TLV and BEI Committees:

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Title: TLV and BEI Committees:

1

TLV and BEI Committees
The Decision Making Process
Presented at AIHce
May 13, 2003, Dallas, TX
Bill Wells PhD, CIH, CSP, Moderator
Dennis Casserly, PhD, CIH Marilyn Hallock, CIH
Monitors

2
Forum Overview

Pat Breysse Introduction
Lisa Brosseau TLV-CS Committee
Larry Lowry BEI Committee
Tom Bernard TLV-PA Committee
Ken Martinez Bioaerosols Committee

3
ACGIH, the TLVs and BEIs

Patrick N. Breysse, PhD, CIH
Johns Hopkins University
Bloomberg School of Public Health
Chair, ACGIH

4
What Is ACGIH?

Membership Society (founded in 1938)
Not-for-profit, Non-governmental Association
(501(c)(6) organization)
Multi-Disciplinary Membership
Traditionally Neutral on Public Positions

5
MembershipApril 2003
Government Academia
Private Industry Others
6
Membership by Profession, 2003
7
Technical Committees
Committees provide the creativity, initiative,
and technical expertise that has made ACGIH what
it is today and what it will be tomorrow. .
8
Core Mission
9
ACGIH Statement of Position

ACGIH is not a standards setting body.
TLVs and BEIs
Are an expression of scientific opinion.
Are not consensus standards.
Are based solely on health factors it may not be
economically or technically feasible to meet
established TLVs or BEIs.

10
ACGIH Statement of Position

TLVs and BEIs
Should NOT be adopted as standards without an
analysis of other factors necessary to make
appropriate risk management decisions.
Can provide valuable input into the risk
characterization process. The full written
Documentation for the numerical TLV or BEI
should be reviewed.

11
Conflict of Interest

Basis for Conflicts of Interest
Employment
Financial benefit
Personal
Professional
Avoid perceived as well as real conflict of
interest

12
Conflict of Interest

Committee members serve as individuals
they do not represent organizations and/or
interest groups
Members are selected based on expertise,
soundness of judgement, and ability to contribute

13
COI Process at ACGIH
14
Todays Roundtable

Chemical Substances - TLV
Biological Exposure Indices (BEI)
Physical Agents TLV
Bioaerosols Committee

15
ACGIH TLVs for Chemical Substances Committee
Update

Chair Lisa M. Brosseau, ScD, CIH
Associate Professor
University of Minnesota
School of Public Health

16
Overview

TLV-CS Committee has 20 members and 3
member-candidates, who volunteer time towards
developing scientific guidelines and publications
Primary goal is to serve the scientific needs of
industrial hygienists
Committee expenses (travel) are supported by
ACGIH
Time is donated by the members

17
Committee Structure

Chair and Vice Chair
Three Subcommittees, Chair and Co-Chair
Dusts Inorganics (DI)
Hydrogen, Oxygen Carbon Compounds (HOC)
Miscellaneous Compounds (MISCO)
Administrative Subcommittees
Communications and Outreach
Membership
Notations
Chemical Substance Selection
Staff Support
Liaison, Clerical, Literature Searching

18
Chemical Substance Subcommittees

Approximately 10 members on each
Membership from academia, government, unions,
industry
Membership represents four key disciplines
Industrial hygiene
Toxicology
Occupational Medicine
Occupational Epidemiology

19
Core TLV Principles

Focus on airborne exposures in occupational
settings
Utilize the threshold concept
Primary users are industrial hygienists
Goal is towards protection of nearly all workers

Technical, economic, and analytic feasibility are
NOT considered
20
Committee Actions in 2003

Adopted TLVs for 22 substances
Proposed 6 new TLVs
(listed on the Notice of Intended Changes (NIC))
Revised 7 adopted TLVs (listed on the NIC)
Proposed withdrawing TLVs for methane, ethane,
propane, butane and liquified petroleum gas.
(Will also withdraw iso-butane.)
All to be replaced with a proposal for Aliphatic
Hydrocarbon Gases, Alkane (C1-C4)
Revised 3 proposals for TLVs and retained on the
NIC

21
Committee Actions in 2003 (Contd)

Adopted a new Appendix E for Particulates
(Insoluble or Poorly Soluble) Not Otherwise
Specified (PNOS)
Developed new Documentation for 2 substances (no
change in values)
Changed the name of one TLV and kept on the NIC
with revised recommendations
Retained 4 proposed TLVs on the NIC
Withdrew 2 proposed TLVs from the NIC

22
Committee Actions in 2003 (Contd)

Proposed withdrawal of Appendix B Substances of
Variable Composition
Proposed revision of Appendix C Threshold Limit
Values for Mixtures
Proposed a new Appendix F Commercially Important
Tree Species Identified as Inducing Sensitization

23
Substances and Issues Under Study in 2003

115 chemical substances currently under study
Issues under study include
Ceiling limits, excursions, and STELs
Notations for reproductive effects
Skin notation
Reciprocal Calculation Procedure, Group Guidance
Values for refined C5 - C15 aliphatic and
aromatic hydrocarbon solvents and constituent
chemicals

24
Particulates (Insoluble or Poorly Soluble) Not
Otherwise Specified

The recommendations are guidelines (not TLVs)
for limiting exposure to insoluble particles
3 mg/m3 (respirable)
10 mg/m3 (inhalable)
Apply to particles that
Do not have a TLV
Are insoluble or poorly soluble in water or lung
fluid
Have low toxicity (not genotoxic, cytotoxic,
etc.)
Only toxic effects are inflammation or lung
overload mechanisms

25
ProposedNew Appendix C TLVs for Mixtures

In the absence of other information, assume
additivity of substances having similar effects
Same outcomes, same target organs or systems

the TLV for the mixture has been exceeded.
26
ProposedNew Appendix C TLVs for Mixtures

Recommends using the TLV Documentation, as well
as the TLV Basis information in the book
Where possible, only combine TLVs having a
similar time basis
Table showing appropriate combinations of
different types of TLVs

27
ProposedNew Appendix C TLVs for Mixtures

Limitations and Special Cases
Do not use when suspect inhibition or synergism
Take care when considering mixtures of A1, A2, or
A3 carcinogens
Not appropriate for complex mixtures with many
different components (e.g., gasoline, diesel
exhaust)

28
Committee Activities

Notations
Complete re-write of Introduction to the TLV-CS
section of the book
Improved definition and categorization of TLV
Basis
Communications
Symposia on substances under study
Membership
Recruitment, especially of physicians and
epidemiologists
Bill Wagner Award member recognition
Chemical Substance Selection
Refining the selection process

29
Committee Activities

Sponsored symposium on TDI (Spring 2002)
Attended ACGIH symposium on oil mists and
metalworking fluids (Fall 2002)
Plenary talk on TLVs at AIOH in Australia
(Winter 2002)
Co-sponsored a colloquium on Workplace Chemical
Exposure Standards with IRSST in Montreal (Spring
2003)

30
Committee Plans

Co-sponsor symposium on enzymes (Spring 2004)
Roundtables on TLVs at other professional
meetings (SOT, ACOEM)
Joint meetings with ACGIH BEI and AIHA WEEL
Committees

31
Questions?
32
Scheduled Break

Take a minute to stretch!

33
Biological Exposure Indices (BEIs)Process and
Use

Larry K. Lowry, Ph.D.
Chair, ACGIH BEI Committee
The University of Texas Health Center at Tyler

34
Where are we going today?

Current definitions of the BEI, 2002
The development of BEIs
The key Documentation
Examples
Biomonitoring without limits
Current and future issues
Resources

35
Biological monitoring. Why?

Assess exposure and uptake by all routes
TLV not protective skin
Includes workload
More closely related to systemic effects
Assess effectiveness of PPE
Legal or ethical drivers
Regulations
Control workers compensation costs

36
Guidelines for biological
monitoring The BEIs
37
The BEIs 2003

BEIs are intended for use in the practice of
industrial hygiene as guidelines or
recommendations to assist in the control of
potential workplace health hazards and for no
other use.

38
The BEI Definition

Biological monitoring entails measurement of
the concentration of a chemical determinant in
the biological media of the exposed and is an
indicator of the uptake of the substance.
The BEI determinant can be the chemical itself
one or more metabolites or a characteristic
reversible biochemical change induced by the
chemical.

39
BEIs

Represent levels of determinants that are most
likely to be observed in specimens collected from
a healthy worker who has been exposed to
chemicals to the same extent as a worker with
inhalation exposure to the TLV-TWA.
Generally indicate a concentration below which
nearly all workers should not experience adverse
health effects.

40
Current basis for BEIs

Bio-equivalent to TLV (traditional)
BEIs represent levels of determinants that are
most likely to be observed in specimens collected
from a healthy worker who has been exposed to
chemicals to the same extent as a worker with
inhalation exposure to the TLV-TWA.
Most of the BEIs are based on TLVs

41
Current basis

Indicators of early, reversible health effect
Approach developed in late 80s as relationships
did not always exist between airborne exposure
and biomonitoring determinant.
Examples
CO, Acetyl cholinesterase inhibiting pesticides,
Cd, Pb, Hg, Hexane-MnBK

42
The BEI Committee Larry Lowry, Ph.D., U TX
Health Center at Tyler Chair

Phil Edelman, MD, CDC Vice Chair
Mike Morgan, Sc.D, CIH, U. of WA Past Chair
Joe Saady, Ph.D., VA Division of Forensic Science
Leena Nylander-French, Ph.D, CIH, UNC, Chapel
Hill
John Cocker, Ph.D., HSE, UK
K. H. Schaller, Dipl. Ing., Univ Erlangen,
Germany
M. Ikeda, Ph.D., Kyoto Ind Health Assoc, Japan
Gary Spies, CIH, Pharmacia
Glenn Talaska, Ph.D., CIH, Univ of Cincinnati
Jan Yager, Ph.D., EPRI

43
BEI development

Volunteer assigned document
Prepares draft Documentation
Sources of data
Human laboratory workplace data
Limited use of animal data
Simulation modeling with verification
Published peer-reviewed data
Draft Documentation discussed in committee
meetings, e-mail

44
Development Process
45
How are chemicals selected?

Chemicals with human data
Potential for dermal absorption
Availability of adequate lab methods
Recommendations by others
Interest/experience of committee member

46
The Documentation

Who is the audience?
The practicing occupational hygienist or other
practicing occupational health professional
What the Documentation is
Justification supporting the BEI
Practical information on sampling, background,
etc.
What the Documentation is not
An extensive review of toxicological data
A novel research approach to setting guidelines

47
The Documentation contents

Basis of the BEI
Uses and properties
Absorption
Elimination
Metabolic pathways biochemical interactions
Possible non-occupational exposure
Summary of toxicology

48
For each index or BEI

Analytical methods, sampling, and storage
Levels without occupational exposure
Kinetics
Factors affecting interpretation
Analytical procedures and sampling
Exposure
Population
Justification the key
Current quality of database
Recommendations and references

49
The notations

B - Background levels expected
Nq- Nonquantitative
Biol. monitoring recommended, no BEI
Ns- Non-Specific
Needs confirmation
Sq Semiquantitative (but specific)
Screening test
Confirmatory tests

50
Practical applications

Bioavailability of metals Chromium
Chromium VI (water soluble) fume
Specificity and Sensitivity Benzene
biomonitoring
t,t-Muconic acid in urine (t,t-MA)
S-Phenylmercapturic acid in urine (SPMA)

51
Bioavailability of metals Chromium

Physical properties and solubility
Cr (III), very insoluble particulates
Cr (VI) insoluble particulate the lung
carcinogen
Cr (VI) water soluble
Fume as generated in MMA arc welding
Mist as generated in electroplating
Health effects of Cr (VI) water soluble
Fume lung irritant
Mist chrome ulcers on skin, mucus membranes

52
Biological monitoring of Cr exposure

Cr (III) inappropriate not bioavailable
Cr (VI) insoluble not bioavailable
Cr (VI) water soluble
If fume, use BEI based on welding studies
If mist, bioavailability less
See chrome ulcers at acceptable BEI values

53
Biomonitoring of benzene
54
Biomonitoring at the current TLV

t,t-Muconic acid in urine (t,t-MA)
Good sensitivity (to 0.1 ppm benzene)
HPLC methodology
Considerable variability in populations
S-Phenylmercapturic acid in urine (SPMA)
Ultimate sensitivity (to 0.01 ppm benzene)
GC/MS methodology
Good data base, but expensive

55
Biological monitoring without limits

What about substances absorbed through the skin
and with chronic systemic health effects that
occur after a long lag time such as cancer?

56
The traditional approach

Cannot relate to airborne limits, TLVs
Irrelevant
Cannot relate to skin absorption
Difficult to quantitate dermal dose
Cannot relate to health effect
Often wrong timeline
What to do?

57
The BEI approach

Rationale
Biological monitoring is essential to assess
dermal exposure
How do you correlate dermal dose with a biomarker
of exposure?
Nq Approach
Biological monitoring should be considered for
this compound based on the review however, a
specific BEI could not be determined due to
insufficient data.

58
Criteria for an Nq

Dermal route of exposure significant
Good measurement methods
Good qualitative data on human exposure and
biomarker concentration
Poor quantitative data relating exposure
biomarker
Long lag time, exposure to health outcome
Low or no background in general population

59
If criteria are met, then

Develop full Documentation
Describe sampling and analysis
Define background levels
Describe justification for biomonitoring
Note the lack of quantitative data
Cite guidance values from literature
Publish BEI as Nq (no value)

60
Examples MBOCA

Principal route of exposure dermal
Alleged health effect in humans cancer
Good methods and human data on exposure-response
Industry practice guidance from the HSE

61
Health and Safety Executive, UK

Scientific basis to justify guidance values
Use "yardstick or benchmark" approach
Issues
Results no "safe" or "unsafe" exposure levels
Results estimates of exposure areas and allow
intervention to reduce exposures
No legal status
Examples MBOCA and MDA

62
The yardstick or benchmark approach

Good analytical methods
All specimens analyzed by one laboratory or with
a single method
Establish "best industry practice" using an
upper 90 confidence limit of the "best"
industries
Benchmarks guidance value to provide users with
assessment of their results

63
Current issues

Carcinogens?
Is there a safe level of exposure?
The German EKA approach
Mixtures and interactions
Metabolism/toxicokinetics on pure chemical
Workers exposed to mixtures
How does this effect BEI?
Biomarkers of effect irreversible effects?
Data gaps lack of human data
Animal data should this be used?

64
Skin absorption Justification for BEI

Existing BEIs for substances with substantial
skin absorption
MBOCA Nq
EGME/EGMEA Nq
EGEE/EGEEA 100 mg/g creatinine
(based on TLV of 5 ppm)
Is this a valid approach?
Are Nq notations appropriate?
Should a chemical without a skin notation have
a BEI?

65
The future

As TLVs drop, BEIs based on TLVs drop
Cannot distinguish exposure at TLV from
background
What do we do for substances that have no human
data?
What is the future of modeling techniques?
Can these modeling techniques be validated?
Should animal data be used?
What about mixtures?

66
Other guidelines
67
GermanyThe BATs from the DFG
68
The HSE UK Biological monitoring guidelines
69
Guidance from WHO How to do biological
monitoring
70
Other GuidelinesNew edition, 2001
71
Your questions please
Thank you for your attention
72
Scheduled Break

Take a minute to stretch!

73
ACGIH TLVs for Physical Agents Committee Update

Vice-Chair Thomas Bernard
University of South Florida
College of Public Health

74
TLVPhysical Agents Committee

Process for Hazardous Agent Selection and
Decision Making

75
Mission

To foster, solicit, collect and evaluate data on
potential health hazards of exposures to physical
agents. When appropriate, recommend ACGIH
Threshold Limit Values for physical agents.

76
2002 PAC

Harry Mahar
Maurice Bitran
Thomas Bernard
Gerald Coles
Anthony Cullen
Daniel Johnson
John Leonowich
William Murray
Bhawani Pathak

Robert Patterson Thomas Tenforde Carla
Treadwell Consultants Thomas Adams Thomas
Armstrong Gregory Lotz Martin Mainster Gary Myers
77
Overview

Physical Agents
Process
Committee Activities
TLV Development
Future
Format
Agents

78
Disclaimer

The opinions expressed here are those of the
author
and not of
his employer,
the Physical Agents Committee or
the ACGIH Worldwide.

79
Physical Agents

Its the Movement of Energy

80
Risk of Health Effects

What is the nature of the energy?
How much energy?
What is the interaction with tissue?

81
Nature of Energy

Electric and Magnetic Fields
Photons
Kinetic Energy
Pressure
Vibration
Mechanical
Heat

82
Amount of Energy

Total Amount of Energy Absorbed
What does it take to raise water temperature?
Rate of Absorption (Power or Intensity)
How fast does the temperature rise?
Normalized to Surface Area
(e.g., mJ/cm2, mW/cm2)

83
Interactions

Electric and Magnetic Fields
Induce Currents
Align Molecules
Vibrate Molecular Bonds
Photons
Vibrate Molecular Bonds
Disrupt Molecular Bonds

84
More Interactions

Mechanical Disruption of Tissue
Pressure
Vibration
Force Applications
Loss of Tissue Function
Thermal Gain or Loss of Heat

85
Bernard Watt-O-Meter
Not Accepted, or Considered Acceptable, by Any
Authority

Power Limits for Various Exposures mW/cm2
Electric and Magnetic Fields 170,000
Radiofrequency/Microwave 1.0
Infrared Light 10
Blue Light 0.0001
Ultraviolet Light 0.0012
Ionizing Radiation 0.00000003
Noise 0.00003
Heat Stress 30

86
Exposure

Energy Distribution in the Immediate Environment
The distribution is usually described as Power or
Intensity (directly or through a surrogate)
versus Frequency or Wavelength in Bands

87
Exposure Threshold

Total Energy
Ability to Absorb Energy
Rate of Energy (Power or Intensity)
Ability to Dissipate Absorbed Energy
In a Band
Integrated Over All Bands

88
Process

Committee Activities
Development of TLVs

89
Representation

Usually one or two members with an expertise for
a particular agent (e.g., a small portion of the
electromagnetic spectrum)
Small committee to maintain a working and
collegial group. We meet as a whole.
Leverage with outside experts

90
Updating TLVs

PAC meets with outside experts
Members bring recommendations to the PAC for
discussion
Consideration of actions taken by national and
international committees or agencies

91
New TLVs

Quintessential Example Hand Activity
Formed a cadre of consultants
Convened a conference
Developed recommendation and Documentation
Presented to PAC and discussed
PAC voted after internal deliberations

92
Future

Format
Agents

93
Format

TLV Book
Use of Flow Charts
Evolving (see Heat Stress and RF/MW)
Training
Documentation
Expanded and Focused (see HAL and Lifting)
Health Effects and Exposure Indices
Guidance (see Heat Stress)

94
Form

Physical agents have their own history and
character with respect to measurement and
exposure assessment
There is an underlying similarity among the
physical agents that may be introduced

95
Example Set

Radiofrequency / Microwave Radiation
Optical Radiation (IR, Visible and UV)
Vibration (Hand-Arm and Whole Body)
Noise

96
Energy Distribution
97
Energy Limits Within Bands
Emin
98
Limits by Band
Is the limit exceeded within one or more bands?
99
Sensitivity Curve
Sensitivity Energy Limit / Emin
100
Hazard Function
Hazard Function 1.0 / Sensitivity
101
Effective Exposure
Effective Exposure Energy Distribution x Hazard
Function
102
Total Energy

Multiplying
Energy Limits by Band
Hazard Function by Band
and Integrating (Summing)
Yields a Constant Value
A Total Energy Limit

103
Limit by Total Energy

Total Energy
In One Band
Under the Effective Energy Curve
Compared to
Total Energy Limit

104
In Summary

TLVs
Limit Power (Ability to Dissipate)
Limit Total Energy (Ability to Absorb)
Limit by
Band
Total

105
Agents Under Review

Lasers
Vibration
Cold Stress

Altitude
Impulse Noise
ELF H-Fields

HAL
Lifting
WMSDs
Wide-Band RF

106
Scheduled Break

Take a minute to stretch!

107
Biologically Derived Airborne Contaminants
Bioaerosols and TLVs

Kenneth F. Martinez, MSEE, CIH
Chair, ACGIH Bioaerosols Committee
NIOSH

108
(No Transcript)
109
Where ?
110
Microorganisms

Obligate parasites (must have a living host)
viruses
bacteria
rickettsia
Facultative saprophytes (will utilize dead
organic material)
fungi
bacteria

111
Size Ranges of Microorganisms
112
Mechanisms for Microbial DispersalLinear
Distances
113
Microbiological Concerns

Infections
Immunologic Reactions
Toxic Effects

114
Infectious Disease

Pathogenicity
Virulence
Relationship between virulence (V), numbers of
pathogens or dosage (D), and resistant state of
the host (RS)
Colonization
Invasiveness

V D
Infectious Disease
RS
115
Infectious DiseaseTerminology

Portal of entry
Exposure vs. infection
Clinical vs. subclinical or asymptomatic
infection
Carrier state
Opportunistic infection
Human pathogen vs. virulence
Immunosuppression

116
Infectious DiseasePathways

Respiratory
Oral (via ingestion)
Contact
Penetration
Vectors (via insect bite)

117
Allergic Disease

Allergic rhinitis
Allergic asthma
Allergic bronchopulmonary aspergillosis
Extrinsic allergic alveolitis (hypersensitivity
pneumonitis)

118
U.S. Disease Prevalence

1 of 5 Americans suffer from allergic disease
Indoor allergens responsible for significant
share
Environmental control reduces disease severity

Source NHLBI, 1991
119
Source Pope AM, et al., eds., 1993
120
Important Mycotoxins
121
Where Are We?
122
Classification of Occupant Complaints

Sick Building Syndrome
Building-Related Disease
Occupant Discomfort

123
Sick Building SyndromeNon-specific Symptoms

Headache
Eye, nose, throat irritation
Sneezing
Fatigue and lethargy
Skin irritation
Dizziness and nausea
Cough
Chest tightness

124
Building-Related Disease

Known etiologies
Related to identifiable exposure

125
No numeric criteria for interpreting environmental
measurements!
126
Why Not Scientifically Supportable?
Total Culturable or Countable Bioaerosols