystanders
Yes
Known products are supplied in aerosol cans,
therefore, spray application is expected.
Liquid
Contact
Dermal
Consumers
Yes
Consumers can potentially handle liquids
containing trans-1,2-dichloroethylene.
Adhesives and
Sealants
Solvent-based;
adhesives accelerant
Use of solvent-
based; adhesives
accelerant
Vapor
Inhalation
Consumer,
Bystanders
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure.
Mist
Inhalation
Consumer,
Bystanders
Yes
Known products are supplied in aerosol cans,
therefore, spray application is expected.
Propellants and
blowing Agents
Polyurethane foam
building insulation
Off-gassing of trans-
1,2-dichloroethylene
from polyurethane
foam insulation
Vapor
Inhalation
Consumer,
Bystanders
Yes
Due to high volatility (331 mmHg at room
temperature), EPA plans to evaluate
inhalation exposure
95
-------
Appendix H SUPPORTING INFORMATION - CONCEPTUAL MODEL FOR
ENVIRONMENTAL RELEASES AND WASTES
Table Apx H-l. General Population and Environmental
xposure Conceptual Model Supporting Table
l.il'o ( \ck'
S(;i»e
Kck'sisi*
r.\|)ONIMY
I\i(Iin;i\ /
Modiii
l'l\|)UMIIV
Koii les
Km'plor /
Population
PlilllS lo
Kiilioiiiik-
All
Emissions to
Air
Emissions to Air
Near facility
ambient air
concentrations
Inhalation
General
Population
Yes
Traiib-l,2-dicliloroolh>loiio ambient air
and deposition to nearby bodies of water
and soil are expected exposure pathways,
not covered under other EPA regulations
Indirect
deposition to
nearby bodies
of water and
soil catchments
Oral
Dermal
General
Population
Yes
TBD
Aquatic and
Terrestrial
Receptors
Yes
Hazardous and
Municipal Waste
Incinerator
Near facility
ambient air
concentrations/
Indirect
deposition to
nearby bodies
of water and
soil catchments
Inhalation
General
Population
No
Stationary source releases of trans-1.2-
dichloroclhylcne to ambient air arc under
the jurisdiction of the RCRA and CAA.
TBD
Aquatic and
Terrestrial
Species
Wastewater
or Liquid
Wastes
Industrial pre-
treatment and
wastewater
treatment, or POTW
Direct release
into surface
water and
indirect
partitioning to
sediment
TBD
Aquatic and
Terrestrial
Receptors
Yes
EPA has developed Ambient Water
Quality Criteria for protection of human
health for trans-1,2-dichloroethylene
Oral
Dermal
General
Population
No
8 The exposure pathways, exposure routes and hazards EPA 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 trans-l,2-dichloroethylenein exposure pathways falling under the jurisdiction of these EPA statutes.
96
-------
l.il'o ( \ck'
S(;i»o
C;iU'ii»n
Release
I'1\|)osiiiv
Pillliw il> /
Media
l'l\|)UMIIV
Koii les
Reeeplor /
Population
Plans lo
l.\aluak,s
Rationale
1 )riiikiim Wiilcr
\ ki Surface or
(iioinid \\';iler
()ral
Dermal and
1 llllllllll Kill
(e u
showernm)
(leneral
l\
------- |