P ro d u c e d u n d e r C o u rt O rd e r in H a rt v , Owena C o rn in c
F ib e r o la a . e t a l. . USDC SD H is s : C o n fid e n tia l io f o r x e t io n ,
n o t t o o e c o p ie d , re p ro d u c e d o r d ie t r id u t e d e x c e p t in

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An
Information
Resource

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U.S. Department
of
Health,
Education,
and
Welfare
Public
Health
Service

National
Institutes
of
Health

PLAINTIFFS
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EXHIBIT

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01 061 0555

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This report was prepared under Contract NO-1-55176 by the
Stanford Research Institute International, Menlo Park, California,
for the Division of Cancer Control and Rehabilitation, National
Cancer Institute, as an informational and educational resource.
Acceptance of the report does not signify that the contents
necessarily reflect the official views or policies of the National
Cancer Institute, nor does mention of trade names or commercial
“aj^pro^ycts constitute endorsement or recommendation for use.

01 061 0556

An
Information
Resource

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National
Cancer
Institute

Division
of
Cancer
Control
and
Rehabilitation

Bethesda,
Maryland
U.S.
Department
of
Health,
Education,
and
Welfare

Richard J. Levine,
Editor

Public
Health
Service

w

National
Institutes
of
Health

-

•ip
“—

DHEW Publication Number
(NIH) 79-1681

o<*

May 1978

t

01 061 0557

fcr-

ACKNOWLEDGMENTS

SRI International (formerly Stanford Research Institute) acknowledges the

P ro d u c e d u n d e r C o u rt O ro e r

in H a rt v., Owens C o rn in c

F if a t r o U a . a t a l . , USDC SO H is s ; C o n f id e n t ia l in fo r m a tio n ,
n o t t o o e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t's o r d e r .

invaluable advice and assistance of the following individuals during the
preparation of this monograph on asbestos:
Henry Anderson, M.D.
Department of Environmental Medicine
Mount Sinai School of Medicine
New York, New York
Robert E. Baumann, Ph.D.
Professor of Engineering
Iowa State University
Ames, Iowa
Arnold Brown, M.D., Chairman
Department of Pathology and Anatomy
The Mayo Clinic
Rochester, Minnesota
Jean Spencer Felton, M.D.
Long Beach Naval Shipyard
Long Beach, California
Graham W. Gibbs, Ph.D., Director
Occupational Health and Safety Unit
Institute for Mineral Industry Research
McGill University
Montreal, Quebec, Canada
Philippe Shubik, M.D., Director
Eppley Institute for Research in Cancer
Omaha, Nebraska
ngwledged also are the many contributions from the staffs of SRI's
(Ranter for Occupational and Environmental Safety and Health, Center for
Resource and Environmental Systems Studies, Biorganic Chemical Department,
“^Minerals and Metals Center, and Center for Research on Stress and Health.

01 061 0558

CONTENTS

LIST OF ILLUSTRATIONS........................................................................................................

ix

LIST OF TABLES

...................................................................................................................

ix

FOREWORD.....................................................................................................................................

xi

ACKNOWLEDGMENTS......................................................................................................................

xiii

I

INTRODUCTION ..................................................................................................................

I

II

PRODUCTION AND USE OF ASBESTOS FIBERS AND PRODUCTS .....................

9

U.S. Consumption of Asbestos Fibers
..... ..............................
U.S. Production and Producers of Asbestos Fibers .........................
End Uses of Asbestos ..............................................................................................
Handling of Fiber and Products During Their Production . . .
Mining
............................................................................... .......
Milling .... ..............................................................................................
Transportation
..............................................................................................
Manufacture of Asbestos-Containing Products ......
Ill

BIOLOGICAL EFFECTS OF ASBESTOS FIBERS

.................................................

21

Disposition of Fibers in the Body...........................................................

21

Inhaled Asbestos......................................................
Ingested Asbestos .........................................................................................
Injected Asbestos ..................................................................... ....
"Asbestos Bodies" .........................................................................................

21
22
23
23

Carcinogenic Effects--Human Studies

-

.......................................................

23

Evidence of Lung Cancer . ..........................................................
Evidence of Mesothelioma...............................................................
Laryngeal Cancer
.........................................................................................
Digestive System Cancer ..........................................................................
Other Cancers..................................................................................................
-~SAFSOciation of Effects with Fiber Type...................................
^B'osC-Response Relationship................................................................
Jhe Cancer Latency Period .....................................................................
incidence of Cancer and Age at First Exposure
■—to Asbestos..................................................................................................
Smoking and Asbestos-Related Cancer .... .........................
Cancer from Incidental Occupational Exposure
....................
Disease in Workers' Households
......................................................
Cancer in the Neighborhood of Asbestos Facilities ...

24
25
25
26
26
26
27
29
29
30
31
32
32

iii

01 061 0559

III

BIOLOGICAL EFFECTS OF ASBESTOS FIBERS (Continued)

Carcinogenic Effects—Animal Studies
' ' Noncarcinogenic Effects of Asbestos
Asbestosis.................... .... ................................................................
Asbestos Pleural Effusion ......................................................................
Pleural Calcification, Diffuse Fibrosis,
and Plaques.........................................................................................
Asbestos Warts
..............................................................................................
Animal Studies--Evidence of Noncarcinogenic Effects . .

IV

34
37
37
38
38

OCCUPATIONAL EXPOSURES .........................................................................................

41

Exposures in Mining and Milling
.................................................................
Exposures in the Asbestos Products Industries
..............................

42
42

Friction Products............................................................................... .... .
Asbestos Paper
..............................................................................................
Asbestos-Reinforced Plastics
............................................................
Asbestos-Cement Pipe and Sheet..............................................
Floor Tile...............................................................................................
Asbestos Textiles .........................................................................................

43
45
45

P ro d u c e d u n d e r C o u rt o r d e r

•

in M a rt v , _ Owens C o rn in g
F ib e r o la a . a t a l . . USDC SO M is s : C o n fid e n tia l in f o r M t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

*

32
34

45
46

Exposures in the Utilization of Asbestos-Containing ProducSP*^.-

46
47

Insulation Trades....................................................................................... ■Eii'>*T47
Brake and Clutch Repair..................................................................... - 48
Installation of Floor Tile, Roofing, and Siding . . .
48
Use of Spackling, Patching, and Taping Compounds
...
49
Wearing Asbestos Garments ......................................................................
49
V

NONOCCUPATIONAL EMISSIONS AND EXPOSURES

.............................................

51

Asbestos Emissions from Natural Sources
.............................................
Asbestos Emissions from Human-Created Sources
..............................
Redistribution and Fate of Asbestos in the Environment . . .

51
51
52

Redistribution by Air ..............................
Redistribution by Water .........................
The Ultimate Fate of Asbestos Fibers
Exposure to Airborne Asbestos

........................................

Exposure from Ambient Air ........................................
Exposures from Asbestos Mining, Milling,
and Product Manufacture ........................................
Exposure from Transportation of Materials
Containing Asbestos .................................................
Exposure from Asbestos Manufactured Products
Exposures from Disposal of Asbestos Products
and Wastes
.....................................................................
Exposures of Asbestos Workers' Families . .
Exposure to Asbestos in Drinking Water ....................
Exposure to Asbestos in Foods and Drugs
....
iv

01 061 0560

52
54
54
55
55
56
57
58
61
62
62
64

VI

CONTROL OF THE ASBESTOS HAZARD—PHYSICAL CONTROL .

.

67

Engineering Measures

67

68
68

Exhaust Ventilation .
Isolation .........................
Plant Design
. . . .
Treatment of Asbestos
Substitution
. . . .

P ro d u c e d u n d e r C o u rt O rd e r

in K a rr v . Owens C o rn in g

F ib e r o la s . a t a l . . USDC SD M i* e : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h i* C o u r t 's o r d e r .

Administrative Measures

69
70
72
72

...............................................................................

75

Limiting the Number of EmployeesExposed
............................
Limiting the Duration of Exposure for Any Given
Person.......................................................................................................
Restrictions on Smoking and Eating
........................................
Smoking Cessation Programs
............................................................

75
75
76
77

Work Practices, Including Housekeeping and Use of Personal
Protective Equipment ....................................................................................

77

Housekeeping
..............................................................................................
Personal Protective Equipment .......................................................

78
78

Control in Specific Manufacturing and Consuming Indus­
tries
......................................................................................................................

80

Asbestos Textile Production ...........................................................
Asbestos Paper
.........................................................................................
Asbestos-Cement Pipe and Sheet.................................................
Automotive Brake and Clutch Repair
........................................
Construction
.............................................................................................
Demolition and Rip-out of Asbestos-Containing
Insulation.............................................................................................
Control of Emissions to the General Environment

80
81
81
81
81
82

....................

83

Air Pollution Control ..........................................................................
Water Pollution Control .....................................................................
Waste Water Treatment Processes .................................................
Control of Asbestos Fibers in Potable Water
Supplies..................................................................................................
Waste Disposal........................................................................................
Identification
........................................................................................
__ Sewar^tion..................................................................................................

83
83
84

87

- Sec^e Transport..............................................................................

87

^ Secigte Ultimate Disposal................................................................

87

Control During Transportation................................................................

87

85

86
86

01 061 0561

°c'

.

t h is C o u r t 's o r d e r .

Composition of the Workforce .

.................................................................

89

Lung Cancer........................................................... .......................................
Mesothelioma
..............................................................................................
Asbestos is...................................................................................................

90
90
92

Early Detection and Treatment of Asbestos-Related
Diseases.................................................................................................................

92

Lung Cancer...................................................................................................
Laryngeal Cancer................................................................ ....
Mesothelioma..............................................................................................
Cancers of theAlimentary Tract ....................................................
Asbestos is......................... .... ....................................................................

92
96
96
96
97

CONTROL OF THE ASBESTOS HAZARD—EDUCATION

99

Goals of Education..............................................................................................
Modes of Education—The Written and the Spoken Word
. . .
The Educators
...................................................................................................

99
100
101

Physicians
.................................................................................... .
Nurses
..............................................................................................
Health Educators (Communication Specialists)
. ,
Industrial Hygienists ........................................................... ,
Union Health and Safety Specialists .............................
Industrial Safety and Other Training Specialists
Science/Medical Writers ...........................................................

t>e

it

89

n o t to

P ib e r o la s .

VIII

CONTROL OF THE ASBESTOS HAZARD—MEDICAL MANAGEMENT

a c c o rd a n c e w it h

p ro d u c e d u n d e r C o u rt O rd e r

in H a re v . Owens c o rn in g
a l . USDC SD M is s : c o n f id e n t ia l in fo r m a tio n ,
c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

VII

Target Groups for Education

'

101
101

v-J-02
'

102
102
102
103

.....................................................................

103

Managerial and Supervisory Personnel
...................................
Workers in the Asbestos, as Well as Other, Trades . .
Retirees and Other Former Workers ............................................
Workers’ Families
...............................................................................
Occupational Health Professionals......................... .

103
104
104
104
104

Assessment of Education's Value

...........................................................

105

APPENDICES
A

ASBESTOS-RELATED AND -ASSOCIATED MINERALS

B

FEDERAL REGULATIONS OF OCCUPATIONAL EXPOSURE
-

................................

B-l

r
L- C

MONITORING AND MEASURING ASBESTOS CONTAMINATION ..........................

C-l

JTTd

ANIMAL STUDIES RELATED TO CARCINOGENIC EFFECTS

E

.........................................

A-l

OF FIBERS.................................................................................................................

D-l

AIR AND DRINKING WATER ASBESTOS CONCENTRATIONS
FROM SOME PUBLISHED SOURCES.....................................................................

E-l

vi

01 061 0562

SMOKING CESSATION PROGRAMS

............................................................................

F-l

G

SOURCES OF EDUCATIONAL MATERIALS

.............................................................

G-l

H

REFj£SMCS&-...................................................................................................................

H-l

F ib a r o ia s .

.

P ro d u c e d u n d e r C o u rt o r d e r

<

in H a rt v . Owens C o rn in g
a l . USDC SD M is s : C o n fid e n tia l in f o r » e t io a
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
e c c o rd e n c e w it h t h is C o u r t 's o r d e r -

;

F

i

V11
".i

f\

)

01 061 0563

ILLUSTRATIONS

1

Distribution of Ultrabasic and Metamorphic Rock
Formations in the United States ................................................................

4

Disposals and Emissions of Asbestos from Asbestos
Production, Manufacturing, and Consumption in the
United States ............................................................................................................

53

Locker Room, Shower Arrangement .

......................................................

71

1

Apparent U.S. Consumption of Asbestos Fiber ...................................

10

2

Operating and Nonoperating Asbestos Mines and Mills
in the United States.........................................................................................

12

3

Selected Asbestos Products and Their End Uses..............................

14

4

Major U.S. End Uses of Asbestos Fiber, By Type & Grade

16 9

5

Deaths from Respiratory Cancer by Cumulative Dust
Exposure......................................................................................................................

28

Exposure to Airborne Asbestos in Selected Asbestos
Product Manufacturing Industries
...........................................................

44

Medical Examinations for Asbestos-Exposed Workers ....................

93

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Q w ent C o rn in g
F ib e r o la s . a t a l . . USDC SD M is s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b « c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

2

3

.

TABLES

6
7

.

.

FV-

ix

01 061 0564

There is increasing realization that asbestos may be present across
the entire spectrum of human exposure--in our air, water, food, drugs,
cosmetics; in our homes and, most importantly, in our workplaces. There
is also developing awareness that several types of cancer may be the con­
sequence of exposure to this material, especially for certain segments
of the population.

P ro d u c e d u n d e r C o u rt O rd e r in H a rt

v . Q w e n i C o rn in g

•

F ib e r o la a . a t a l . , USDC SD M ie s : C o n f id e n t ia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d ia t r ib u t e d e x c e p t in
e c c o rd a n c e w it h t h is C o u r t ‘ a o r d e r .

FOREWORD

Recognizing our responsibility to transfer information to the scien­
tific community and the public, the Division of Cancer Control and Rehabil­
itation, National Cancer Institute, is making available this document on
asbestos and cancer.
Several of the more important objectives of the
document are to:
(1) present both current and historical evidence of the
carcinogenic potential of asbestos; (2) examine potential exposure of the
public; (3) describe current intervention and control technology; and
(4) discuss the possible prevention roles of various individuals and
groups in the community.
Dissemination of information is a fundamenta
prerequisite to the formulation and implementation of action programs
for effective cancer control and prevention at the federal, state, and
local levels.
This document represents work of individuals in many different
research fields, and the contributions of all these individuals are
acknowledged.
The comments of many scientists in the federal government and private
sector are greatly appreciated.
Particular thanks must be given to Dr.
Herman Kraybill and the Interagency Collaborative Group on Environmental
Carcinogenesis for their comments and to Drs. Irving Selikoff, Mearl
Stanton, Paul Kotin, Elizabeth K. Weisburger, and Kenneth Bridbord for
their review and suggestions.
Dr. Winfred F.
Cancer Institute.

Malone served as Project Officer for the National

Division of Cancer Control
and Rehabilitation
National Cancer Institute
rfNr ocS

0<:

xi

01 061 0565

ACKNOWLEDGMENTS

SRI International (formerly Stanford Research Institute) acknowledges the
invaluable advice and assistance of the following individuals during the

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
E ib e r o ia s . a t a l . , USDC SO h ie s : C o n fid e n tie l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
A c c o rd a n c e w it h t h is C o u r t's o r d e r .

preparation of this monograph on asbestos:
Henry Anderson, M.D.
Department of Environmental Medicine
Mount Sinai School of Medicine
New York, New York
Robert E. Baumann, Ph.D.
Professor of Engineering
Iowa State University
Ames, Iowa
Arnold Brown, M.D., Chairman
Department of Pathology and Anatomy
The Mayo Clinic
Rochester, Minnesota
Jean Spencer Felton, M.D.
Long Beach Naval Shipyard
Long Beach, California
Graham W. Gibbs, Ph.D., Director
Occupational Health and Safety Unit
Institute for Mineral Industry Research
McGill University
Montreal, Quebec, Canada
Philippe Shubik, M.D., Director
Eppley Institute for Research in Cancer
Omaha, Nebraska
Acknowledged also are the many contributions from the staffs of SRI's
Oni-pr for Occupational and Environmental Safety and Health, Center for
ReSourJ^ and'TSIvironmental Systems Studies, Biorganic Chemical Department,
Mi'heralfr'and Metals Center, and Center for Research on Stress and Health.

xiii

061 0566

Chapter I
INTRODUCTION

Because of their unique combination of resistance to heat and chem­
ical attack, high tensile strength, and flexibility, fibrous asbestos
minerals have long been used by man.
The early Greek geographer,
Pausanias, speaks of golden lamps made about 430 B.C. with incombust­
ible wicks of "Carpathian flax." The Romans used asbestos as cremation
clothes to conserve the ashes of deceased persons of rank.
The French
emperor, Charlemagne, had a tablecloth of asbestos and is reputed to
have impressed his enemies by passing it through fire to clean it.
Today, asbestos is found in thousands of commercial products
including heat-resistant textiles, reinforced cement, special filters
for industrial chemicals, thermal insulation, floor tiles, gaskets, and
brake linings.
More than 725,000 metric tons (800,000 short tons) of
asbestos have been consumed in the United States alone in producing these
products in each of several recent years.
As a consequence of man's
utilization of asbestos, coupled with the natural occurrence of the mini ~
eral, asbestos fibers are found in the air we breathe, the food we eat
and the water we drink.

A Hazard to Human Health
The fact that asbestos is a hazard to man's health was recognized
quite early.
In the first century, both Pliny the Elder, the Roman
naturalist, and Strabo, the Greek geographer, wrote of a sickness of
the lungs in slaves whose occupation was the weaving of asbestos into
cloth. However, the association of asbestos with chronic respiratory
disease had to be rediscovered in the modern era.
A series of case
reports was followed by an epidemiologic study published in London in
1930,1 52 years after large-scale mining of asbestos had begun with the
opening of a mine at Thetford, Quebec, Canada.
The cancer-producing
potential of asbestos was not established until 1949, when a report was
published describing an excess of cancer of the lung and pleura among
individuals dying from asbestosis.^
Jj^is^ru3K_ clear that among asbestos workers, there is, in'addition
to" the^risk of asbestosis, a greatly increased risk of death from lung
cancerjB&d from.pleural and peritoneal mesothelioma, malignancies that
are sehhrni found in the general population.3>^ Moreover, asbestos has
been—ilnked with gastro-intestinal, oropharyngeal, and laryngeal cancer
According to the U.S. Public Health Service, one
now living in the United States either work or have wo

0
1

01 061 0567

asbestos product manufacturing industry.^

This figure does not include

those employed in mining and milling asbestos; those whose work may
involve installation, modification, or repair of asbestos products;
persSTTs-exposed indirectly to asbestos in the course of their work such
as a^SSfffpyards or in the construction industry; persons living in the
neighborhood of an asbestos product factory; or consumer users of asbestos
materials.

What is "Asbestos?"
To the mineralogist, asbestos is the generic name for a group of
naturally occurring hydrated mineral silicates of the amphibole or
serpentine series that are characterized by fibers or bundles of fine
single crystal fibrils.
Naturally occurring asbestos fibers typically
have length-to-width ratios of the order of 100 and higher.
Included in this definition are the following minerals:
•

Chrysotile

•

Crocidolite

•

Amosite, and

•

The fibrous varieties of anthophyllite, tremolite, and
actinolite.*

All of these minerals may occur in a nonfibrous form, in which case
they are not classified as asbestos.
Commercially, chrysotile is the
form of asbestos used most.
Crocidolite, amosite, and anthophyllite
also have some commercial significance.
It is important to note that identification of asbestos fibers is
relatively simple with macroscopic samples that clearly show the fibrous
nature and other unique characteristics of these minerals.
Positive
identification is based on morphology, crystallographic structure,
color, hardness, optical properties, and appearance.
However, in the
case of microscopic samples, positive identification becomes increasingly
difficult, even when special microanalytical techniques are used.
The identification of asbestos is complex because many of the mineral$ that are chemically almost identical to different varieties of
asbe^§s-t{j^g.T grunerite to amosite, serpentine to chrysotile) exhibit

Crocidolite, amosite, anthophyllite, tremolite, and actinolite are
derived from the amphibole series and may be referred to as
"amphiboles."
2

01 061 0568

perfect prismatic cleavage (the ability to break along well-defined
crystallographic planes), so that physical degradation often leads to
the formation of minute cleavage fragments that are chemically as well
as physically indistinguishable from asbestos fibers.
Recent compre­
hensive studies*at'the_U.S.
studies*at~the U.S. Bureau of Mines have concluded that there is
currently no atBsTute way to distinguish between finely divided asbestos
and certain'other minerals of similar composition.6 Some minerals other
than asbestos that may exhibit fibrous structure are listed in Appen­
dix A.
On the other hand, recent biological studies suggest that, in
terms of carcinogenic activity, mineral shape and size may be more
important than chemical nature.^ The question of asbestos carcino­
genicity can, therefore, be viewed as part of a broader issue—i.e.,
tissue modification caused by mineral fibers.

Occurrence of Asbestos
All forms of asbestos develop through several stages of geologic
processes (paragenesis) from parent rocks that are transformed into
asbestos.
Parent rocks of asbestos minerals include basic constituents
normally found in ultramafic, dolomitic, or limestone rocks.
Transfor­
mation may occur under localized conditions of temperature and pressure
which lead to recrystallization of other in-situ minerals (metamorphism).
It may occur as a result of the action of hot mineral solutions that
can dissolve or otherwise alter some minerals to form others (hydrother­
mal processes).
In all of the commercial asbestos deposits, the geologic conditions
have been favorable to the development of fibers of sufficient quality
and concentration to warrant their extraction.
(The same conditions
may operate in other mineral deposits but yield asbestos fibers that are
too disseminated or scarce to be of commercial interest.)
Minerals and rocks that can contain asbestos are listed in Appen­
dix A.
A favorable mineral association is not a sufficient condition
for the formation of asbestos—it will form only if special structural
and other geologic conditions are met.
If asbestos presence is, in
fact, established, the minerals and rocks listed in Appendix A would be
significant sources of contamination for humans, since they include
important raw materials for industry and are mined in commercial quan­
tities, worldwide.
The aceas w thS^United Stated having basic geologic constituents
associated with(.the formation of asbestos are shown in Figure 1.
Again,
this graphic doe§~ not necessarily depict actual asbestos occurrence but,

3

01 0G1 0560

Inferred ultrabasic intrusive*.

in H a rt v . O wen* C o rn in c
F ib a r o la a . a t a l . . USDC SD M is s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
P ro d u c e d u n d e r C o u rt O rd e r

rather, is an overview of the areas that are more likely than others
to provide the geologic setting associated with formation of asbestos.
Although deposits of asbestos may be found throughout the United
States, asbestosis'commercially mined and milled at only five loca­
tions, in the s®WSs”of California, Arizona, and Vermont.
(Most of the
asbestos consumed in the United States is imported, nearly all of it
from Canada.)
In addition to commercial mining and milling of asbestos,
human-created occurrences of asbestos fiber may result from the raining
and milling of mineral ores associated with asbestos; from the inadver­
tent disturbance of asbestos deposits by activities such as farming and
road building; from the transportation of asbestos ore, milled fiber,
products, and wastes; from the manufacture, use, repair, and demolition
of asbestos-containing products; and from the disposal of asbestos
wastes. All are discussed in succeeding chapters of this monograph.

Regulation of Asbestos-Fiber Emissions
A recommendation for limiting exposure to asbestos in U.S. industry
was made in 1938 by the U.S. Public Health Service.® The recommended
limit, an airborne concentration of less than 5 million particles per
cubic foot, was formally recognized in 1964—as a guideline issued by
the Bureau of Labor Standards.
No legal regulations were established
until passage of the Occupational Safety and Health Act of 1970 and
establishment of the Occupational Safety and Health Administration
(OSHA).

Occupational Exposure
OSHA regulations apply directly to all private employers, including
federal government contractors, but not to federal, state, or local
government agencies.
Federal agencies are required to establish their
own occupational safety and health programs consistent with the stand­
ards of the Act and subsequent OSHA regulations.
States are encouraged
by the Act to develop programs and regulations, for private employers,
that are at least as effective as OSHA regulations and can, under these
conditions, assume responsibility for enforcing standards—at the time
of this writing, 24 states have programs of their own.9 The current
OSHA limit on occupational exposure to asbestos fibers is an 8-hour
time-weighted average of 2 fibers per milliliter, no longer than 5
micrometers, with a length-to-width ratio of at least 3:1, detected by
a method using phase-contrast (optical) microscopy.
The permissible levels of occupational exposure to asbestos con­
tained in ail feSirral regulations (and one proposal) are summarized in
tabular form in Appendix B.
Also, the provisions of these regula­
tions for method of compliance, monitoring, medical surveillance, ed
cation, and the keeping of records are summarized there.

5

01 061 057

Emissions to Air and Water, Disposal of Solid Waste, Transportation
A national air emission standard for asbestos, first published in
1973,1^- requires either the institution of specified air-cleaning meth­
ods -or frlse no visible emissions (except water) to be released to the
outsidefgjr.
The standard applies to the milling of asbestos (but not
to adjapS? storage depots); manufacturing or processing of specified
products^ renovating or demolishing certain buildings (but not ships)
containing more than a specified amount of friable asbestos insulation;
and to wastes containing commercial asbestos or products of asbestos
mining and milling.
Friable or spray-on insulating materials, except
when applied to equipment or machinery, must contain no commercial
asbestos; however, spray-on paints, decorative materials, and weather­
proofing are not regulated.
Under the terms of guidelines and standards promulgated in 1974
and 1975, certain asbestos-manufacturing operations were to achieve, by
July 1, 1977, wastewater effluent limitations requiring application of
the best practicable control technology currently available; and by
July 1, 1983, except for operations involving solvent recovery, there
is to be no discharge of wastewater pollutants to navigable waters.H
Federal agencies are directed by two Executive Orders to monitor,
evaluate, and control their activities so as to protect and enhance ^
the quality of the environment and to conform to air and water quality]
standards of the Clean Air Act and the Federal Water Pollution Control!
Act.

Food, Drugs, Consumer Products
The Food and Drug Administration (FDA) has reviewed several com­
mercial practices that may result in asbestos contamination of food and
drugs and, in January of 1976, revoked approval for use in foods of
sodium chloride (salt) produced by the electrolytic diaphragm process.
In the absence of more-reliable data on background concentrations of
asbestos in water and the contribution of asbestos filters to levels
of asbestos found in ingestible products, the FDA has not regulated
the use of asbestos filters for filtering edible foods, beverages, and
nonparenteral drugs.13 The agency has, however, enacted regulations to
limit asbestos and other fibrous materials in parenteral drugs.^ The
FDA has approved (1) the use of asbestos as a component of various
types of food-contact articles in which contamination of food is not

I!

i

6
CLAIMED
privileged
by ' OCF'

.

01 061 0572

I'*.- W<- e

nf

i *4

-v. • ."v i^v^» 'n*~*

CLAIMED
PRIVILEGED
BY'OCF' .

likely to occur, and (2) the use of talc, in which asbestos is a possible
impurity, in cosmetics.*
fr--

The Coi^iioex^Product Safety Commission has banned general-use
garments,containing asbestos.
The use of asbestos in special garments
such as fire-fighting suits is permitted, but only if they are con­
structed so that asbestos fibers will not become airborne under normal
conditions of use.I^t
-

USDC SD M is s :

re p ro d u c e d o r d is t r ib u t e d e x c e p t in

ir t O rd e r in H a rt v . Qwenc C o rn in g

C o n f id e n t ia l in fo r m a tio n ,

Constraints on Monitoring and Measuring Asbestos Levels
As will be brought out later in this monograph, it is simply not
known what attributes of asbestos it is that constitute a health
hazard—size, shape, mass, type etc.—nor is it known what amount is
hazardous or over what period of time.
The U.S. federal occupational
standards are, perforce, an attempt to optimize what is known about
the health hazard with the technical and economic practicalities of
measuring the substance.
For example, by using phase-contrast optical
microscopy, rather than the higher resolution electron microscopy, it
is not possible to count all the fibers and not always possible to even
distinguish between asbestos and other fibers (as noted previously);
electron microscopy, on the other hand, is time-consuming and expen­
sive.
The difficulties of measuring and identifying are of such pro­
portions that there are extreme variations in the measurement of a
sample, both within a laboratory and among laboratories.
As a consequence, the reader should always bear in mind the pos­
sible grossness of measurements referred to throughout this document,
even when they are expressed in terms that bespeak of precision—e.g.,
the decimal point.
At the same time, the fact remains that asbestos is
a human carcinogen and that, as such, is a suitable subject for treat­
ment in this document, the prime purpose of which is helping man control
cancer.
The constraint on monitoring and measuring asbestos is such,
nevertheless, that it is the subject of more extensive treatment in
Appendix C of this document.

Talc is listed as a "generally recognized as safe" (GRAS) substance
for user inlg^er^.paperboard, and cotton food packaging materials; as
an anticaking agent for forms used in molding various food shapes and
in chevH.ng pirn base; and to coat polished nonenriched rice, as a free­
flow agent. *and as a vehicle for enrichment formulas.15 An FDA.ruling
on talc dS^a direct food or drug additive has been deferred until an
acceptable analytic method can be developed.^
^Full attainment of the desired result of regulation inevitably requires
adequate means of enforcement. Legal powers of enforcement as well as
de facto enforcement practices differ widely among the various govern­
ment agencies having statutory authority.
See Reference 17 for an ex­
ample of divergence of enforcement practice in just one regulatory agency
from what is required by law.
.7
1t - ft?•

01 061 0573

*****

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g

F ia « r o l« a . a t e l . . USDC SO M is s : c o n f id c n t is l io to r » e tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
e c c o rd e n c e w it h t h is C o u r t 's o r d e r .

.Summarized in the next four chapters are:
production and uses of
asbeffTOS fiber and fiber-containing products; the biological effects,
carcW5gUHTc and noncarcinogenic, of exposure to asbestos; occupational
and aonoccupational exposures and exposure levels.
In the final three
chapters, strategies and programs for the control of the health hazard
represented by human exposure to asbestos are set forth.

01 061 0574

fcr-.
“t™*"
Chapter II
PRODUCTION AND USE OF ASBESTOS FIBERS AND PRODUCTS

Although some exposure of humans to asbestos fibers in air and
water is always possible as a result of the weathering of asbestoscontaining rock, it is man's large-scale commercialization of the mineral
that has engendered greater health risk.
In this chapter, the major
facets of such commercialization in the United States are reviewed—
consumption and production volumes; categories of manufactured goods;
and processes for mining, milling, transporting, and manufacturing
asbestos and asbestos-containing products.*

U.S. Consumption of Asbestos Fibers
During the five years ending in 1975 the amount of asbestos fiber
apparently consumed'!'
the United States averaged some 800,000 tons
annually, although between 1974 and 1975 apparent consumption declined
27% from 856,000 to 629,000 tons.t It is expected that consumption will
have recovered to about 820,000 tons in 1976.
The sharp decline between
1974 and 1975 reflects not only a market affected by a sharp recession,
but also a substantial interruption of supply associated with work
stoppages, a landslide at a major mine, and a serious fire at an asbestos
mill in Quebec, Canada.
The estimated U.S. apparent consumption of
asbestos fiber for the 1971-75 period is shown in Table 1.
It can be seen in Table 1 that most of the asbestos fiber used in
the United States is imported (about 90%).
Nearly all of this imported
asbestos is chrysotile fiber that comes from Canada (96.5% in 1974). The

*
This chapter includes information obtained through a special survey of
industry carried out in the Fall of 1976 by the Mineral and Metals
Center, SRI International.
^"Apparent" consumption—i.e., production plus imports, plus net ship­
ments from govern«^p stockpiles if any, less exports.
Apparent con­
sumption figures o* not:"take into account any changes in inventory
levels of manufacturers and therefore differ from "actual" consumption

Volumes in this "chapter are expressed in short tons (2,000 pounds)
accordance with industry practice.

rrMH

$ ;■*«

9
} \i'■

01 061 0575

Table 1
APPARENT U.S. CONSUMPTION OF ASBESTOS FIBER
(Thousands of Short Tons)

*=--

1971

1972

1973

1974

1975

Production

131

132

150

113

100

Imports

681

736

792

776

575

Stockpile releases

10

13

7

29

4

Exports

54

59

66

62

50

768

822

883

856

629

-

Apparent consumption

ource:

U.S. Bureau of Mines , Commodity Data Summaries,

1976.

Republic of South Africa accounted for some 3% of the U.S. imports'
1974 (crocidolite and amosite fibers), and a number of countries suj
plied the remainder.
A substantial portion of Canadian output is pi
duced there by U.S. companies that manufacture asbestos products.
It should be noted that in addition to importing both crude and
milled fibers, the United States imports products manufactured from
asbestos.
In 1974, for example, the value of products exported from
Canada to the United States was as shown below:^
Canadian Dollars
(millions)
Brake linings and clutch facings

$0.9

Building materials

3.7

Other products

3.2

Total

$7.8

H«*ever, the value of imported products is not large compared with U.S.
Z doffi§tic::stripments, which, for example, totalled $742.6 million in

,19

,—The U.S. Bureau of Mines has estimated that U.S. demand for asbes­
tos in the year 2000 will range between 1.0 million and 1.8 million
tons.^ it is also possible, however, that substitution of other

10

01 061 0576

V

materials for asbestos could result in a lower level of demand.
substitution could occur for a number of reasons such as:
•

This

More rap:jkprice increases for asbestos than for its
competit^^^rndnrt-g .

•

Health aqjl safety considerations.

•

Lack of availability (an industry expert has estimated
that by 1980 supply could fall short of potential world
demand by about 500,000 tons, or about 10% of world
demand).

U.S. Production and Producers of Asbestos Fibers
The volume and value at the mines of asbestos fiber production in
the United States during recent years is shown in the tabulation that
follows:
Production
(Thousands of
Short Tons)

Value
Per
Ton

1971

131

$ 93

$12.2

1972

132

102

13.5

1973

150

121

18.2

1974

113

158

17.9

1975

100

182

18.2

Total Value
(Millions o:
Dollars)

The decline in production volume from the all-time peak of 150,000 tons
in 1973 resulted primarily from the closing or reduction in output of
several mines such as GAF Corporation’s Lowell Vermont mine (acquired
by the Vermont Asbestos Group), Pacific Asbestos Corporation's mine
near Copperopolis, California (later reopened by Calaveras Asbestos
Limited), and the Christie mine of'Coalinga Asbestos Company, Inc., at
Coalinga, California (a 15,000-ton-per-year mine that has remained
closed).
The average domestic production of only 125,000 tons annually
during the 1971-75 period is a relatively small fraction of the nearly
800,000 tons consumed annually in the United States during those years.
As a result of an increase in the production volume and average value
per ton in 19_76^eh^ value of U.S. asbestos fiber production could be
in the range ^of ^5-3(1 "million in 1976 (11-13% of the mine/mill value of
all asbestos like^f- to be consumed during the year) .
U.S. asbestos—mines and mills, their locations, output, and employ'
ment are shown in Table 2.
The current total mill capacity is on the'

&
V

11

f /; <

01 061 0577

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
P ib e m i« g , a t a i . . USDC SO M is s : C o n f id e n t ie i in f o r a a t io n
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

order of 143,000 tons per year (all in the form of chrysotile fibers).
California mines and mills account for about 70% of total U.S. output.
It is difficult to predict changes in U.S. asbestos output because
such changes wiHJjg^^.f unction of costs, including environmental costs,
in the United SEStes as compared with costs in Canada and other sources
of supply.
Neither current nor projected costs are published.

End Uses of Asbestos
The high tensile strength, flexibility, heat and chemical resis­
tance, and favorable frictional properties of asbestos fiber make it
adaptable to a large number of uses.
Depending on the length of fibers
and other characteristics, asbestos can be:
Carded, spun, or woven
Used as structural reinforcement of materials such
as cement, plastic and asphalt
Laid and pressed to form paper.
Some authorities, such as the U.S. Bureau of Mines, state that
there are more than 2,000 discrete uses of asbestos; others, such as the
Asbestos Information Association and Canada's Department of Energy,
Mines and Resources, suggest that there are upwards of 3,000 uses.
A
selected few of the many applications are shown in Table 3.
The properties of asbestos fibers determine the uses to which the
fibers are put.
Properties of major importance are length distribution,
bundle diameter distribution, harshness, tensile strength, and surface
activity.
Other considerations include color and content of iron and
dust.
The relative-strength standard developed for chrysotile asbestos
by the mining industry in Quebec is a convenient basis for delineating
some major uses.
For example:

•k

•

Long fibers (Groups 1 and 2 and 3) are used in textiles,
electrical insulation, filtration media, and maximumstrength asbestos cement products.

•

Medium length fibers (Groups 4, 5, 6) are used as rein­
forcing fillers in asbestos cement products, in friction
raaterilpE syefe__as. brake linings and clutch facings , in
paper, and in pipe covering.

No. 1 crude is 3/4 inch staple and longer (to nearly 6 inches) . No.
crude is 3/8 to 3/4 inch staple.
Other groups are milled fibers.

2

13

<- li

:

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01 061 0579

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!
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t
f
•

Short fibers (Groups 7, 8) are used as reinforcing filters
in plastics, floor tile, and asphalt and in paints and
oil-well drilling muds.

•

Chrysotile fiber accounts for a very high proportion of
total asbestos use (94% in 1974).

•

About 98% of the crocidolite is used in the production of
asbestos cement pipe, because of (1) its hardness,
brittleness, and high tensile strength, which add to the
rigidity of the end product, and (2) its superior fil­
tration qualities, which enhance the drainage of water,
permitting the cement to dry more rapidly.

•

Asbestos cement pipe and sheets account for a large pro­
portion of total use (38% in 1974).

•

A very large proportion of total asbestos use is accounted
for by the shorter-length fibers (Quebec Grade 7 chrysotile
alone accounted for nearly 40% of the total use in 1974).

■

P ro d u c e d u n d e r C o u rt o r d e r

in H a rt v . Q w ent C o rn in g
F ib e r o la a «C a l . . USOC SD M ie s : C o n fid e n tia l in f o n u t io n ,
n o t t o b e c o p ie d / re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

The consumptidkjjittern for asbestos fiber in the United States is shown
in Table 4.
Xne construction industry—including new building, renova­
tion, and maintenance—accounts for an estimated 70%-80% of total U.S.
consumption.
The first four uses shown in Table 4, which are constructionindustry related, account for only 65% of the total use, but a portion
of some of the other uses is associated in various ways with the con­
struction industry.
Several other aspects of Table 4 are noteworthy:

The transportation industry uses about 14% of all the asbestos con­
sumed.
The applicance industry uses some 5%-6% of the total.^

Handling, of Fiber and Products During Their Production
Producing the many asbestos-containing products that are used
involves mining asbestos ore; milling, or hand-separating, the fibers
from the ore and from each other; transporting both ore and fiber; and
manufacturing the products themselves.
These four general processes
are reviewed briefly in the sections that follow.

Mining
Most asbestos ore is mined in surface operations.
Of the five U.S.
mines in o^eraJgfcSnT^feiir are surface mines and one is underground.*
Each operating mine is associated with a mill that processes the ore.

For a description of each mine and a discussion of the mining, milling,
and dust-control procedures, see National Environmental Research Center,
Characterization and Control of Asbestos Emissions from Open Sources,
North Carolina, September, 1974.
15

01 061 0581

P ro d u c e d u n d e r C o u rt O ro e r in H a rt

v

■

Qwena

C o rn in g

■

F ib e r o la a . a t a l . . USDC SO M is s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t's o r d e r .

In three cases, the mine and mills are at the same location, but two
mines send their ore by truck to mills 32 and 55 miles away.
(See
Table 2.)
The methods used to mine asbestos ore in the United States
are described b elfet..
Area stxip mining, as practiced in the California operations.
entails removal of the ore by earth-moving equipment from shallow
deposits—in one instance without even the need for blasting.
Generally,
a shallow overburden with low concentrations of asbestos fiber must be
removed.
Open pit mining, as practiced in the Vermont operation,
similar to area strip mining operations except that to follow the
veins, the workings are much deeper.
Blasting and removal of ore
primarily on the sides of the pit along terraces that spiral down
the sides of the pit toward the bottom.

is
fiber
occur
around

Underground mining, as practiced in the Arizona operation,
entails following the veins of ore with shafts, galleries, and drifts,
using blasting and earth-moving equipment.
This operation is followed
by transporting ore to the surface, where it is processed further.
At the typical asbestos mine, coarse ore is crushed by a jaw
or gyratory crusher to a size that can be accommodated by the mill.
Oversize rock is separated by rotating cylindrical trommel screens and
is crushed in a secondary crusher, usually of a conical type.
The ore
streams are conveyed to driers—rotary kilns in larger installations—
where moisture in the ore (up to 30% by weight) is removed.
The dried
ore is then stored, with large amounts being held to allow for varia­
tions in fiber demand and mine production over time.
Prior to milling,
dried ore is conveyed to an additional crushing step.

Milling
Milling, done primarily by hammer mills (fiberizers) or crushers,
serves to free the fibers from the rock and separate the fibers from
each other.
In general, longer-length fibers in the final mix bring
higher prices.
Hence, it is desirable to hold the mechanical working
or fibers to a minimum since, although the fibers have very high ten­
sile strength, they are so fine that they are easily broken.
The most exp^nsive grades of fiber are not mechanically milled at
all; rather, -they^Se-liand-separated ("cobbed") from the surrounding
rock into bundles »f relatively long fibers with lengths of 3/4" or
more.
Such fiber-5s- valued for manufacturing asbestos textiles.
The solutiorr to the problem of maximizing the recovery of fibers
other than hand-cobbed, in all but one of the asbestos mills in the
United States, is to use mechanical means to free the fiber bundles from
the rock, but to use air aspiration systems to separate and convey the

17

i >!

01 061 0583

fibers.
In these systems, the ore is shaken on progressively finer
screens through which small rocks and fiber bundles pass for further
treatment while larger rocks are retained for further crushing or for
conveyance to tailing dumps.
The fibers freed are removed by the flow
of Mr^fhiQugh powerful suction hoods.
Separated fibers are caught in
dry Cyclones and conveyed to screens that separate them according to
sizST After sizing, the fibers are sent to bins for storage.
Subse­
quent operations include removing the fibers from the storage bins,
blending in fibers of different sizes to produce the desired final
shipping specification, and bagging for shipment.
The one exception to the air-aspiration milling system is found
in a California mill that processes the loose fiber ore by a wetseparation system.

Transportation
Conveyors and trucks are used at mine and mill sites to move ore
from mines to mills.
Asbestos fibers typically are shipped from the mills in 100-pound,
multiwall, paper or plastic bags.*
(One producer reports the use of a
stronger, woven, polyvinyl bag for some shipments.)
Bags are presdflfcr
packed to reduce bulk, damage, and dust.
It is customary to tape r»r
ped or punctured bags when the damage is discovered; yet the fact t*t
the fibers are tightly packed may often prevent them from escaping
if the damaged area is not repaired.
The technology is now availabret
pack asbestos even more tightly—i.e., to form blocks with twice the
density of fiber shipped in conventional bags, a 100-pound block having
a volume of about one cubic foot.
Palletizing is used almost universally, with the bags glue-locked
to each other or shrink-wrapped to the pallet (wrapped with a film of
plastic which is then shrunk) to stabilize the load. Much of the asbes­
tos shipped is further unitized by being loaded into sealed railroad
boxcars or shipping containers.
Sometimes the asbestos is made into
pellets, which, rather than being packed in bags, are loaded on and off
railroad boxcars by gravity flow through pipes.
The majority of Canadian chrysotile fiber is shipped into the
United States in conventional sealed railroad boxcars in which the con­
tents are protected by inflated-rubber bags.
The modern damage-free
b-wijAead cars are being used as they become available.
The cars are
roSTed^rrectly from the Canadian mills to the U.S. manufacturing
plants.
Smaller proportions of chrysotile imports from Canada are
received in containers, either by rail or by ship via the Atlantic

Some manufacturers can add the bags, along with the fibers, to their
product mix without even opening them.
18

01 061

Ocean.
All fiber from South Africa, the source of all U.S. imports of
crocidolite, arrives by ship in containerized bags at Gulf Coast ports.
U.S. exports af fiber, virtually all of which are from California
and destined for JpXico, Central America, and the Far East, leave the
mills by both raiJBJUU Tl/uck.
Containerized ocean shipments leave from
ports such as Stockton, Sacramento, Oakland, and San Francisco.
Although
100-pound bags are by far the most widely used in the industry, one of
the California mills, for the convenience of its customers, ships all
of its fibers in bags weighing from 10 to 50 pounds.
One company plans
to shrink-wrap each paper bag individually, for added protection, since
some users buy in less-than-pallet lots. A representative of one of the
world's largest shippers of asbestos reports that about 2% of the bags
shipped sustain some damage.

Manufacture of Asbestos-Containing Products
Production processes used in th<= consumption of asbestos are high­
lighted below for selected products.
Asbestos cement products use the largest amount of asbestos
of any product category (about 317,000 tons, or 38% in 1974).
Specific
products include wallboard, pipe, shingles, and blocks.
Advantages of
the products over their nonasbestos counterparts are better tensile
strength, strength-to-weight ratio, strength under heat stress, resis­
tance to acid, and smoothness of finished surface (critical to ensure
laminar flow in pipe used for transport of liquids).
Asbestos fiber (primarily chrysotile, but also others to a
limited extent) is mixed, either wet or dry, with Portland cement and
silica in proportions ranging from 10% to 70% of the total material.
If
the mixing is'done dry, the mixture is generally metered in a flat layer
onto an open surface, where the requisite water is applied by over­
head spray. The resulting layer, much thinner than the final product,
is then wound onto mandrels in a spiral mat (for pipe) until the requi­
site thickness is built up, or is layered flat (for wallboard or shingle
forms).
The same winding or layering process may be used for wet-mixed
products, or the mixture may be cast.
Finishing processes for the dried
cement products vary with performance requirements and type, and may
include grinding, drilling, sawing, or cutting.
Asbestos can be made into the full range of textile products—
from nonwoven lap yid felt, through yarn and cord, to woven cloth, rope,
and tube.
Therasb^^fostfibers required for textiles are significantly
different from those used for other asbestos products; they must be quite

For a more detailed discussion of the manufacture of asbestos-containing?*”-^
products, see U.S. Environmental Protection Agency, "Development Docu­
ment for Effluent Limitations, Guidelines and Standards of Performance:
Asbestos Manufacturing," Washington, D.C., 1973.
19

01 061 0585

long to be spinnable.
Spinnable fiber is sometimes obtained by textile
producers in hand-cobbed, "crude," form—i.e., as unopened, rock-free
fiber blocks or bundles—since, as noted previously, it is difficult to
pfectect fiber length during milling operations.
If the fibers are received as crude, they are opened in edge
(tcnife) mills into small bundles and then milled into extremely fine
flexible fibers.
The resultant fibers, as well as being more delicate
and breakable, are also more"floatable,” leading to a greater emission
potential per unit weight.
Once the fibers have been adequately opened
and fluffed,
they may be blended with up to 20% of a cellulosic fiber
such as cotton, the specific material chosen depending upon the appli­
cation of the final product.
The subsequent processes, such as carding,
lapping, roving, spinning, and weaving or braiding (as required) are
all performed on equipment essentially identical to standard textile
machinery.
Asbestos is used in vinyl and asphalt floor tiles as a filler
and reinforcement to provide strength and stability without reducing
flexibility and compressibility. Very short fibers are used, compris­
ing 8-30% of the total weight.
In the case of vinyl tile, for example,
polyvinyl chloride resin serves as the binder, limestone and other
materials are used as fillers, and pigments and chemical stabiliz
make up the rest of the typical mix.
The manufacturing process i
typically a 24-hour operation that includes weighing, mixing, hea
about 150°C, decorating, calendering, cooling, waxing, stamping,
fe­
ting and packaging.
Friction products and gaskets typically contain 30-80% asbestos, generally in some sort of organic binder.
In friction products,
the asbestos is used for its unique combination of strength, compaction
characteristics, friction properties, and stability at high temperatures.
Asbestos is used in these products in two different ways:
(1) the
asbestos, as loose fiber, is mixed with the binder; or (2) the asbestos,
as either matted or woven textile, is impregnated with the binder.
The
low total volume of the latter process is because it is used only in
special situations, generally in gaskets, where dimensional stability
and elasticity are of significance.
Asbestos paper has essentially the same properties as the
usual cellulose-based paper, except that it has superior thermal insula­
tion properties and fire resistance.
It is used primarily as building
paper (roofing and flooring) although it has been reported that the
’'Ij^ve^raaiTtioned qualities also find use in high-quality-bond document
papers.* Asbestos paper is made using the same processes as those used
f<gt~ standard woodpulp papers, but the raw materials mix, by weight,
m£ght be 70-90% asbestos fibers (typically short in length), china clay
starch (or sodium silicate) as the binders, plus other constituents
that provide special properties.

20

01 061 0586

*Chapter III
IgW^eeiCAL EFFECTS OF ASBESTOS FIBERS

As noted in the Introduction to this monograph, asbestos fibers are
known to cause cancer.
In this chapter, (1) a summary of what is known
about the disposition of these fibers in the body is followed by (2) a
description of the carcinogenic effects of the fibers, based on human
studies as well as animal experimentation; also included is (3) a dis­
cussion of the noncarcinogenic effects of asbestos fibers.

Disposition of Fibers in the Body
Technical difficulties associated with the assay of biological
tissues for asbestos have limited the amount of information available
about the disposition of asbestos. Almost all data have come from
animal experiments in which asbestos was monitored by electron micro­
scopy or radiotracers.
Asbestos fibers typically enter the body by
inhalation or ingestion.

Inhaled Asbestos
The disposition of asbestos fibers entering the respiratory tract
is not fully understood.
Certainly some fibers are ultimately deposited
in the airways and lung tissue.
Some could also be expectorated or con­
veyed to the gastrointestinal tract by airway clearance mechanisms and
possibly some to the pleural and peritoneal cavities via lymphatic
drainage.
Of asbestos fibers found at autopsy in human lungs, a majority are
less than 5 ym in length;^-’^ seldom do they exceed lengths of 200 ym or
diameters of 3.3 yra.3 One autopsy study of persons with occupational
exposure demonstrated that all asbestos fibers examined in the lung were
less than 0.5 ym in diameter.2 This preponderance of small fibers in
part reflects their ability to remain suspended in air for longer per­
iods than larger fibers, but it is also a function of their deposition
and clearance characteristics once they enter the respiratory tract.
It
is also possible that some fibers may be fragmented as the result of
biological ar.tTvg^f within nnlmnnarv tissues.

%
Longer Tibeigpare screened more effectively by the nasal hairs.
Inside the upper respiratory tract, fibers are deposited through the
forces of gravitational sedimentation and impaction at points where the
air stream changes direction; and these depositions depend largely on

21

"/

01 061 0587

fiber diameters.3,4 In the small airways, especially at airway branch
points, the collision cross-sectional area, which is a function of fiber
length, is of greater importance.3 As a result of these obstacles, a
- greater proportion of fibers reaching the gas-exchange surface of the
al^oii may be small, compared with fibers entering the upper respiratoBsrerset.

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Qwena C o rn in g

F ib e r-P la n , a t a l. . USDC S D M i* s : C o n fid e n tia l in t o r x e t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

Studies with mammalian cells in culture indicate that these shorter
fibers (usually less than 5 ym) may be engulfed by alveolar macrophages
and transported to lymphatic channels or the mucociliary blanket for
excretion.
Longer fibers may be only partially engulfed or may be
engulfed by several macrophages at once.*7
Data from autopsies of humans have suggested that some fibers may
enter alveolar lymphatic channels and be carried to hilar and mediastinal
lymph nodes.® Numerous fibers can be found in the pleura, a serous
membrane which covers the surface of the lungs, thoracic diaphragm, and
chest wall; how they gain access to the pleura is not known.
Generally,
the concentration of fibers in the pleura is less than in the lung it­
self, but in some areas of the pleura, fiber concentrations similar to
those within the lung tissue have been observed.9

Ingested Asbestos
a-S**-

Most asbestos fibers entering the gastrointestinal tract are p|
ably excreted with the feces.
Although it has been reported in one|£^~
study that there is little evidence of asbestos fibers-^ penetrati
the walls of the gastrointestinal tract, there have been animal studies
showing such penetration.
In a study reported in 1965, chrysotile
fibers were found in the lining of the colon in rats fed a diet contain
ing a massive amount (6%) of chrysotile asbestos. 3-1 in another study,
fibers of amosite asbestos suspended in saline, when placed into an
isolated segment of rat jejunum in vivo, were found penetrating and
within the jejunal wall.
one recent study of rats fed 250-300 mg of
asbestos per week for a year did indicate that if penetration of the
gastrointestinal tract lining does indeed occur, the number of

In an experiment with rats, about one-third of inhaled asbestos (crocidolite) was deposited on the surface of the respiratory tract.
Half
-fejje amount deposited at inhalation was found immediately afterward in
t«E "gastrointestinal tract, nose, pharynx, and larynx; clearance from
thgse latter respiratory tissues to the gastrointestinal tract was
~ practically complete within an hour.
Of the remaining crocidolite
deposited in the lungs, one-quarter had been evacuated at the end of
She month.® In another study of rats exposed to amphibole asbestos for
six months, 41%-74% of the asbestos found in the lungs immediately after
exposure had been removed within 18 months.®

penetrating fibers would be very small (90% probability of less than
1500 fibers).!3

Injected A&sestos
Asbestos i^ected into the bloodstream is rapidly removed and
deposited in various tissues, with highest concentrations observed in
lungs, liver, and spleen.Limited evidence suggests that asbestos
in the blood may be transported across the placenta of rats.16
In mice, asbestos injected subcutaneously migrates along lymphatic
pathways from the injection sites.
Fibers accumulate in lymphoid tis­
sues, particularly in regional lymph nodes, and are usually contained
within macrophages.
Small numbers of fibers may be found in the spleen,
pleura, liver, kidneys, and brain.1?

"Asbestos Bodies"
Approximately 10% to 30% of the fibers retained by human lungs
(usually longer than 5 pm) become coated with mucopolysaccharide and
hemosiderin to form yellow-to-brown rod-shaped structures with clubbed
ends, often beaded along their length.1® These structures were first
called "asbestos bodies," but now they are frequently referred to by the
more general term, "ferruginous bodies," since identical structures may
result from the coating of fibers other than asbestos.
It has been
hypothesized that this coating, laid down by engulfing macrophages,
renders the fibers biologically less active.
It is thought that a certain balance is achieved between the forma­
tion of asbestos bodies and their dissolution or excretion.19,20
Asbestos bodies found in the sputum are strong presumptive evidence
of asbestos exposure.
Occupational exposure as brief as one day and as
long ago as ten years has been shown to produce sputa containing asbes­
tos bodies.20 Asbestos, bodies in lung smears or tissue (unlike those
in sputum) are commonly found among residents of urban areas who may
never have been exposed to asbestos in the workplace.21-23
Asbestos bodies or fibers have been detected in extra-pulmonary
tissues of persons occupationally exposed to asbestos:
in tonsils,
thoracic and abdominal lymph nodes, pleura, peritoneum, liver, spleen,
pancreas, kidney, adrenals, and small intestine.
The numbers found
appear to be^ f3fittewer_^than in the lung.®>24
c
Carcinogenic Effaafic—Human Studies

°c

The many observations, both case reports and epidemiologic studies,
of cancerous effects among humans exposed to asbestos fibers could be

23

/:

>

01 061 0589

looked at from a number of points of view, but the ones used here are:
types of cancer; fiber type; dose-response relationship; latency; age at
fj^s-t exposure; smoking; indirect occupational exposure; household expoSi«-o- ana residential exposure.
The section on human carcinogenic effects
ollowed by a summary discussion of animal experiments and asbestosi
redrated cancer.
High rates of lung cancer have been observed in asbestos workers
exposed to all commercial asbestos types.
Among some groups of asbestos
workers, approximately 20% of all deaths are caused by lung cancer where
the proportion of deaths expected from this cause would be only about
5%.25 Pleural and peritoneal mesotheliomas* are a frequent occurrence
among occupational groups exposed to chrysotile, crocidolite, and
amosite.
Estimates for certain occupational groups suggest that as many
as 8%-ll% of deaths may be due to mesothelioma, a relatively rare cause
of death in the general population.26
Some occupational groups exposed
to asbestos have, furthermore, demonstrated an excess of other cancers,
especially of the larynx and gastrointestinal tract.
Asbestos exposure leading to an excess of cancer may occur among
groups exposed indirectly, as in shipyard workers or in groups mining
other minerals that may contain asbestos as a contaminant.
Mesothelioma
also has occurred among persons living in the homes of asbestos woScSts
or in the vicinity of asbestos facilities.
Both cigarette smoking and occupational asbestos exposure ind*53ually increase the risk of lung cancer but, together, they act to pro­
duce a risk of lung cancer that exceeds the sum of their separate risks.

Evidence of Lung Cancer
The evidence that asbestos is a cause of lung cancer is over­
whelming.
Lung cancer was first linked with exposure to asbestos in
1935, when three cases of asbestosis and carcinoma of the lungs were
found at autopsy in asbestos textile workers.27,28 Other case reports
followed.
In 1949 the Chief Inspector of Factories of England and
Wales examined 225 deaths from asbestosis or in which asbestosis had
been proved at autopsy.
Cancer of the lung or pleura was found in 31,
or 13.2%.
This was not characteristic of other pneumoconioses; among
6,884 deaths with silicosis at autopsy, for example, only 91, or 1.32%
had cancer of the lung or pleura.29
W- Farther evidence implicating asbestos in the etiology of lung canceL-Came from a matched-pair case-control study published in 1Q5A
Upgh classifying by 5 years or more employment in occupations

Mesothelioma is a term used to refer to a tumor made up of cells from
the pleura or peritoneum.
24

01 061 0590

involving asbestos exposure (steam fitters, boilermakers and asbestos
workers), 10 patients with lung cancer but only one control had been
so employed.30
fcrIn a study■Mregorted one year later, 11 of 113 workers employed in
an asbestos texfftle factory in the United Kingdom for at least 20 years
were found fo have died from lung cancer.
By applying to this group
age-specific mortality rates for lung cancer in the general population,
0.8 deaths would have been expected.
The ratio of observed to expected
deaths, therefore, was greater than 13.31 Continued study of workers at
this factory has shown a reduced risk of lung cancer, although still
two- to three-fold in excess, among workers first employed after 1933,
when regulations for control of asbestos exposure in the United Kingdom
had gone into effect.32,33 Numerous other studies have independently
confirmed an increased risk of lung cancer in various occupational groups
exposed to asbestos.35>34-39

Evidence of Mesothelioma
There is also overwhelming evidence that asbestos is a cause of
pleural and peritoneal mesothelioma.
Cases have been described in per­
sons with occupational and nonoccupational exposures.
The first case
report of a pleural neoplasm related to asbestos exposure appeared in
1933.^0 Additional cases were noted in the 1940s,41-43 an(j -£n 1954 a
peritoneal tumor was reported.44 However, it was not until 1960, with
the publication of a series of cases from South Africa, that the asso­
ciation between mesothelioma and asbestos exposure was generally recog­
nized.
Of 33 South African patients with mesothelioma, 32 gave a history
of occupational exposure to asbestos or residence in a crocidolite min­
ing area.45 Subsequently, a plethora of individual case reports, case
series, case-control studies, and studies of the mortality of occupa­
tional groups have related the occurrence of mesothelioma to a history
of exposure to asbestos.35,39,46-53 The ratio of pleural to peritoneal
tumors varies considerably in different studies, but peritoneal tumors
seem to be associated with heavier exposures and with asbestosis.54-56

Laryngeal Cancer
The evidence casually linking asbestos and laryngeal cancer is
highly suggestive.
In a study of 119 patients with squamous carcinoma
of the larynx and age- and sex-matched controls, 33 with laryngeal can­
cer, but only -S««ieontrols, gave a history of occupational exposure to
asbestos .37-j58 '5ftris‘-'5rfference was striking, and the suggested increased
risk has

since Leen confirmed by similar case-control studies,39 and

25
i <U'

A

01 061 0591

Digestive System Cancer
-- An excess risk of cancers of the digestive system attributable to
occupational asbestos exposure has been suggested by a number of epidemioPTgical studies.25,34,35,60,62-69
^ major problem with these
stu®jgy“ HUL been the inclusion of peritoneal mesothelioma cases among
-all~Qbserved cases, making it difficult to document an increased risk of
any one digestive system cancer independent of that for mesothelioma.
In occupational cohort mortality studies where peritoneal mesothe­
liomas were separated from other cancers of the digestive system, excess
cancers of some sites have been observed.
Among 933 amosite asbestos
factory workers who were first employed between 1941 and 1945, there
were 11 deaths from stomach cancer by 1971 (vs. 4.58 expected); 15
deaths from cancer of the colon or rectum (vs. 7.05 expected), and none
from cancer of the esophagus (vs. only 1.23 expected).25 of 1.779
deaths through 1974 among a cohort of 17,800 insulation workers there
were observed 15 deaths from oropharyngeal cancer (vs. 7.87 expected);
14 deaths from cancer of the esophagus (vs. 5.35 expected); 18 from
stomach cancer (vs. 11.23 expected), and 47 from cancer of the colon or
rectum (vs. 28.63 expected).25.60 other studies of groups exposed to
asbestos examining the risk of these specific cancers after excluding
mesotheliomas are needed to further elucidate the role of asbestos in
cancers of the digestive system.

Other Cancers
Studies of women asbestos workers have suggested possible increases
in cancers of the ovary and uterine cervix.
Among a group of female
English asbestos worker, 4 and possibly 6 deaths from ovarian cancer
were observed while only 2.1 had been expected.55
Investigators from
the Soviet Union have reported significantly increased rates of cervical
cancer among older female asbestos workers; however, the numbers of persons in the study populations were not indicated.35 Findings in these
reports need confirmation elsewhere.

Association of Effects with Fiber Type
There are few studies of persons exposed to a single type of
asbestos, and the studies that are available often lack information
on potential confounding factors such as cumulative exposure, smoking
history, and physical characteristics of airborne fibers.
It is theretssign a scale of relative pathogenicity
For example:
“~S~ Crocidolite mined in the Northern Cape Province of South
Africa and in Western Australia is frequently associated
with pleural mesotheliomas, whereas fewer cases have been
reported for crocidolite from the South African Transvaal.

26

01 061 0592

It has been proposed that this apparent difference in risk
may relate to a difference in physical characteristics of
fibers from these areas—crocidolite fibers from the
Transva^jLrare thicker and longer.70
•

As asbeSb^ proceeds from mine to mill to manufacturing
plant, ft can become subdivided (and fractured), pro­
ducing fibers of smaller diameter and length, with pos­
sibly greater or smaller attendant biological risk.

•

Asbestos thought to be of one type may be "contaminated"
with asbestos of another type.
Lung tissue from men
employed in Canadian chrysotile mining has been observed
to contain tremolite and other amphiboles, often more
than the amount of chrysotile.71

All types of commercial asbestos have been related to high rates of
lung cancer in asbestos workers, and in occupational groups exposed to
chrysotile, crocidolite, and amosite, pleural and peritoneal mesothe­
liomas have been observed.72 Studies of anthophyllite miners in Finland
have shown a slight excess of lung cancer, but no mesotheliomas.^6,37
The lack of mesotheliomas may be due to the small size of the cohort
studied: however, none has been reported from the communities in the
mining area.'J
There is some information suggesting that chrysotile may not be as
hazardous as other types of asbestos.38,47,74-78 The mortality experi­
ence of a cohort of workers employed at an asbestos paper and millboard
manufacturing plant that used only chrysotile asbestos would seem to
bear this out.79
Pleural and peritoneal tumors, as well as excess lung cancer, have
been found in the mortality experience of workers who had mined and
milled New York State talc.80*8*
This talc may contain large quanti­
ties of tremolite asbestos as well as smaller amounts of anthophyllite
and chrysotile.
In Italy, where the talc is reportedly uncontaminated,
mining and milling has not been associated with mesothelioma or excess
lung cancer.8^

Dose-Response Relationship
Evidence that the risk of developing cancer is related to the
degree of exposS&e ^o^asbestos by some quantitative estimate strengthens
the basis for assuming asbestos to be of causal importance.
A precise
dose-response relationship is difficult to establish for any environ­
mental exposure
no less so for asbestos.
However, attempts have
been made for_a£bestos and there is some evidence suggesting that dose

V4

01 061 0593

as measured by severity of exposure and duration of employment relates
to rates of cancer in groups occupationally exposed to asbestos.
jfrrte study concluded that within an age cohort for which data were
most jko^yrarp there was an increasing mortality due to lung cancer with
increasing duration of employment.63 However, rates for individuals
employed the longest were lower than those in the category of next
greatest duration of employment; persons employed longest might more
likely be those whose occupational exposure to asbestos was less intense
or who were themselves less susceptible to cancer and respiratory dis­
eases (for example, persons who do not smoke).
An investigation of mortality among workers at an asbestos textile
factory in England found markedly reduced mortality from lung cancer,
and from other diseases in the presence of asbestosis, with reduction
in length of exposure before 1933.32 Moreover, the risk of lung cancer
and mesothelioma among workers at a Londom asbestos textile and insulat­
ing materials factory was independently found to be related to the
severity and duration of exposure.39,55,83
The respiratory cancer mortality (includes deaths due to pleural
mesothelioma in addition to cancers of the lung and larynx) of a group
of retired asbestos workers was categorized according to cumulative dugt
exposure.
"Exposure" was the product of job-characteristic dust level**®'
in millions of particles per cubic foot (mppcf) and number of years orifc
the job, summed across all jobs held (thus giving cumulative exposure F.
in mppcf-years) .
The result is shown in Table 5.
It can be seen thaMsL
there is a clear gradient of increasing Standard Mortality Ratio (SMR),
or ratio of observed to expected deaths x 100, with increasing cumula­
tive dust exposure.
Table 5
DEATHS FROM RESPIRATORY CANCER BY CUMULATIVE DUST EXPOSURE

Total Dust Exposure
(mppcf-yr)

Number of
Men

Respiratory Cancer Deaths
SMR
Expected
Observed

Under 125

533

15

9.0

166.7

125-249

305

12

4.8

250.0

250-499

328

17

5.2

326.9

:

5Cip74£

-

126

9

1.8

500.0

__

75<^and over

56

5

0.9

535.6

Source:

Chapter Reference 78.

V

28

01 061 0594

The Cancer Latency Period

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v , Owens C o rn in c
F ifa e ro la a . a t a l . . USDC SD M ia s : C o n f id n t ia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

From all"avay.able evidence, the period between first exposure to
asbestos and deatftfrom lung cancer appears to be related to intensity
of exposure.84 AiW!^" workers at an English asbestos textile and insu­
lating materials lactory, an excess mortality from lung cancer was
demonstrated fpllowing a latency of 15 years for those with heavier
exposures, whereas an excess did not appear until 25 years from onset
of exposure for those whose exposures were less intense.39,61,83
Fifteen years is probably the minimum latency period for asbestosrelated lung cancer.
An excess of lung cancer deaths first appeared
among a group of heavily exposed amosire asbestos workers 15 years after
onset of exposure,85 and in a large cohort of insulation workers fol­
lowed from 1967 through 1974 (135,000 person-years of observation), no
applicable increase in mortality from lung cancer was observed before
15 years had elapsed from onset of exposure.
The peak increase occurred
about 30-35 years after onset of exposure.25
In 85% of one series of mesothelioma cases, death occurred more
than 25 years after first exposure to asbestos, with a range of 3.5 to
53 years.86
Another investigator reported a mean latency period of 37
years 87 and among a large cohort of asbestos workers, most deaths from
pleural and peritoneal mesotheliomas occurred 30-35 years after first
exposure 25

Incidence of Cancer and Age at First Exposure to Asbestos
A characteristic of many cancers is a marked increase in incidence
with advancing age.
It is generally acknowledged that the higher inci­
dence of cancer in older persons is not necessarily because their tis­
sues are more predisposed to cancer, but because of the usually long
period between initial exposure and the appearance of diagnosable tum­
ors.^ In fact, with regard to susceptibility of body tissue to cancer,
it has been hypothesized, from experimental animal evidence, that the
tissues of .younger people may be more susceptible to carcinogens but
that, conversely, older people may be more susceptible to cancer because
of a less efficient immune surveillance system.89
In a study of the relative incidence of lung cancer according to
age at first exposure to asbestos, data were obtained on 117 men who
were exposed fnr.jinrp than 20 years and who were followed for an average
of 13 additi&altP&rs-^’-A greater incidence of lung cancer was observed
among men first exposed at older ages.
For those first exposed under
age 25, the annua’riung cancer incidence was 26% of the rate for all
ages; for first exposure between ages 25 and 29 it was 165%; at age 30+
it was 195%.
Tfffise incidence rates were corrected to account for varia­
tion in the duration of exposure, duration of survival after first
exposure, and for the fact that some lung cancers may have been due to
<s%?-Gr

29

oi 061 0595

nonoccupational causes more common among older men.
The data suggested
that susceptibility to asbestos-related cancer may increase with

age.®®’®?
It ffeems unlikely, however, that age per se is a principal factor
in deter®Uflf£"frequency of cancer, and it is not clear whether age
itself plays a-part that is independent of exposure duration and time
elapsed-since first exposure.

Smoking and Asbestos-Related Cancer

i*
Is

0M O -0 30
OQhU

iss

There is strong evidence that cigarette smoking alone is sufficient
to cause lung cancer.
Many studies attempting to examine the effect of
cigarette smoking on the increased risk of lung cancer observed in
groups exposed to asbestos have been deficient in one or more of these
respects:
•

Follow-up periods have been too short to allow accurate
computation of risk after the necessary 15-20 year latency.

•

Nonsmoking asbestos-exposed groups have been very small.

•

Smoking habits have not been completely ascertained.

•

Smoking-adjusted mortality rates from the general population
have not been used for comparison.

A few studies have found that cigarette smoking was insufficient to
account for the increased risk of lung cancer among asbestos workers.
This has been generally accepted as evidence that asbestos can act
independently to cause lung cancer, a view that has been corroborated by
animal experiments and by some evidence suggesting an increased risk
among nonsmoking asbestos workers.62
An investigation of two groups of asbestos workers—one with a high
dust exposure and a high respiratory cancer mortality, the other with a
lower dust exposure and a lower respiratory cancer mortality—found that
their smoking habits were similar.?® This implies that high doses of
asbestos can account for higher mortality among smokers.
Another inves­
tigation, a case-control study of lung cancer patients, revealed an
enhanced risk of lung cancer with asbestos exposure, whatever the number
of cigarettes smoked.62
ifn
the combined effects of asbestos exposure and smoking,
the smoking habits of 1,334 male and 482 female asbestos factory workers
were ^exam^ted in relation to mortality from lung cancer over a 10-year
period. Aflong 955 smokers with severe asbestos exposure, 41 lung cancer
deaths were observed, while only 11.3 were expected for smokers from the
general population.
Among 161 never-smoking asbestos workers with

.severe asbestos exposure, 1.7* lung cancers deaths were observed, while

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
F io e r a ia a . a t a l . . USDC SD H is s : c o n f id e n t ia l in fo rm a tio n ,
n o t t o o e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is c o u r t 's o r d e r .

only 0.2 were expected for nonsmokers in the general population. There
were approximately five times as many person-years of observation in the
smoking group compare^ with the nonsmoking group, but about 24 times as
many lung cancer deatfec among the smokers.90

cohort of 17,800 insulators.
In 9,591 workers with a history of ciga­
rette smoking, 248 lung cancer deaths were observed, compared with 59.5
expected. Among 609 workers who had smoked pipes and/or cigars, two
lung cancer deaths were observed and 1.24 were expected. Of 1,457
workers who never smoked regularly, four lung cancer deaths were
observed, while 1.08 were expected.25 Expected deaths were based on
approximate smoking-specific U.S. death rates.
Further analyses of group data have been performed to examine how
cigarette smoking and asbestos might be acting together.91.92 On a
In another study-; smoking histories were obtained from 11,657 of a
statistical basis it appears that these two independent causes of lung
cancer interact positively.
In the general population, cigarette smokers
have a 10-15-fold excess risk of lung cancer.
One study observed an
excess of lung cancer among smoking asbestos workers compared with
smokers in the general population, but the excess was 92-fold when com­
pared to the general population of nonsmokers.92 This suggests that the
combined effect of smoking and asbestos exposure is greater than the
simple sum of their separate effects.
The relation of this statistical
interaction to the pathogenesis of lung cancer is uncertain. However,
it seems clear that, due to the important enchancement of risk by one
cause complementing the other, the increased risk of lung cancer in
groups exposed to asbestos may be concentrated among those who also
smoke.
There is very little evidence that cigarette smoking increases the
(requency of developing pleural mesothelioma after asbestos exposure,
and no evidence exists that smoking increases the risk of peritoneal
mesothelioma.
Of 9,951 insulation workers with a history of cigarette
smoking, there were 23 deaths from pleural mesothelioma and 47 deaths
trom peritoneal mesothelioma, with none expected.
Among 1,457 workers
who never smoked regularly, there were two deaths from pleural meso­
thelioma, eight deaths from peritoneal mesothelioma, and none expected.2^

Cancer from Incidental Occupational Exposure
Persons who do not work with asbestos directly, but who mav be
incidentally expos ed“jj^r as bentos while working, may suffer excesses of*
cancer.
A 10% ra'hdom'TsampTe 0f shipyard workers, widely distributed

*This is an adjusted figure to compensate for missing smoking inf
mation for the deceased.

31

01 061 0597

•>
■L

-•

throughout the various trades, revealed that some had pleural plaques
and some had pulmonary fibrosis, and retrospective and prospective
coljgrt mortality studies have revealed a 2.5-fold excess risk of lung
cattcej^a^well as a number of mesotheliomas among workers with pleural
plJ^bes .
Even those without X-ray evidence of exposure to asbestos had a
slightly increased risk of lung cancer and a few mesotheliomas.
A study
of sheetmetal workers also revealed a small excess of lung cancer and
one mesothelioma.93-95

Disease in Workers' Households
There are presently 37 reported cases of mesothelioma in persons
whose presumed exposure to asbestos was limited to living in the homes
of asbestos workers.96 However, no comprehensive studies of the dis­
tribution of mesothelioma by age and sex among contacts of asbestos
workers in their homes have been conducted.
The majority of reported mesotheliomas related to household
exposure have been in women, perhaps because they are more likely to
be exposed to asbestos by washing the garments of asbestos workers.96,97
Thirty-five percent of examined family contacts of asbestos workers^^ere
found to have radiological abnormalities characteristic of asbestot Jc“
disease. 72,96

Cancer in the Neighborhood of Asbestos Facilities
On the basis of numerous anecdotal reports, indirect assessments,
and case-control studies, there seems little doubt that both pleural and
peritoneal mesotheliomas may result from some types of residental expo­
sure to asbestos.45,48-50,74,86,98-103 However, there have been no
adequate population-based studies, and an accurate estimate of risk,
where occupational and household exposure are definitely excluded,
cannot be made.
On the basis of one case-control study of mesothelioma
patients, relative risk of mesothelioma was estimated at 2.1 for residentially exposed, and 4.3 for occupational exposed, persons.^9
Two studies have been made of the possible effects of increased
asbestos contamination of drinking water in Duluth, Minnesota, due to
the disposal of taconite tailings into Lake Superior.
No carcinogenic
effects have been noted, but the period of observation was short relat-igeto the probable latency period of environmentally-induced can-

Car-ei-nogenic Effects—-Animal Studies
All commercial types of asbestos—chrysotile, crocidolit^e, amosite.
anthophyllite—have been found to be carcinogenic when tested in mice,
rats, hamsters, and rabbits.
A brief review of evidence derived from

32

01 061 0598

experimental observations is presented below for its value in corrobo­
rating known human cancer risks, predicting other effects, and increas­
ing the plausibility of certain hypotheses on causal mechanisms. A more
detailed treatment of these and other relevant studies in animals can be
found in Appendi^D-.
Intrapleural or intraperitoneal injection of asbestos has produced
sarcomas* and mesotheliomas.
Laboratory animals have not been known to
develop mesotheliomas spontaneously, so that finding even a single such
tumor in an experiment may be significant.
Rats and rabbits receiving
intrapleural injections of crocidolite developed pleural mesotheliomas,
as did rats receiving chrysotile.106 For both these fiber types the
carcinogenic response appeared to be dose-related in another study with
rats.107 Mesotheliomas have also been induced in rats by Russian
chrysotilelOS and in hamsters by various types of asbestos fibers.109
Peritoneal mesotheliomas were observed in rats following intra­
peritoneal injections of chrysotile and crocidolite but not amosite.106
Rats that received intraperitoneally chrysotile milled to 99% <3 pm also
developed peritoneal tumors.HO Mesotheliomas were induced in rats
inoculated with crocidolitelH and in mice inoculated with chrysotile,
112
crocidolite, or glass fiber. J-L
Lung carcinomas and pleural mesotheliomas have followed from the
inhalation of asbestos.
Rats exposed to various doses of chrysotile,
crocidolite, and amosite have developed malignant tumors of the lung
and of the mesothelium.
> H3-115 Among these studies, adenocarcinoma,
squamous cell carcinoma, and fibrosarcoma were reported.
Among groups
of rats that were exposed with varying durations to five different types
of asbestos fibers, all of which produce asbestosis, a dose-response
relationship for malignancies was suggested.6
in this study it was
observed that as little as one-day exposure was sufficient to produce
tumors.
Few data exist about the effects of asbestos administered orally.
One study found that oral administration of asbestos filter material
to rats led to an increased incidence of malignant tumors.116 Car­
cinomas of the lung, kidney, and liver, as well as reticulum-cell
sarcomas, were found.
The available evidence from animal studies relating asbestos type
to differences in carcinogenic potency is limited and inconsistent.
This may be due to the predominant influence of size and shape of fibers,
which may vary from one study to another for each asbestos type.
Min­
eral fibers ^othi3fc?tli3av..asbestos, but of similar size, can produce meso­
theliomas in ra£s after intrapleural or intraperitoneal injection.107,
117,118 Althougitthe carcinogenic mechanism involving fibers has not

A sarcoma is a malignant tumor derived from mesodermal tissue.
33

01 061 0599

been entirely elucidated, a reasonable hypothesis is that it may be
related to morphologic characteristics.
^ftvere are few studies in which fiber size alone has been varied and
adecJ^WSfy^recorded (diameter as well as length).
Furthermore, the
preparation of fibers for experimental purposes may alter mineral
properties.H9* However, smaller fibers are thought to be more active
in producing tumors.

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
F ib e r o i a s , a t a i . . USDC SD M is s : C o n f id e n t ia l in f o r M t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

Noncarcinogenic Effects of Asbestos
Noncarcinogenic effects of asbestos exposure were noted several
decades before the association between asbestos and cancer was recog­
nized.
In 1906, deaths among asbestos textile workers from penumoconiosis were reported in England and France.121,122 These were the first
reports in modern times of the diffuse interstitial fibrosis of the
lung associated with asbestos exposure—"asbestosis."

Asbestosis, which is characterized by a diffuse interstitial f
sis of the lung, is one of the many dust-related lung diseases that
terminal pneumoconioses.
However, unlike some of the other pneumo­
conioses, asbestosis does not predispose to the development of pulmo
ary tuberculosis, nor does evidence suggest that it is causally rela^
to emphysema and chronic bronchitis.123

The signs and symptoms of asbestosis, listed below, are no
different from those for other forms of diffuse interstitial fibrosis;
there are no pathognomonic features.

•

Cough, usually dry, but may be productive

•

Chest tightness or pain

Ball milling of chrysotile, for example, can result in decreased
crystallinity and changes in interlayer branching and surface hydroxyl
configuration.
These alterations have been accompanied by decreased
hemolytic activity.120

qC2

01 061 0600

USDC SD M is s :

re p ro d u c e d o r d is t r ib u t e d e x c e p t in

i r t O rd e r in H a rt v .-O w e n s C o n iin e

C o n fid e n tia l in fo r a a tio n ,

Signs:

aeu

M **

•

Decrements in lung function (decrease in lung
volume and flows)

•

Radiofulifre.1 -abnormalities (chest)

•

Ralesy-basilar

•

Restricted chest motion

•

Clubbing of fingers

•

Cyanosis

•

Cor pulmonale (right ventricle hypertrophy)

•

Pleural effusion.

The earliest and most prominent clinical finding—breathless­
ness on exertion—rarely becomes apparent until after at least a decade
of exposure.
Thus, by the time this "early" clinical finding appears,
the underlying disease process is well under way.
As the disease pro­
gresses, breathlessness may be present even at rest.
The most characteristic physical sign exhibited by the patient
with asbestosis is the presence of dry, crackling sounds (rales), heard
on auscultation at the lung bases and in the axillae during inspiration.
As fibrosis progresses, rales become more widespread and occupy a greater
part of the inspiratory cycle.
Clubbing of the fingers is usually a late feature of asbes­
tosis and is not found consistently.
Cyanosis of the skin and mucous
membranes of the mouth and tongue may also occur in the later stages of
the disease.

Radiographic Abnormalities
Radiographic features of asbestosis are similar to those of
other forms of diffuse interstitial fibrosis of the lung, except for the
frequency of pleural changes, expecially pleural plaques (which should
always signal the possibility of asbestos exposure).
Radiographic
diagnosis of asbestosis is based on the presence of small, irregular,
or round opacities distributed prominently in the lower lung fields.
The earliest changes often occur bilaterally in the cosophrenic angles.
Short, horizontal, linear septal lines (Kerley B-lines), which are
believed to repreajgpt J^yiaphatic obstruction, 54 may also be present.
With time, the abnormal shadows gradually spread upward into the middle
and upper zonas of-lthe lung, fields and become increasingly coarse and
blotchy.
In more advanced cases, a "honeycomb" pattern may be present,

■

35
U o'*

f

»i

01 061 0601

and the outline of the diaphragm and heart may become blurred and
"shaggy." Pleural changes are likely to be present as well, perhaps in
as many as 50% of the cases.

Jtc..
Pulmonary Function Changes
The interstitial fibrosis associated with asbestos exposure is
accompanied by changes in pulmonary function characteristically observed
with interstitial fibrosis from other causes as well.
Thus, while these
changes are not unique to pulmonary asbestosis, they provide useful
diagnostic information when interpreted together with other evidence
such as exposure history, signs and symptoms, and chest radiographic
findings.
Changes in pulmonary function considered most characteristic
of asbestosis are:
•

General reduction of lung volume, especially of
vital capacity (VC)

•

Decrease in pulmonary flow rates such as indicated by
forced expiratory volume in one second (FEV^ q)

•

Impaired alveolar-capillary diffusing capacity,
reflected by reduced oxygenation of the arterial
blood and increased alveolar-arterial PO2 gradient
(alveolar-capillary block syndrome) .

Although it is usually claimed that airway obstruction is
rarely a major feature of asbestosis,123-125 one investigator has
pointed out that epidemiologic studies of lung function have been unable
to clarify the relationship between obstructive airway disease and
asbestos exposure.
She advised that, until further evidence becomes
available, "an open mind should be kept in this regard."54

Asbestosis and Cancer
On the basis of case reports, an association between asbes­
tosis and lung cancer was suspected as early as the 1930s.
More than
a decade later, two authorsl26,127 reported that, among British asbestos
workers, carcinoma of the lung and pleura had been found in about 15% of
deaths either caused by asbestosis or in which asbestosis had been
proved present at autopsy.* By the period 1961-1963, figures from the
Br^jjpeh^Mipistry of Labour showed that approximately 50% of patients
certified as suffering from asbestosis (in contrast to exposed to

4ETt remained for another investigator
to show that the actual risk of
dying from lung cancer was increased on the order of 10-fold over the
general population for male asbestos workers employed for 20 years or
more between 1922 and 1953.
36

V

asbestos) died of (or with) lung cancer.
Although carcinoma of the
lung is often found’ in the presence of asbestosis, there appears to be
no scientific evldefree that the two lesions are interrelated, except
that they both may ^^iajsified as diseases that are causally associ­
ated with exposure To asbestos.
With regard to another asbestos-related cancer, two reviewers
of the subject have noted that mesothelioma of the pleura and peritoneum
has often been associated with even low levels of asbestos exposure for
brief periods in the remote past.54,123 There appears to be no regular
correlation between severity of asbestosis and occurrence of mesothe­
lioma.
In fact, it is unusual to find significant pulmonary interstitial
fibrosis (asbestosis) with pleural mesothelioma.
However, prominent
asbestosis is frequently observed in association with tumors of the
peritoneum,54,123 and peritoneal tumors generally appear to be associ­
ated with heavier asbestos exposure.45,130 One reviewer noted that this
appears to support the notion of retrograde lymphatic spread of asbestos
fibers from the lung to the abdominal lymphatics resulting from thoracic
lymphatic obstruction due to advanced pulmonary fibrosis.54

Asbestos Pleural Effusion
Benign pleural effusion, which usually occurs in the presence of
some degree of parenchymal asbestosis, is another clinical manifesta­
tion of disease due to asbestos exposure.
Among a series of 57 patients
with asbestosis or asbestos exposure, 12, or 21%, were found to have
"asbestos pleural effusion"—i.e., a pleural effusion in an individual
with a history of occupational exposure to asbestos in the absence of
any other disease known to cause pleural effusion.131 A number of
individuals diagnosed as having had asbestos pleural effusion have sub­
sequently developed mesothelioma.3-32,133

Pleural Calcification, Diffuse Fibrosis, and Plaques
Asbestos-related plaques occur as discrete, elevated, grey-white
lesions on the inner surface of the rib cage and on the diaphragm.

The reason for th^- apparent increase in the percentage of deaths in
which asbestosis and Tune cancer were found on autopsy is not clear.
One explanation msy-be that the cases described by earlier
authors3-26,127 received much of their asbestos exposure in the early
quarter of the centruy, when it was likely that airborne concentra­
tions of asbestos were high.
As a result, many of these cases may
have succumbed to asbestosis at an early age—before lung cancer, with
its long latent period, could develop. 3-28,129
37

01 061 0603

Microscopically, the plaques consist primarily of connective tissue,
often containing deposits of calcium.
They do not interfere with
pulmonary function to any significant extent, nor do they necessarily
iRTl&ate the presence of pulmonary fibrosis.
_
An association between pleural abnormalities and exposure to
asbestos—both occupational and nonoccupational—has been clearly demon­
strated. 54,123,134-139 Accordingly, their presence should always alert
the examiner to the possibility of asbestos exposure.
In this regard,
it may be 20 to AO years after exposure to asbestos that pleural
calcifications appear radiographically.135
Although pleural plaques do not, themselves, appear to be precur­
sors of malignant disease, a retrospective death-certificate study of
A08 shipyard workers with pleural plaques showed that the risk of
developing bronchial carcinomas was increased by a factor of 2.4.95
Three cases of mesothelioma also occurred in this series.
In a pro­
spective study from the same shipyard, 235 men with radiographic evi­
dence of pleural plaques were found to have a 2.4-fold increased risk of
bronchial carcinoma.
Among 70 deaths, 13 were due to mesothelioma,
an excess of obvious significance.9^

Asbestos Warts
Asbestos warts, or corns, are of minor health significance,
they are an indication of exposure to asbestos.
They are caused w
asbestos fibers penetrate the skin and are most often found on the hands
and forearms.140 The warts may have a pinpoint, black center and are
often tender to pressure.
Unless removed by excision, they may persist
for years.

Animal Studies—Evidence of Noncarcinogenic Effects
Exposure by inhalation to any of the four commercial asbestos t es
may result in fibrosis of the lungs in animals as well as in humans.'K 1
Under experimental conditions a fibrogenic response to inhaled asbestos
has been reported in rats, hamsters, guinea pigs, rabbits, and mon­
keys .142-144
Outside the laboratory, pulmonary fibrosis in the presence of fibers
and asbestos bodies has been demonstrated in baboons, donkeys, and wild
d^fnfes~Living in the vicinity of crocidolite mines or mills. 145
Pulmonary asbestosis has also been reported in a dog kept as a rat
cJEcher in a London asbestos factory.146 There are marked interspecies
differences in susceptibility to asbestosis.
Tissue reaction in rats,
’
’
s is typically less severe than in hamsters and

38

01 061 0604

it

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
F ib e r o ia a .
t l . . USDC SD M is s : C o n fid e n tia l in fo r m a tio n ,
o o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is c o u r t 's o r d e r .

Subcutaneous injection of asbestos or injection into the pleural
or peritoneal cavities produces a fibrotic reaction.
Thickening of the
pleural, pericardial, and peritoneal membranes has been reported, with
formation of adhesfcms and granulomas as well as pulmonary and mediaL48,149
stinal abscesses.-17714''
Neither shape‘*Ror chemical composition is sufficient to explain the
fibrosing effects of asbestos.
Fibrosis has been induced with a variety
of fibrosis as well as nonfibrosis mineral dusts.
Some investigators
feel that fibers are more fibrogenic than nonfibrous particulates and
that fibrogenic reaction increases with increasing fiber length.
How­
ever, the role of fiber length is difficult to evaluate without simul­
taneously taking into account possible effects of diameter and aspect
ratio (length/diameter).
On injection, chrysotile heated to 400°C caused fibrotic reaction
in the pleura of mice equivalent to that of unheated chrysotile, but
fibrosis production diminished as temperatures increased above 400°C
(at 600°C, 800°C, 1000°C).
Asbestos in dust from automobile brake
linings, which are subjected both to high temperature and mechanical
grinding, resembled chrysotile that had been heated to 800°C or more
and then ground.^
Effects of asbestos that may be related to fibrogenesis have been
observed in vivo in mammalian tissues as well as in cell culture.
Bio­
chemical changes, including stimulation of anaerobic metabolism, and
physical effects such as damage to cell membranes and chromosomes have
been noted.^O-ISS

Such observation^nray shed light on the mechanisms by which asbestos
induces fibrosisJIZEor example, it has been postulated that during
phagocytosis, asbestos causes damage to the membranes of macrophage
lysosomes, which are cell organelles that contain lytic enzymes.
Sub­
sequent intracellular release of these enzymes may injure or kill the
macrophages, resulting in release of a fibrogenesis-stimulating factor.^9
39

!1 , '

V i

01 061 0605

fcr-Chapter IV
OCCUPATIONAL EXPOSURES

There is little recent data in the published literature on expo­
sures to asbestos, and it is difficult to assess whether what has been
published is typical.
Furthermore:
•

Occupational asbestos concentrations are commonly
reported as optical-microscope-visible fibers per
milliliter greater than 5 pm long, and these may
account for only a small fraction of the total
electron-microscope-visible fibers

•

It is not known whether small differences in fiber
counts actually reflect differences in fiber levels
or, if they do, whether they indicate a change in the
risk of incurring asbestos-related diseases (see
Appendix C).

Nevertheless, quantitative air sampling data from representative occupa­
tions is provided in this chapter in an attempt to indicate the range of
exposures found in three workplace situations:
asbestos mining and
milling, production and processing of asbestos products, and utiliza­
tion of asbestos-containing products.
Fewer than 600 persons in the United States are employed in mining
and milling asbestos.* However, industries that manufacture asbestos
products or that make use of them provide jobs for millions.
These
industries may be categorized as primary, secondary, or consumer accord­
ing to whether they produce manufactured goods from raw asbestos fiber,
process asbestos manufactured products to make other products, or
utilize a finished product containing asbestos without additional modi­
fication.
Over 37,000 persons are employed in the manufacture of primary
asbestos products; 300,000 are employed in secondary asbestos industries;
and millions more work in the asbestos consumer industries—over 185,000

Many more may be exposed to asbestos as a contaminant during the
mining and milling of other minerals.

41

01 061 0606

of them in shipyards and almost 2 million in automotive sales, service,

in Mining and Milling
Sources of asbestos exposure in mining and milling include blast­
ing, crushing, transporting, and drying ore; air-aspiration milling;
and disposing of waste.
Time-weighted-average (TWA) levels of fiber in
mining reported in 1973 ranged from 0.5 to 2.8 optical-microscope-visible
(o-m-v)* fibers per milliliter, with an average of 0.9.
Much higher
concentrations were found in milling, where exposures ranged from 6.0 to
12.1 fibers per milliliter.2
In addition to mining and milling of asbestos, the mining and mill­
ing of other mineral ores that may contain asbestos as an impurity is
a potential source of asbestos exposure.
For example, concentrations
of asbestiform fiber in one hard-rock gold mine were reported in 1976
to average 0.25 o-m-v fibers per milliliter, ranging up to 2.8,3 and
fiber counts of 8 to 260 per milliliter were recorded in a talc mining
and milling operation, according to a 1973 report.^

Exposures in the Asbestos Products Industries
For all segments of the primary industry, manufacturing begl
i
fiber receiving and warehousing.
Levels of airborne fiber in th€
areas have ranged from 0.2 to 2.5 o-m-v fibers per milliliter and are
typically about 1.0.+ Levels at the upper limit of the range reflect
damaged shipments, careless unloading or ineffective housekeeping.
The
most important factor influencing asbestos exposure at this step of
production is the condition of the bags in which asbestos is shipped.
Next, asbestos fibers are introduced into the process.
Bags of
asbestos are usually cut open and dumped manually, either into open
hoppers or into bag opening enclosures.
This activity can result in
relatively high exposures if hooding is inadequate or lacking.
Disposal
of the emptied bags may also add to airborne fiber levels.
In four of
the seven major primary industries, highest TWA exposures occur in fiber
introduction and have ranged from 0.3 to 10.0 o-m-v fibers per milli­
liter,
typically somewhat above 2 fibers.
Exposures in mixing and blending depend upon how dry the materials
IS??. £bafc._are being mixed, the intensity of agitation, and the effective­
ness of ventilation.
Typical TWA values in the past have been

Greater than 5 micrometers in length.
^Data in this section are from Chapter Reference 1 (published in March
1976).
42

01 061 0607

approximately 2.2 fibers per milliliter, with a range of 0.2 to 10.0
fibers per milliliter.
Sometimes asbestos is dumped directly from the
bags into mixing-or blending tanks, augmenting the usual exposures foui
at this step. Once the asbfcWifTIb ers are engulfed by a medium that prevents
them from beceming_airborne, exposures drop.
This may occur at the st<
of mixing and blending—as in the production of floor tile, paper, and
cement pipe—or in a subsequent step.
Exposure levels in formulation operations have ranged from 0.2 to

22.0 fibers per milliliter, with an average level of 1.8 fibers per
milliliter.
This wide variety of exposures is due to the number of
different processes represented by that stage.
Finishing operations vary significantly from one type of industry
to another, but usually include machining (i.e., cutting, drilling,
grinding) the rough product to specification.
The mechanical energy
imparted during machining causes asbestos fibers to break loose and
become airborne.
Average TWA levels of exposure in these operations
have ranged from 0.1 to 8.0 fibers per milliliter, with a mean of 1.6.
In the last two production steps—inspection, and storage and
shipping—asbestos exposures are usually the result of airborne dust
generated by other operations, which may drift through the plant to
these areas or adhere to the products themselves,- becoming airborne
during handling.
Exposures are typically less than 1 fiber per milliliter.
Exposure levels in the major asbestos industries are summarized in
Table 6 and are discussed below.^

Friction Products
Friction products may contain 30% to 80% asbestos, and TWA exposur
in the industry vary widely (0.1 to 15.0 o-m-v fibers per milliliter),
averaging 2 fibers per milliliter for most operations.
Greater concen­
trations may occur in preforming operations, ranging from 0.5 to 22.0
fibers per milliliter and typically about 4 fibers per milliliter.
The
elevated exposure levels found in these operations result from manual
handling of the dry preform mix (asbestos fibers and metal reinforcing
materials in an organic matrix), which is conveyed in open carts,
scooped by hand, weighed, and poured into a block mold for mechanical
pressing into ^the ■pipe, refL the finished product.
>

Other operatltSrs that may yield high asbestos levels include fiber
introduction, mixing of the dry preform, and finishing.
During finish­
ing, the products*are trimmed, drilled, sanded, ground, and sawed to
specification.
Exposures vary with work practices and equipment.
For
example, exposures at ventilated radial grinders are below 2 fibers per

43
i

01 061 0608

Table 6
EXPOSURE TO AIRBORNE ASBESTOS IN SELECTED
ASBESTOS PRODUCT MANUFACTURING INDUSTRIES

Asbestos Concentrations
(Time-Weighted Average In Flbers/ml)a
Most Operations
Operations with Highest Levels
Name of
Typical
Range
Typical Range
Operatlon(s)

Number of Employees
Production
Workers
Total

Friction Products
Primary

2

Secondary

0.1-15.0

0.5-22.0

2.5-6.5

Forming or
Rolling

4,900

Fiber Intro­
duction

1,100

Fiber Intro­
duction

900

7,300
34,500

Asbestos Paper
Primary
Secondary
AsbestosReinforced
Plastics
Primary

1

0.3-2.8

1.0-3.5

1

Secondary
Cement Pipe

0.75-2.7

0.2-2.5

0.5-3.0

0.5-2.0

4,500
198,000

2,600
11,000

1.5

0.25-3.5

0.6-4.5

Finishing

1,600

2

0.3-8. 7

0.9-8.4

Dry Mixing,
Sanding

600

2,400

Cement Sheet
Primary
Secondary
Floor Tile

1.0-6.0
1

0.5-4.3

0.9-4.3

Fiber Intro­
duction

2,900

4

0-25-10

2.0-10

Carding

2,400

Textile
Primary
Secondary
Paints, Coatings
and Sealants

2.0-6.0
1

1.0-2.5

1,300
24,000
6,700

3,700
7,500

1.5-8.0

Fiber Introduction

350

3,000

aOptlcal-oicroscope-visible fibers, 5 um long or longer.
Sources:

Daley AR# Zupko AJ, Hebb JL:
Technological feasibility and
economic Impact of OSHA proposed revision to the asbestos
standard.
Roy F. Weston Environmental Consultants-Designers,
MAJtch 1976 (prepared for: Asbestos Information Association
“'ofTTorth America).

44

01 0G1 0609

|
i
i

milliliter, but chamfers and backgrinders may cause exposures of 5-8
fibers per milliliter.5 If the finished products have not been cleaned
of adherent particulates, exposures may be high during inspection (4-7
fibers per milliliter).

Asbestos. Papner
Exposure levels in the asbestos paper industry vary with the
asbestos content of the manufactured product, which can range from 5%
to virtually 100%.
Typical TWA concentrations in the primary industry
average 1 o-m-v fiber per milliliter (range 1-3 fibers per milliliter)
except in fiber introduction and stock preparation (wet blending),
where concentrations typically average 1-3 fibers per milliliter and
range up to 10.
The lower concentrations are achieved in plants which
use disintegrating, pulpable bags, thus obviating bag opening, dumping,
and disposal.
33

ric h t h is C o u r t'

J) V U
MOO
eH*-g
* m

Since papermaking is a wet process, little asbestos dust exposure
is realized after fiber introduction until the product is dried.
Expo­
sure concentrations may then be elevated somewhat by the manual handling
and mechanical modification (slitting, calendering, converting, etc.)
needed to prepare paper sheet according to specifications.

Asbestos-Reinforced Plastics
The asbestos content of reinforced plastic is relatively small,'*'
and reported exposures in both primary and secondary industries are
lower than in most other segments of the asbestos industry.
TWA concen­
trations during most operations range from 1.0 to 2.5 o-m-v fibers per
milliliter.
Fiber introduction, dry blending, and handling of the
blended mixture and preform are sources of moderate levels of exposure.
After the preform has been remelted, the asbestos is bound tightly in
the polymer matrix, reducing the potential for airborne release.
Fibers may still break free, however, during finishing.

Asbestos-Cement Pipe and Sheet
Asbestos-cement products may contain 10% to 70% asbestos.
Although
more asbestos is used in manufacturing asbestos-cement pipe and sheet
than any other primary asbestos products, relatively few workers are
employed in these branches of the industry (3,600 total, 2,200 in pro­
duction).!
.
In asbesJzos-ijEment pipe factories, TWA fiber levels range from
0.5 to 4,5 o-m-v f-ibers per milliliter, averaging about 1.5.
In the

0r

45

01 061 0610

manufacture of asbestos-cement sheet, some fiber-introduction and dry­
mixing operations may yield higher exposure levels (0.3 to 8.7 fibers per
milliliter) than in the manufacture of asbestos-cement pipe, because
fiber may be introduced directly into the dry mixer.
Once fibers are
en fed. fed by the cement mortar during wet mixing, there is little opporthem to become airborne until finishing.
Higher levels
(averaging above 2 fibers per milliliter) may be found during cutting
anJTnachining in cement pipe factories; and sheet trimming and sanding
present the highest levels of exposure in the asbestos-cement-sheet
process, generally about 2.5 and 3.0 fibers per milliliter, respectively.

Floor Tile
Asphalt or vinyl asbestos floor tile contains 8% to 30% asbestos.
Airborne TWA asbestos concentration ranges from 0.5 to 5 o-m-v fibers
per milliliter.
Typical concentrations are approximately 1 fiber per
milliliter, except for fiber introduction, where concentrations of 4
fibers per milliliter are common.
Once the asbestos is engulfed by the
agglomerated plastic during the later phases of mixing, the potential
for exposure is reduced significantly.

Asbestos Textiles
Levels of exposure in primary and secondary production of asbefcfeasw^
textiles vary directly with the asbestos content of the manufacture^^
products but generally are higher than in any other asbestos indust^Sbesides milling. A typical TWA concentration of airborne fiber—i.’e.,
for most operations—in the primary textile industry is 4 o-m-v fibers
per milliliter (range 0.1 to 22.3 fibers per milliliter) except in the
carding operation, where the typical concentration exceeds 5 fibers per
milliliter (range 6.1 to 27.3).
High asbestos exposures in the asbestos
textile industry result from the processing of dry—or, at best, par­
tially damp—fibers, which are easily dispersed into the atmosphere.
During carding, the vigorous manipulation of the dry fibers to separate
and align them accounts for the particularly high concentrations observed
at this step—even in the face of intensive efforts to achieve effective
ventilation.
The liquid dispersion method of asbestos textile manufacture, in
which asbestos fibers are mixed in water with chemical dispersing agents,
results in much lower exposure levels (less than 1 fiber per milliliter)
than in conventional plants.6 Moreover, the use of asbestos textiles

' c
vgfvx

46

01 061 0611

made from dispersed yarns results in significantly lower asbestos
exposures to the user than from conventionally manufactured products.^

Exposures in thefctilization of Asbestos-Containing Products
With two notable exceptions, the insulation trades and clutch and
brake installation and repair, levels of exposures to workers in the
consumer industries are generally very low.
But although exposure
levels are low, the vast majority of workers in the asbestos consumer
industries, it is surmised, are less aware of the health hazards of
asbestos than are workers in the production industries and may not
utilize basic control methods to minimize risk.

Insulation Trades
Exposures in the insulation trades vary widely, but they include
the highest occupational exposures and control is difficult.
In the
early 1970's, there were approximately 36,000 insulation installers®
employed largely in insulating industrial equipment, commercial buildings,
and ships.
It is difficult to obtain characteristic exposure levels for
these workers due to the many different insulating materials and condi­
tions of work.
The asbestos content of materials in use ranges from 10% to almost
100%.
Asbestos substitutes are gaining in use as regulations over the
use of asbestos become increasingly more restrictive.
Jobs performed by insulation workers can be classified into six
categories:
•

Prefabrication: materials are precut and shaped using
hand or power saws either on the job or at the con­
tractor's shop (10% of time).

•

Application: Materials are fitted, hammered, or carved
and attached to surfaces by wiring or gluing (40% of
time).
Some materials used to be sprayed applied, but
this practice has been virtually eliminated in recent years.

•

Finishing: Materials are coated with asbestos-containing
cement, resin, asbestos or cotton cloth, or petroleum
based sealer (30% of time).

•

"Rip-outlii. Removal of old or unusable materials in the
process 4p^eittSt»iating (10% of time).

•

Mixiiig: Sjfcneral wool, asbestos, fiber glass, and cement
or glue a^e—mixed in buckets or troughs separately or
in cnmhiflJT-rnn (5% of time) .

•

Miscellaneous:
(5% if time).

»

Cleaning up, transporting materials

47

01 061 0612

Percent of time at each task is highly variable, of course, and intended
only as a rough guide.9
Highest concentrations encountered by insulation workers have
occurred during "rip-out" or removal of old asbestos insulations.
In a
196
"' on air samples collected on a ship during removal of
asbestos coatings, removal of 100%-asbestos lagging, and subsequeirt- cleanup were said to average 248 o-m-v fibers per milliliter,
62-159 fibers per milliliter, and 353 fibers per milliliter, respec­
tively; in comparison, the application of pipe lagging containing 15%
asbestos resulted in exposures of 5-60 fibers per milliliter, and cut­
ting and drilling incombustible board prior to installation yielded
exposures of 0.7-4.5 fibers per milliliter.10 Levels of 30-100 o-m-v
fibers per milliliter have been reported ruing application of spray
asbestos insulation.H Nearby workers may be exposed to elevated
levels of asbestos as the result of.the activities of insulators—
especially in shipbuilding, where work often goes on in enclosed poorly
ventilated spaces.

Brake and Clutch Repair
There are almost 2 million persons employed in automotive sales,
service and repair, of whom 900,000 are said to be frequently expose^^^
to asbestos from automotive brake and clutch repair.-'(Note that this1'-'-'
figure does not include persons who repair other kinds of brakes and
clutches.)
Asbestos exposures were determined for specific brake servicing
operations including blowing-out automobile brake drum assemblies,
grinding used truck brake linings, and bevelling new truck brake linings.
Average peak o-m-v asbestos air concentrations for these activities
based on sampling within 10 feet of the operator were 10.5, 3.75, and
37.3 fibers per milliliter, respectively.12
In a similar study, mean concentrations found 3-5 feet, 5-10 feet,
and 10-20 feet from an operator blowing dust out of brake drums were
16.0, 3.3, and 2.6 fibers per milliliter.
Grinding truck brake shoes
gave average concentrations of 4 fibers per milliter, and bevelling
produced an average count of 37 fibers per milliliter.
Measurable con­
centrations (0.1 fibers per milliliter) were found at distances up to
75 feet from the blowing-out operation (14 minutes after), 60 feet from
grinding, and 30 feet from bevelling, indicating that other garage
employees besides those directly involved in brake and clutch repair
are..at risk.J-3 Another study estimated the time-weighted average
-expo^fe’e^-fS'r-brake mechanics to be 0.8 o-m-v fibers per milliliter.^

installation of Floor Tile, Roofing, and Siding
There is limited information relating to levels of exposure during
installation of asphalt or vinyl asbestos floor tile.
Because asbestos
48

01 06i 0613

Installing asbestos roofing and siding should result in exposures
of lesser magnitude since these operations are performed outside.

Use of Spackling, Patching, and Taping Compounds
Asbestos may be a primary component of spackling, patching, and
taping compounds used in wallboard construction to finish joints and
repair damage, or it may be a contaminant of talc, limestone, or other
rock used as raw material. Used mostly in the construction industry,
the compounds are also used by persons doing their own construction
and repair, and intermittent exposure to asbestos may occur during
mixing, application, and sanding (finishing).

.

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . Owens C o rn in c
P ib B r o la g . a t a l . USDC SD M i* s : C o n fid n tia l in fo rm a tio n ,
n o t t o £»• c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

fibers are firmly imbedded in the tiles, installation per se is unlikely
to be a source of important asbestos exposure.
It is accepted practice,
however, to sand bid asphalt or vinyl tile floors before installing new
covering.
Conventional belt sanders with coarse grit are used to sand
the tiles, and, normallv. 240 to 250 square feet of tile can be sanded
per hour.
One regfrft states that levels of 1.2 and 1.3 o-m-v fibers
occurred during a “simulation of normal sanding activities over a short­
term sampling period.15 it is likely that fiber levels fluctuate
significantly depending on the age and condition of the tile being
sanded, grade of sandpaper, speed of the sander, size of the workspace,
ambient humidity, and quality of ventilation.

To determine possible exposure during application, air samples were
collected at various jobs and sites.
Peak airborne asbestos concen­
trations measured during such operations as hand sanding, pole sanding,
mixing of dry spackle with water, and sweeping-up averaged 2.3 to 47.2
optical-microscope-visible fibers per milliliter.16
All exceed the current OSHA occupational standard for an 8-hour
time-weighted-average (2 fibers per milliliter), and many exceed the
permissible ceiling (10 fibers per milliliter).

Wearing Asbestos Garments
Tests of wearing asbestos garments have indicated that breathing
zone concentration can exceed 2 o-m-v fibers per milliliter.
At one
plant where hoods, coats, mittens, and leggings were worn, concentra­
tions of airborne asbestos fibers ranged from 9.9-26.2 fibers per milli­
liter, and the 8-iM»ur time-weighted-average concentration was 4.7 fibers
per milliliter.
-•
Exposures f romwearing fire-fighting helmets also have been mea­
sured.
A new helmefe-with an unlined asbestos cover, an identical older
helmet, and a helmet covered with aluminized asbestos cloth produced
breathing zone concentrations of 2.3, 1.4 and 0.0 o-m-v fibers per
^
milliliter, respectively. 18

49

01 061 0614

? ,5 i'

;V.• .Si'ViA:■

:i

i.
Chapter V
[ONOCCUPATIONAL EMISSIONS AND EXPOSURES

Persons not employed in asbestos-related occupations are exposed
to asbestos fibers that originate from natural sources or from mancreated sources such as the manufacture and use of asbestos products.
Such asbestos may be inhaled—as, for example, in an office building in
which the air is contaminated by asbestos insulation—or it may be
ingested with water, food, and drugs.
As would be expected, the further
one gets from the occupational environment, the fewer data there are on
such exposures—termed "nonoccupational" exposures.
However, the avail­
able data are reviewed here to provide at least some indication of
possible general environmental contamination.
(See Appendix C for a
discussion of the difficulties in measuring asbestos contamination.)

Asbestos Emissions from Natural Sources
Rock that contains asbestos can be disturbed by natural means, such
as weathering or landslides, or inadvertently by such human interven­
tions as road building, construction, and tilling of the soil.
In such
cases, free asbestos fiber may be deposited onto soil or enter air and
water,^ thereby contributing to levels of contamination in the ambient
air and in water as discussed in this chapter.
The occurrence of rock formations that could possibly contain
asbestos was discussed in Chapter I of this monograph, and the geograph­
ical distribution of such rock formations in the United Stated is shown
in Figure 1.
If the primary areas of source rock are looked at in
conjunction with high population density, the most critical areas for
emissions from natural sources appear to be eastern Pennsylvania, south­
eastern New York, southwestern Connecticut, and greater Los Angeles and
San Francisco.

Asbestos Emissions from Human-Created Sources
Human-created sources of nonoccupational exposures to asbestos
include th§ uiln^g and milling of asbestos; the transportation of asbes­
tos materials
ptoHucts; the manufacture, installation, use, and
demolition^of aj^estos products; and the disposal of wastes.
Some gross'"estimates of annual emissions in the United States
from asbestos mining and milling, manufacturing, use of asbestos

51

01 061 0615

products, and disposal of wastes have been made and are shown in Fig­
ure 2.
Although these estimates are uncertain, by at least an order
of magnitude, several important conclusions are indicated:

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . O w ent C o rn in c

F ih g f o ia a . a t a i . . USDC SD M is s : C o n fid e n tia l in t o r * a t io n ,
n o t t o o # c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

• Asbestos is preponderantly disposed to land, least to
^“water.
•

Most of the asbestos disposed to land is consumer waste,
which is more likely to be disposed to uncontrolled
waste dumps and handled by persons unaware of the
hazards.

•

Disposal to land is an important source of atmospheric
asbestos and, because of proximity to urban popula­
tions, may be even more significant to health than
the emissions to air that come from mining and milling.

Redistribution and Fate of Asbestos in the Environment
Because asbestos is exceptionally resistant to thermal and chemical
degradation, it persists in the environment and can be widely redis­
tributed by both natural forces and human means.
The magnitude of
this redistribution is governed by an extraordinarily complex set of
factors which include the height of the emission source, the rates of'
air and water flow, fiber diameter, rain, thermal air inversions,,
electrostatic forces, agglomeration of particles, and the density of
vehicular traffic on asbestos-containing landfill, to name only a few.

Redistribution by Air
If, for example, asbestos is emitted to air as part of a "large"
agglomerated particle, it will settle to earth relatively quickly and
thereby have a limited potential for environmental contamination; thus,
concern over the relatively large quantities of asbestos emitted to
air from mines is somewhat attenuated by knowledge that the mining
processes tend to produce relatively large particles.
At the same time,
however, an appreciable fraction of the large mass of asbestos dis­
charged by mills is in the form of free fibers that may remain in the
atmosphere for long periods of time, travel great distances, and expose
many people.
Studies of atmospheric pollution in the area surrounding
asbestos mines and mills in Finland showed small amounts of asbestos
dust as far away as 27 kilometers.2
Sp&impEt#ied calculation of "drift distance" for two sizes of
^
asbestbs fibers was made for this monograph using the method of Cowherd
at\d a 'jrerminal settling velocity as determined according to Harris.^
Fiberfwwere presumed to be injected at a height of 50 feet (15.2 meters)

/

52

01 061 061G '

into a constant crosswind of 10 mph (4.5 meters/second) with no net
effect of turbulence.
The locality was assumed to be rural with a
"roughness height" equivalent to that of a wheat field.
A small fiber,
one’with a diameter of 0.1 micrometers and length of 10.0 micrometers,
undejt-such conditions would drift 1120 kilometers; a large fiber, 1.0
micrometer in diameter and 50 micrometers long, would drift 13.3 kilom­
eter?:’

Redistribution by Water
Asbestos borne by water can also travel considerable distances.
Studies of Lake Superior, reported in 1974, indicate that asbestos
particles can move several hundred miles or more.5 Another report,
made in 1976, shows that high river flows in surrounding regions have
resulted in unusually high fiber counts in the Philadelphia and Atlanta
water supplies.6
Water samples taken from wells located in areas containing asbestos
rock have shown elevated concentrations of asbestos. A well at Malvern,
Pennsylvania, drilled in a belt of serpentine rock, had an asbestos
content of up to 0.157 micrograms per liter, in contrast with a well at
Glendale, Arizona, in an area known not to have such rock, which had an
asbestos content of 0.023 micrograms per liter or less.7

The Ultimate Fate of Asbestos Fibers
Very little has been reported on the ultimate fate of asbestos
fibers once they are released to the environment. While it is known
that fibers can be readily subdivided by mechanical means into fibrils
of submicron diameter, it has not been established if fibers are sub­
divided by natural means.
It does seem likely, however, that natural
forces such as erosion, grinding, abrasion, moisture, and temperature
gradients would cause their eventual subdivision.
All types of asbestos resist prolonged attack by strong alkalis.
However, it has long been known that hydroxyl groups of chrysotile,
in contrast with other asbestos types, will react with weak acids and
even water, causing magnesium and silicon to be released from the
crystal lattice.8-10 Generally, despite some degradation, it is felt
that the fibrous morphology is retained.8 Thus, to a limited extent,
chrysotile may undergo decomposition through reaction with water and
acid present in the environment.
'^mpefifnires required for thermal decomposition of asbestos are
seldoi^attained in the natural environment.
With chrysotile, dehydrafion trecurs at about 100°C, and full dehydroxylation is achieved at

>

54

V

01 061 0618

'i
t
800°C.^

Thermal decomposition of amphibole asbestos occurs at somewhat

higher temperatures.

n o t t o o i c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
e c c o rd e n c e w it h t h is C o u r t 's o r d e r .

P ro d u c e d u n d e r C o u rt O rd e r in H * rc v - Owens C o rn in g
F if a t r o ia n . « t » ! . . USDC SD M i* s : C o n fid e n tie l in fo r m a tio n ,

Exposure to Airbaru«' ftnh estos
As one woul.3~expect, airborne asbestos can be found in the vicinity
of asbestos mines, mills, manufacturing facilities, and waste dumps.
But elevated levels of fibers also may be found near concentrations of
braking vehicles, in buildings in which asbestos spray products have
been used, and in cars and homes of asbestos workers who have contamin­
ated them with dust brought from the work area on clothing, body, or
equipment.
Asbestos may be inhaled by persons who install their own
asbestos roofing or flooring, or who repair such items as automobile
brakes and clutches, home heating and plumbing systems, wires for
toasters and waffle irons, or the walls of their homes.
Other situations with possible exposures to airborne asbestos
include the use of roads and driveways surfaced with asbestos-bearing
gravel or paving, humidifiers charged with water containing high levels
of asbestos, talcum powders, paints containing asbestos, and cigarettes
with asbestos filters (reportedly no longer used in U.S. cigarettes).
Even powdered pdpier mache mixes, which are widely used in elementary
schools, have been found to contain 50% or more asbestos.H
These exposures may be of a one-time or intermittent nature, but,
because of the cumulative permanence of a small portion of inhaled
asbestos, they contribute to a person's total risk.
Asbestos is also found as a contaminant in the ambient air, and
this source is treated first in the review of exposure sources that
follows.

Exposure from Ambient Air
The large majority of the U.S. population does not live in areas
that have elevated levels of atmospheric asbestos due to asbestos min­
ing, milling, manufacturing, or construction.
Nor are most people
involved in part-time installation or repair of asbestos products.
Ambient air, therefore, constitutes the basic source of atmospheric
exposure for the population at large.
There is. a*'jjjjjeijty..j?f atmospheric asbestos-concentration data,
due, in part,* to Tifre cost and difficulty of obtaining it.
Moreover:
data have sometime-been reported as mass of asbestos per volume of air
(most often the case)* while sometimes as concentration of fibers;

Appendix E contains data from several studies.

v

v

55

01 061 0610

usually only chrysotile asbestos has been measured; and the procedures
for measuring, and hence the precision of the measurements, have varied
widely.
The Environmental Protection Agency is currently developing
standardized measurement procedures, but until these are implemented and
substantially more data are accumulated, atmospheric asbestos levels
will Wsplargely unknown for most geographical areas.
The scant data available for ambient levels of asbestos in rural
air include a reported range of 0.01-0.1 nanograms per cubic meter,12
and levels of 40-100 electron-microscope-visible fibers per cubic meter
found in a remote area of California.13
Average reported concentrations of asbestos in urban air vary
between 0.09 and 70 nanograms per cubic meterl^>15 and, from one study,
between 0 and 2,400 electron-microscope-visible (2.4 o-ra-v) fibers per
cubic meter.13 Fiber readings in one study of air at Silver Bay,
Minnesota—readings that are not typical, since the locale is near a
taconite milling operation—ranged up to 150,000 electron-miscroscopevisible fibers per cubic meter.16

-33
H
• »>

aJ> WO MO
»

a h

a -

£.

o i * **
a - t>

*;s
«u -c
3 I.

?M il•• *iOfU
a, st. a *

Exposures from Asbestos Mining, Milling, and Product Manufacture
Asbestos fibers are released in mining and milling during removal^
of overburden and preparation of ore bodies for strip and open-pit min-4j
ing, as well as during drilling blasting to remove ore.
Other emissioi*
occur from ore piles and waste dumps that are exposed to wind due to did
turbance by bulldozers.
Drying, crushing, grinding, and screening of
the ore result in the release of fibers.
In this connection, the large
volume of air required for air-aspiration milling (seven to ten tons of
process air for every ton of fiber produced),17 together with the length
of time that asbestos fibers can remain suspended in air, generates a
significant potential for emissions.
Baghouses are the predominant engineering control measure used to
remove airborne dust from effluent air streams at mills and manufac­
turing plants. A study in 1974 showed that baghouses using specific
filter materials, and when properly designed, operated, and maintained,
have a collection efficiency of over 99.99% for fibers greater than 1.5
micrometers in length.13 However, the collection efficiency for fibers
less than 1.5 microns in length was approximately 98%.
Since generally
there are an enormous number of short fibers, a considerable quantity
of fibers can be released to the atmosphere even after passage through
the be^t available baghouses.
Fibers removed that are not reintrodiifced
production process must be disposed of outside the plant
and maj? result in emissions to air.
A is/4 field survey on the air concentrations of asbestos fibers in
the "Vicinity of anasbestos mill at Coalinga, California, showed 100
million electron-microscope-visible fibers per cubic meter within 500
meters from the mill tailings pile.18 No data for farther distances

56

01 061 0620

<*■■$>■

from the source are reported. A 1974 EPA report showed atmospheric con­
centrations of 2 to 106 micrograms per cubic meter within about one
kilometer of the Vermont mine-mill complex.19 Average readings were
about 30 micrograiK per cubic meter. At another site, about 1.5 kilom­
eters from the plant," the readings were .012 to 0.180 micrograms per
cubic meter, withfjfc? "average of about .096 micrograms per cubic meter.
In 1972, some atmospheric sampling was conducted at the asbestos
mill located near King City, California.20 one sampling station located
100 meters downwind of the source showed concentrations on the order of
100 million fibers per cubic meter, and, due to unusual wind conditions,
concentrations on the order of 10 million e-m-v fibers per cubic meter
were recorded at a station located 500 meters upwind from the source.
Another atmospheric sampling, conducted within 3 milometers of the mill
during August and November of 1974, showed concentrations of up to 1
million fibers per cubic meter downwind and 10,000 fibers per cubic
meter upwind.21 Elevated concentrations (4,500 fibers per cubic meter)
were found out to the farthest station (3 km).
These samples were
obtained with an 0.8 micron-pore-sized Nuclepore filter, whereas the 1972
samples were collected with a Millipore filter.
Hence, it would appear
that the Nuclepore filter failed to collect a substantial number of
fibers smaller than one micron and that the 1974 data may have under­
estimated the total number of fibers present.
The King City mill is
unique in that it uses a wet process; hence, it is believed that most
of the fibers in the atmosphere come from the ore pile and tailings dump.
Dispersion of asbestos emitted to the atmosphere depends upon fiber
length, topography, meteorological conditions, and the emission source
itself.
Wind speed and temperature stratification are important factors.
As asbestos travels in the atmosphere, gravity and rain remove it from
the atmosphere, and the process of agglomeration can be a significant
determinant of how many fibers will be present.
Because most of these
factors are different at each site, detailed estimates of asbestos con­
centration in the atmosphere at each site require individual, special­
ized, calculations.

Exposure from Transportation of Materials Containing Asbestos
Movement of asbestos ore from mine to mill in open trucks, often
over roads paved with mill tailings, may contribute to the overall con­
tamination of the environment.* However, three of five mills operating

The national asbesXos air emission standard
prohibits the surfacing
of roadways witTf*wastes containing commercial asbestos or tailings from
asbestos mining and milling, except for temporary roadways in the area
of an ore deposit.
The use of wastes that may contain noncommercial
asbestos as a contaminant has not been regulated.

57

01 061 0621

in the United States are located at the mines, the remaining two are
separated by short, rural, distances (32 and 55 miles).

P ro d u c e d u n d e r C o u rt O rd e r in H a r t v . Owens C o rn in g
F ib a r o la ft. «t- a l . . USDC SO M is s : C o n £ rd e n tie l i.n £ o r» » tJ .c m ,
n o t t o b e c o p it d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

45hipment of milled asbestos fiber, usually in bags, can result in
emis^QB6»*iken bags are broken, but such emissions are minimized by
pressure packing and unitization as described in Chapter II of this
monograph.
If bags are reused, either in the asbestos industry or
elsewhere, they may become a source of contamination.23 When milled
asbestos is pelletized and transported in sealed railroad cars (see
Chapter II) the potential for emission is no doubt reduced considerably.
Emissions of fibers could occur during the shipment of manufac­
tured products, but they would be negligible, since most manufactured
products contain asbestos tightly bound in a matrix.
A more important
emission source, perhaps, would be the transporting of asbestoscontaining solid wastes in open vehicles through urban areas. Also,
the transportation of other asbestos-bearing ores, such as talc and
taconite, and their products may result in environmental emissions.

Exposure from Asbestos Manufactured Products
Host asbestos is incorporated into finished products where the
fibers are bound in a matrix (e.g., asbestos-cement pipe and sheet,
flooring and roofing products, and friction products), and this reduc
the possibilities for air contamination. Yet, by the application of
sufficient energy, fibers may be dislodged from even tightly bound
materials; automobile brake linings are an example.
Clearly, there are opportunities for human nonoccupational atmos­
pheric exposure during installation, use, and repair of asbestos pro­
ducts.
However, since there are so many products that use asbestos or
materials that may be contaminated with asbestos, it would be next to
impossible to estimate human exposure for each product type.
In the
paragraphs that follow, some data and information are presented for
automotive friction materials and spray asbestos.

Automotive Friction Materials
Friction materials used in automotive brake linings, disk pads,
and clutch facings contain an average concentration of 50% chrysotile
asbestos by weight.24 it has been estimated that about 118 million
£ourttfit,pf asbestos are used annually to produce brakes in the U.S. and,
assuiSng a'15% grinding and milling loss, approximately 103 million
pound^-of asbestos are actually incorporated into brakes; similarly, it
has b£en_- estimated that 4.5 million pounds are incorporated annually
into_ automotive clutch facings.25 However, since brakes and clutches
are usually repaired before they are completely worn out, and since
^
some working automobiles are scrapped, not all this automotive asbestos-^-."^

58

will be released to the atmosphere.
Hence, the estimate of how much
actually is worn away annually is 74 million pounds, but only a small
amount of which is released as fibrous material.25
Tests jfryformed on brake linings have indicated that under con­
ditions of normafusage, considerable alteration of the asbestos occurs.
One study has reported that most of the dust collected from brake drums
is nonfibrous And is similar in appearance to thermally degraded asbes­
tos, and it was suggested that the temperature at the points of contact
of brake linings and drum actually reaches levels at which thermal degra­
dation of asbestos can occur.24
Three research studies of asbestos emissions from brake linings
give estimated percentages of free fiber at 1% or less, 0.3%, and less
than 0.02%, respectively.25,26,27
in the first of these studies, it
was estimated that annually in the United States there are 239,340
pounds of asbestos fiber emissions from cars, buses, and trucks and
that, of this amount, 204,952 pounds drop out on the roadway; 7,655
pounds become airborne, and 26,733 pounds are retained within the brake
and clutch housings.*25 These atmospheric emissions are of greatest
concern in ubran areas near traffic routes with high volumes of braking
vehicles.
Electron and light microscopy were used in a recent study to
analyze the number and size of asbestos fibers collected from air at
four Los Angeles freeway loop sites and from upwind ambient air controls
within 200 feet of the freeway.15 Concentrations of chrysotile asbestos
at the four freeway sites were low, generally in the range of 0 to
12,000 electron-microscope-visible fibers per cubic meter, and they did
not differ significantly from concentrations of chrysotile in the matched
upwind ambient air samples (0 to 9,000 fibers per cubic meter).
Concen­
trations of amphibole asbestos did not differ between freeway or controls
(1200 fibers per cubic meter).
There was no correlation of asbestos
fiber concentrations in the freeway samples with number or speed of
motor vehicles passing by during the sampling periods, nor was there a
correlation with wind direction or velocity.
Measurements were also made of chrysotile and amphibole asbestos
at the San Francisco Bay Bridge toll plaza, and the concentrations there

There is apparetrtiy an error in data used in this study from "Brake
Emissions: Emission Measurement from Brake and Clutch Linings from
Selected Mobile Sources," March 1973 EPA (NTIS #68-04-0020).
Total
4'4emissions should have been 239,340 pounds and, therefore, the other
emission figures have been scaled up accordingly in this monograph.

59
0

til*1-

01 061 0623

were found to be 1,400 electron-microscope-visible fibers of both types
per cubic meter.
This compared with an average San Francisco Bay Area
atmospheric chrysotile concentration of 500 fibers per cubic meter.^3

Spray Asbestos
From 1958 through 1973, spray materials containing 10% to 30%
asbestos by weight were used extensively to fireproof girders, spandrels,
and decking of high-rise office buildings, and use of spray asbestos for
decorative and acoustical purposes dates from the mid-1930s.15,28
Erosion of such spray materials alone may cause asbestos fibers to enter
building air, but the materials might also be damaged and dislodged—as,
for example, by workmen repairing fixtures inside the space between a
ceiling and the floor above.
In large-office buildings, air is often
returned to the ventilation system through these spaces.
A recent study of public buildings in which asbestos sprays
had been used showed that there were elevated levels of asbestos within
the buildings, as compared with the air outside. Also, the difference
between inside and outside air was greater in the case of fibroussprayed buildings than in the case of buildings sprayed with cementitious asbestos.38
Flaking of sprayed asbestos from ceilings has been reported
inside schools, libraries, dormitories, and warehouses.19,39,30,31
Air concentrations may range from 0.02 optical-microscope-visible fibei.
per milliliter under quiet conditions to 4.0 per milliliter during dry
dusting.31
Prior to implementation of federal regulations on asbestoscontaining fireproofing materials,* data were obtained at various
building sites in lower Manhattan where such materials were being
sprayed.32
Generally, average atmospheric concentrations within onequarter mile of a construction site were at least twice the background
level.
Current spray materials that contain 1% asbestos or less may be

k
Spray-^E^-materials used to insulate or fireproof structures, pipes,
and coipiults must contain less than 1% asbestos on a dry-weight basis,
and,-^or the spray, application of material containing more than 1%
asbestos used to insulate or fireproof machinery or equipment, no
visible emissions are permitted.32 Spray-on paints, decorative mate­
rials, and weatherproofing are not regulated.

60

01 081 0624

expected to result in no more than one-tenth of the elevated asbestos air
concentrations that occurred previously.
*

Exposures

osal of Asbestos Products and Wastes

Solid waste's- produced from the manufacture and use of asbestoscontaining products and from demolition^ can be emission sources, and
in the past,
these waste materials were often disposed of without
regard to their emission potential.
Moreover, their disposal may result
in the mingling of asbestos-containing wastes with municipal wastes in
open dumps, thus creating a long-term emission source.
Industrial asbestos wastes include process wastes such as dust,
slurries, waste from overspraying, and mill tailings; waste collected
by air control equipment (e.g., the dust from sawing, grinding, drilling,
etc. that is vented to control devices); scrap; and emptied asbestos
shipping bags.
This latter item, the bags in which the milled fiber is
received, is an asbestos-containing waste common to almost all manu­
facturers of asbestos products.
If the bags are not shredded and incor­
porated directly into the product mix, they are incinerated or disposed
to landfill, sometimes sealed in plastic bags.
Occasionally, they may
be treated like nonasbestos wastes and result in exposures to unknowing
handlers.23
Water may become polluted with asbestos fibers in manufacturing,
particularly in the paper and cement product industries, and during use
in wet cyclones for cleaning exhaust gases from factories.
The slurry
waste from such processes may be directed either into settling ponds and
the water recirculated (the dried waste disposed to land), or it may be
dumped directly into convenient sewers, rivers, or lakes.23 jn either
case, but especially in the latter, it can contribute to contamination
of the environment with asbestos.
The results of a survey of waste disposal methods used by asbestos
products manufacturers show that 37% of 97 plants surveyed used dumps
for wastes and that 13.4% used landfills.
(The remainder reuse.*

*See also Reference 19.
t.
For years, .asfr^gfcps
.aslregtps has been incorporated into material such
tion, cemerrt stwet,~T?6:ofing, and floor tiles and used in constructing
industrial,_and ^mmercial buildings and ships.
(For the most part,
single-family residences contain only small amounts of asbestos insula­
tion.)
When suetr~buildings and ships are demolished, areas of loosened
asbestos, especially from insulating materials, are open to the ambient
air and can emit fibers.
Obviously, demolition will continue to be a
source of emissions in the future, requiring control measures.

61
\

>

01 061 062

sell, store or wet-slurry their wastes.)
Of greatest concern from the
standpoint of emissions are those wastes that are disposed to uncovered
dumps•
AsfMa*«B-mills generate vast quantities of waste.
Whereas a large
manufacturing waste disposal site may have a surface area of 12,000
square meters (about 3 acres), a large mill tailings disposal site may
be 400,000 square meters (about 100 acres).
Mill waste may contain from
less than 1% asbestos by weight, as in the case of the Vermont mill, to
over 30% asbestos, in some California operations.

is

o
<3 a

■m a

5

Obviously, there also are opportunities for asbestos emissions from
the disposal of nonindustrial wastes, which constitute the majority of
asbestos wastes disposed to land (Figure 3).
Most notable of these
wastes are those generated by the renovation and demolition of ships and
buildings, which may contain large amounts of friable asbestos insula­
tion as well as many other asbestos products.

*
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Three studies of asbestos concentrations in air near asbestos waste
dumps, all conducted prior to the establishment of EPA standards in the
fall of 1975, have been published.13,19,34 it is apparent from these
studies that atmospheric asbestos concentrations in the vicinity of
waste disposal sites, often in urban areas, are considerably higher than
background concentrations—perhaps 10 to 1,000 times higher—and may
even approach occupational levels.
(The revised EPA asbestos standard
that went into effect after these data were recorded may help reduce
emissions.)35

Exposures of Asbestos Workers' Families
Families of persons employed in the asbestos industry may be sub­
jected to asbestos contamination that augments their exposures from
other sources. Workers may bring asbestos fibers home on their skin or
clothing or on equipment such as lunch boxes and automobiles. Atmos­
pheric concentrations of asbestos in the homes of asbestos workmen have
been reported to be 100-500 nanograms per cubic meter,28 concentrations
similar to estimated concentrations in the vincinity of asbestos mines
and mills and much higher than the 0.09 to 70 nanograms per cubic meter
reported in some U.S. cities.*14,15

Exposure to Asbestos in Drinking Water
*Dri
water is one of the possible routes by which humans are
exposed tjfasbestos.
Contamination of drinking water may be due partly

*It is known that occupants of households of asbestos workers have
elevated rates of asbestosis and mesothelioma.36

62

01 061 0626

to erosion from natural deposits of serpentine and other asbestoscontaining materials found throughout the United States, as noted pre­
viously in this chapter ("Redistribution and Fate of Asbestos in the
Environment"). Substantial contamination may also result from improper
disposal of asbesty^^taetes.
These wastes may be effluents that are
directly discharged into water systems, or they may be released to the
atmosphere or disposed of on land and subsequently join the water
system.
Another potential contaminator of drinking water is the piping
and pumping of municipal water distribution systems.
About 200,000
miles of asbestos-cement pipes are used to carry water to U.S. consumers,
and the pipes provide a source of asbestos fibers from leaching and
erosion.'>38
Gaskets and insulation used in treatment and in pumps are
other possible contaminators.*6
The major difficulties in determining the asbestos content of water
are discussed in Appendix C.
Furthermore, most of the analyses that are
available are for "grab" samples—samples of a few liters of water that
are taken from one source at one time.
The degree to which grab sam­
ples represent the characteristics of an entire municipality's water
supply over location and time could be questioned—some municipalities
receive their water from several sources, and seasonal and climatologi­
cal variations can change the asbestos content of water.'!'
For this monograph, data on the concentration of asbestos in drink­
ing water were extracted from 9 different published studies, represent­
ing 105 water supplies in the United States.6>?,39-45
(See also Appen­
dix E.)
An effort was made to select data only for finished drinking

*
A study of asbestos concentrations in two water systems using asbestoscement pipes revealed average increases of 0.074 and 0.004 micrograms
of asbestos respectively per liter of water at the tap.7 Laboratory
tests conducted by the EPA37 and Johns-Manville? on sections of
asbestos-cement pipe also have shown increased concentrations of fiber
in water.
However, a recent (February 1978) report showed no signifi­
cant release of chrysotile asbestos from asbestos-cement pipe exposed
to the action of "moderately agressive" water.38
t

In San Francisco, water from other sources is supplemented by water
from a reseryoiT^j^ha^t
located in a chrysotile rock area.
(Recall
also the study mEgitioh'ecTpreviously that showed higher asbestos fiber
counts in Philadelphia and Atlanta water supplies during periods of
high river flows ia-the surrounding regions.)
Further, a study pub­
lished in 1974 fflUnd that the amount and mineralogical nature of suspended solids in the Duluth water supply is most evident when heavy
rainfalls are followed by an increase in the amount of suspended
solids resulting from river runoff and shore erosion.39

63

• * : /'

01 061 0627

water—some of the samples were taken from taps in the water supply
system; others were taken at municipal water stations.
Also, only
studies in which electron-microscope measurements were made are included
The &bies in the studies were not selected to be representative of U.S.
citigjjf*twiHed, some were selected because asbestos was suspected to be
in their drinking water.
Chrysotile fibers, amphibole fibers, or both were found to be
present in 56 of the 105 water supplies.
Fiber concentrations in indi­
vidual samples varied between the lower limit of detection and 130 mil­
lion electron-microscope-visible fibers per liter (for only two cities
did the samples range over 40). Mass asbestos concentrations in indi­
vidual samples varied between below-detectable and 800 micrograms per
liter (for only three cities did the samples range over 60).*

Exposure to Asbestos in Foods and Drugs
Asbestos contents of food and drugs have not been well-established
to date, and the FDA has no regulations concerning the content of
asbestos in foods and nonparenteral drugs.
Foods may be contaminated during their agricultural phase from
asbestos in air and soil and from asbestos impurities in talc used as
a pesticide vehicle.
Uptake of contaminated water by plant roots, as
well as deposition of contaminated water directly onto leafy surfaces
by sprinkler irrigation, are possibilities, but no published litera- ture has been found to substantiate them.
One instance of accidental
contamination of food in the course of transportation has been docu­
mented.
Processed foods may become contaminated with asbestos either from
water used in their preparation or from the use of asbestos filters,
adhesives, rubber, and resins in processing and packaging.47 Foods for
which asbestos filters are used may include beer, wine, liquors, fruit
juices, sugar, lard, and vegetable oil.^ Asbestos filters have also
been employed to process cider, condiments, drinking water, mouth­
washes, syrups, tonics, and vinegar.49
The authors of one study found between 1.1 and 6.6 million
electron-microscope-visible fibers per liter in U.S. and Canadian beer,
and between 1.7 and 12.2 million fibers per liter in Canadian soft
drinks.
They also reported between 1.8 and 11.7 million fibers per

*
Some authors reported their data as fibers per liter, some reported
micrograms per liter, and some reported both.
64

01 061 062S

manufacturer's gin; the water used in the processing of gin contained
between 3.3 and 8.7 million fibers per liter.51
Any estimate of the quantity of asbestos consumed with food must
be purely spec^ative since virtually no concentration data have been
reported.
ThegEJM* WAV reported that under test and market conditions
certain foods contained less than 10 ppb asbestos.52
Asbestos filters also have been used in the processing of drugs
and blood plasma.
But since April 1975, as noted in Chapter I, the
FDA has disapproved their use in preparing parenteral drugs and bio­
logies.
Asbestos filters may be used, however, in the manufacture of
nonparenteral drugs and their ingredients.
Talc, which may contain asbestos as an impurity, has been used in
the manufacture of medicinal capsules and tablets and has found various
other uses in medicine and dentistry.53-55 Also, talc may be added to
processed foods, either directly as an ingredient or indirectly as a
form release agent or as a constituent of packaging materials.56-66

65

01 061 062.9

Chapter VI
CONTROL OF THE ASBESTOS HAZARDPHYSICAL CONTROL

Three program approaches for controlling the adverse health effects
of asbestos fibers in man's environment are presented in this and the
following two chapters.
These approaches are:
•

Physical control of human exposure to asbestos
fibers—i.e., reducing the contact between man and
the fibers

•

Medical surveillance—measures taken by physicians
and other health-care personnel in behalf of asbestosexposed persons

•

Education—ultimately, of course, of persons exposed
to asbestos fibers so that physical and medical con­
trol measures will be of maximum effectiveness, but
also education of persons who are in a position to
motivate those who are exposed, and other persons with
responsibilities for asbestos-control measures.

Reducing the extent of contact between asbestos fibers and man can
be accomplished by actions discussed in this chapter.
Such actions
include:
(1) engineering of the materials, processes, and facilities
for utilizing asbestos commercially; (2) administrative measures that
relate to the persons who might be exposed; (3) improvement of work
practices; (4) control of emissions and asbestos wastes; and (5) con­
trol during transportation of asbestos raw materials and products.
The
chapter includes a section on the application of control measures in
several specific manufacturing and consumer industries.

Engineering Measures* •
Control of airborne asbestos fiber by engineering methods is not
greatly different from the control of other solid particulate matter
having a simiiar Iprodyaamic size, though some special problems and
technologies may Ee involved.
Engineering control methods include:
•

Enclosure

-

Exhaust ventilation
•

Isolation

67

01 061 0630

•

Plant design

•

Treatment of asbestos

^

Substitution of alternative materials.

Enclosure
Unless borne by wind, dust particles, even when impelled at
extremely high velocities, travel only a short distance in air—a few
inches at the most.
This behavior is particularly true of asbestos
fibers, due to their low mass and aerodynamic characteristics.
Because
of the short travel distance, a good start toward control of asbestos
dust generated by machine operations is enclosure or hooding.
However,
enclosures must often have openings, to permit manual operation of a
machine or so that the machine may otherwise carry out its function.
Hence, there must be a continual inflow of air into the unit at suf­
ficient velocity to prevent the escape of asbestos dust.
For many
operations, an intake velocity of 200 feet per minute at the face of
an enclosure is adequate.
Enclosures for high-velocity wheels or
operations involving very large parts require special care in design.

Exhaust Ventilation
Adequate exhaust ventilation, with negative pressure, must be pr
vided for enclosed areas to remove airborne fibers.
The design of a
proper exhaust system is critical and should be accomplished by perso
who are experienced in the principles of air movement and other important
aspects of ventilation-system design.
Dusts for asbestos operation carry air at velocities ranging from
3.000 to 5,500 feet per minute.
The lower velocities are used where
relatively small concentrations of well-divided fibers must be carried,
such as in the dust-control systems at textile plants.
The higher
velocities are used where space is restricted and where larger pieces of
material must be carried, as in dust systems for machines that cut and
shape brake shoes or asbestos-cement pipe.
Most systems, including lowpressure penumatic conveying systems, function well at velocities of
4.000 to 4,500 feet per minute.
All parts of asbestos control systems should be maintained under
negative pressure to prevent leakage of dust into the plant from loose
joints and open seams, as well as to ensure adequate collection at hood
faces^prAnojliier-major consideration in a plant's ventilation system is
the provision of make-up air—the amount of make-up air introduced
s-houldpe-lightly exceed the amount of air exhausted.
A mechanical air

68

01 061 0631

supply system, rather than "natural" room ventilation, is preferred
and, in most cases, necessary to achieve the necessary ventilation per­
formance.
Many specif^^^aas- for duct contruction design may be found in
Industrial Ventilation issued by the American Conference of Governmental
Industrial HygiefRsts.1

P ro d u c e d u n d e r C o u rt O ro e r in H a rt v . Owens C o rm n c
F ib e r o ia g . a t a l. . USDC SD M i* s : C o n fid n tia l in f o r a e t io n ,
n o t t o toe c o p ie d / re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o rd e r-

Even with a ventilation system that is designed and built according
to good engineering principles, periodic measurements must be made to
determine that the system is adequately balanced and performing accord­
ing to design.
Such measurement include:
•

Static pressure

•

Air flow

•

Supply, capture, and conveying velocities

•

Fan performance.

Frequent measurements are essential, since plugging and wear can cause
variations in the balance and, hence, efficiency of the system.

Isolation
"Dirty" operations in the asbestos industry are frequently isolated
to minimize human exposure to asbestos fibers.
For some operations,
particularly vibrating screens and bagging at asbestos mills, such
engineering measures as ventilation and enclosure have not been able to
reduce airborne asbestos levels below the two-fiber time-weightedaverage limit, thereby necessitating isolation.
In addition to reducing fiber levels through a plant, there are
other advantages in isolating asbestos-fiber-emitting operations and
restricting access to them: (1) an employee working at a dusty opera­
tion is not so likely to relax his adherence to restrictive work prac­
tices if he is separated from fellow employees who are working freely at
operations that present no exposure hazard;
also, isolation can
(2) reduce costs for local exhaust ventilation, and (3) make for more
efficient housekeeping.
Unloading and storage of asbestos is another candidate for isolation
because of dust from bags that are inevitably perforated by in-transit
shifting or (Tare®p?s loading.
Such bags should be repaired—or the
asbestos rebagged-?-and vacuum-cleaned within the boxcar before being

M.

Mf

69

01 061 0632

transferred to the warehouse.
Also, of course, careful unloading is
required to minimize bag breakage.
B|tg:-opening stations, as well as being enclosed and ventilated,
should^hfl inflated from other operations in the mixing or compounding
arga. "The emptied bags themselves should be "isolated" by being rolled
up witKin the opening station's ventilation hood and put into either a
clean, sealed bag, a shredder, or a tube that conveys emptied bags to an
isolated, enclosed, central collection point from which they are ulti­
mately disposed of in sealed containers. (In some industries, bags can
be mixed with other material and submersed into the manufacturing pro­
cess .)

Plant Design
Not often is industry afforded the opportunity of designing and
constructing a plant to specifications that place such hazard control
measures as isolation and dust control at the forefront of priority.
As a rule, process flow efficiency, quality control, and cost factors
receive higher priority.
But enlightened management is aware that
efficiency, product quality, and cost savings do not necessarily con­
flict with design for health and safety.
An ideal design for isolating a dusty work area is one in which
entry can be made only through locker and clothes-change rooms.
Two
locker rooms, separated by a shower room should be provided—one for
street clothes, the other for work clothes and protective equipment.
Interposing a shower bath between the two locker rooms makes taking a
shower at the end of a shift more likely.
(See Figure 3.)
The contaminated change room should be under negative pressure,
with the exhaust air directed to a suitable collecting system.
Air flow
between the two locker rooms should be toward the contaminated room. If
connecting doors between change rooms and shower are self-closing and
well sealed, it may be possible to use the separating shower room as
an air lock.
Some other important considerations in designing for asbestos fiber
control are:
•

~

Engineering a dusty operation so that it can be handled
by as few employees as possible.

•^plifciading a protected observation area next to an isolated
I work area so that entry of supervisory personnel and
‘i^isitors can be kept to a minimum.

70

01 061 0633

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01 061 0634

•

Planning the layout so that airflow into hoods,
enclosures, and other exhaust equipment is not disturbed
drafts from fans, windows, and doors.
Off-set doors
with indirect, right-angle entries help to deflect
^*^.nd diffuse incoming air currents.

•

Constructing interiors such that beams, pipes, and
ledges do not serve as areas where airborne asbestos
can settle.

Treatment of Asbestos
There are various methods of treating loose asbestos to reduce
fiber emissions.
One of the most effective is wetting.
Although not
applicable to operations that will not tolerate moisture, such as the
manufacture of friction products, wetting can be used in mining and
milling and in the construction industry.
At present there is one asbestos mill in the United States that
utilizes wet processing. At this mill, asbestos is separated from
heavier rock through a series of flotation devices.
It is then col­
lected between pillow filters and extruded and dried in pellet form,
or it is fluff-dried and packaged as loose fibrous material.
Dust
control is needed only for pelletizing and bagging the finished produc
Use of pelletized asbestos, which can be pumped pneumatically int
enclosed railroad cars and unloaded through gravity release at its
destination, has been tried in the manufacture of friction products
and textiles but with little success.
These products require long
fibers, but pelletizing breaks fibers into shorter, unusable, lengths.
The shorter fiber length of pelletized asbestos should present less of
a problem in the manufacture of other asbestos-containing products.
A recent method of treatment to reduce airborne fibers in the
asbestos textile industry is the application of polymer to asbestos
yarn.2
Such a coating, however, is not useful where the inherent sur­
face characteristics of asbestos fibers are required, particularly when
the fibers are to be bound in a matrix with other materials.
Treatment of asbestos with anti-dusting agents may be helpful.
These agents are viscous liquids that are applied to dry asbestos by
spra^wuig or mixing.
The fibers are then dried at room temperature.
Tfiis Iftrcretains the performance criteria of untreated asbestos.-^

Substitution
Although the use of asbestos is well entrenched in many important
applications, it is likely that substitution will play some future
role in reducing the health hazards from asbestos.

72

01 061 0635

4

the largest asbestos users, the U.S. Navy, has issued an "Instruction"
that asbestos not be used in construction, overhaul, repair, and mainte­
nance where suitable alternative materials have been designated.
fcr--

Fibrous glass

Steel wool

Kaolin wool

Slag wool

Exfoliated vermiculite

Silica

Cellulose

Potassium titanate

Ceramics

Sintered metals

Carbon fibers

Rock wool

Few alternative materials have proved as satisfactory as asbestos due to
lack of strength, heat resistance, flexibility, or durability, or because
of cost.
Moreover, since attention has been drawn to the possibility
that inhaled fibers other than asbestos may be carcinogenic,4 it is
essential that the toxicity of proposed asbestos substitutes be evalu­
ated.
In certain industrial processes where asbestos is used as a binder,
less toxic materials have been substituted with little effect on the
quality of the product.
This has been the case in the manufacture of
rubber, plastics, and various adhesives and cements.
Similarly, less
asbestos might be used in paints, coatings, caulks, sealants, and joint
fillers.
Satisfactory asbestos substitutes have been developed for a variety
of reinforced plastics and resins and for insulating materials.
For
critical insulating applications, however, the strength and heat
resistance of asbestos cannot be duplicated economically.
Not many replacements have been found for asbestos in paper pro­
ducts in which the heat resistance, chemical inertness, and electrical
and insulating properties of asbestos are highly valued—products such
as mill board, roofing felts, pipe coverings, fine quality electrical
and insulating papers, and asbestos-latex flooring felts.
Glass cloth,
felt, and thread have found limited application in roofing and floor­
ing underlayments, but in the majority of these paper products, asbes­
tos fibers are still used.
Two of the more successful asbestos substitutes, soda-lime-silica
and high silica glass fibers, are viewed briefly below.
Soda-Lime-Silica Glass Fibers
Soda-lime-silica glass filaments, made by highly refined
processes involving the use of platinum dies, are of high quality and

73

i

01 061 063G

uniform size.
Some are less than one-half micron in diameter and are
adaptable to highly specialized uses, such as weaving into fabrics.
- Glass fibers will not burn, but they will soften and coalesce
at tHftiej.cTtares which vary according to the composition of the glass.
Theig_heat and moisture resistance is limited by the organic film
applied to them during manufacture to improve processing and to reduce
breakage during subsequent plying and weaving operations.
(Without
such a coating, the fibers are more brittle and self-abrasive.)
Hightemperature properties are impaired to some extent, but the fibers will
withstand temperatures up to 1,200°F.
Exposure of very fine glass fibers to water vapor results in
relatively rapid deterioration, making them less resistant than asbestos
to the effects of steam and moisture. Attempts to use them in place of
asbestos in asbestos-cement products have been unsuccessful because of a
chemical reaction, between the glass and cement, that decomposes the
fibers.
Glass fibers are efficient thermal insulators in types of equip­
ment, such as stoves and refrigerators, where conditions are not corrosive.
Their high tensile strength, greater thermal stability compared with
organic fibers, and electrical resistance make them suitable for ele
trical insulation. Glass fiber is used in conjunction with asbestos
or as an optical alternative material in Navy shipboard cable.^
A glass-asbestos cloth designed during World War II to ext
the supply of asbestos textile fibers has continued in use as a covering
on thermal insulation applied to piping on naval vessels.
It is woven
with a plied yarn, having one strand each of glass and asbestos.
Glass fabrics or combined glass-asbestos fabrics have some
advantage over asbestos textile products because they are lighter and
stronger, but they are generally less resistant to flexure, abrasion,
and chemical action.
Fabrics made of interwoven glass and asbestos
yarns are being made in many weights and colors for use as theater
curtains and fireproof draperies.
As a substitute for asbestos in friction equipment, glass fiber
has, in general, given unsatisfactory results, chiefly because of the
poor abrasive characteristics of glass.

-

^..High-Silica Glass Fibers

4EPGlass fibers approximating vitreous silica in composition
are superior to soda-lime-silica glass fibers in resistance to the
/

/

74

01 061 0637

action of water vapor and high temperature.
They are difficult to manu­
facture, however, because fused silica is extremely viscous at its
melting point (1,725°F).

Administrative measures are a complement to engineering control of
the hazard in the workplace.
Possible administrative measures include
(a) limiting the number of employees exposed, (b) limiting the duration
of exposure for any given person, (c) restricting smoking and eating in
the workplace, and (d) smoking cessation programs.*

Limiting the Number of Employees Exposed
The number of employees exposed to excessive airborne concentra­
tions of asbestos may be limited by:
•

Restricting access to contaminated areas (this measure can
also involve engineering design; hence, also see "Isolation"
and "Plant Design" further on in this chapter)

•

Reducing to a minimum the number of persons handling
asbestos

•

Conducting particularly dusty operations during shifts
where the number of persons in the plant is at a minimum.

Smaller numbers of continuously exposed employees are more easily
and effectively trained, controlled, and protected than a larger group
that is only casually and occasionally exposed.

Limiting the Duration of Exposure for Any Given Person
As noted previously, the OSHA standard for asbestos is an 8-hour
time-weighted average of no more than 2 fibers, greater than 5

•k
Another administrative measure, which has been used in the British dye­
stuffs industry in connection with cancer control,^ would be to give
preference to job applicants who are of an advanced age and who have not
previously bees*, occupationally exposed to asbestos.
The reasoning here
is that the ri’J'^of'-Sfeveloping asbestos-related cancer during the em­
ployees' lifetimes will be somewhat reduced.
However, while this meas­
ure may ha^?e sdgg~ basis in theory with regard to lung cancer, it does
not take into account other asbestos-related diseases or even the pos­
sible aggravation of adverse health conditions not normally considered
to be asbestos-related.
Moreover, there are other ethical and economic
considerations that would need to be explored.
Still another possible
administrative measure—giving preference to job applicants who do not
smoke (because of the greater risk to smokers)—would appear to be sub­
ject to the same considerations.
75
v y.o

}

01 061 0638

micrometers in length per milliliter of air; also concentrations must
never-, exceed 10 fibers per milliliter. This means that during any single
shift, employees may be exposed to airborne asbestos levels above 2
fiber^per milliliter so long as such excursions are compensated for by
equiv>j«wt«»-reductions in exposure, except that in no instance can the
exposQre exceed 10 fibers per milliliter.
As an example:
employees on a shift can be exposed for 4 hours
to an airborne asbestos level of 4 fibers per milliliter, which
is equivalent to a 2-fiber exposure for 8 hours, as long as they
are subject to zero exposure for the remainder of the day.
The
remaining four hours of the shift would be covered by employees
who had received zero exposure during the first half of the 8hour day.
Or, for example, a worker could be exposed to an air­
borne level of 9 fibers per milliliter for 1 hour, as long as he
was exposed to a level of no more than 1 fiber per milliliter
for the remaining 7 hours of the shift.
Control of exposure using averaging is deficient in a number of
respects since, in effect, it is assumed that: (1) exposure levels will
remain constant, not fluctuate; (2) the worker receives no asbestos
exposures, on or off shift, other than those associated with his work;
(3) 2 fibers per milliliter greater than 5 microns in length is that ^
level at which, for practical purposes, there is zero physiological
£
response; and (4) the submicron fibers present but not counted are
■
unimportant form a toxicity standpoint.
Other assumptions are that aK
sufficient work force is available for required alternation of person-J
nel, and that economics (increased payroll) is not a factor.

Restrictions on Smoking and Eating
For any toxic materials, a strong corporate stand should be estab­
lished against the practice of eating, drinking, or smoking on the job.
These activities should be restricted to a designated, clean location
visited only after established decontamination procedures have been
followed.
If such action represents a change in policy, the change
should be clearly and frankly explained as a step being taken to pro­
vide a safe work environment.

"It iJ^noted in a recent publication that asbestos fibers longer than
5 pm^iaving a length-to-diameter ratio greater than 3 (using 430x phasecontrast light microscopy) account for approximately 2%_ of all asbestos
fibers present in industrial settings and that, hence, every fiber
greater than 5 pm in length corresponds roughly to an actual fiber
^ ,V-Cr
count of 50.7

76

01 061 0639

Smoking Cessation Programs
Because of the interaction of tobacco smoking and working around
asbestos in producing lung cancer, and since smoking is a health hazard
in its own rightia^UflgJsing cessation program might be undertaken as a
cancer control nCSsure.
Unfortunately, however, the various programs
that have been tried have rarely brought about significant long-term
cessation, although smoking rates have been reduced.
It is possible
that recent moves of federal and state governments to restrict smoking
in public places* and public-service media campaigns to educate the pub­
lic on the hazards of smoking could improve the efficacy of cessation
programs.
Various approaches to smoking cessation are discussed in Appendix E
of this monograph with a view to providing a broad perspective of the
available options.
If it is decided that a smoking cessation program
should be undertaken, the discussion should be of help to the health­
care worker in selecting an appropriate program.

Work Practices, Including Housekeeping and Use of Personal Protective
Equipment
Changes in work practices often may be the most cost-effective way
of reducing occupational exposure to asbestos.
Some of the ways in
which work practices may be modified include:
•

Mixing asbestos mortar in closed polyethylene bags rather
than in mortar boxes or buckets.

•

Maintaining central fabrication shops from which insulation
material is sent to the field for installation with minimal
on-site cutting or sawing.

•

Permitting power tools to be used only in central shops.

•

Using single-point cutting and chipping tools, rather than
saws or cutting equipment using abrasion.

•

Jettisoning polyethylene bags into the product mix when
possible.

•

Substituting vacuuming for the blowing off of machines and
equipment with compressed air.

•

Good housekeeping (as discussed in more detail below).

•

Use ?f pVECaalrv.protective equipment (also discussed below).

Since 1976, 19 states have passed a total of 23 antismoking ordinances
that restrict smoking in public places of recreation, waiting rooms of
health facilities, and restaurants.

4fo*

77
?

i •

01 061 0640

Housekeeping

0

Good housekeeping is essential to reducing levels of airborne
asidestos. Waste materials such as rejects, scrap, shavings, or oYher

F ib e r y la a . a t

.

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . Qwena c o rn in g
a l . USDC SD H is s : C o n fid e n tia l in fo rm a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d ia t r ib u t e d e x c e p t in

dettrjs should be picked up and placed in plastic bags.
At the end of a
shift,these bags should be taped shut, labeled as to the hazard con­
tained therein, and disposed of.
Asbestos dust on floors, ledges, equipment, overheads, and other
plant surfaces can become airborne when disturbed by drafts or work
activity, and it should be removed.
Sweeping is not the way to remove
it, however, because the fine fibers are entrained into the air and
deposited on remote ledges, pipes, and other inaccessible surfaces.
Nor is wet mopping a satisfactory way of cleaning, since it tends only
to spread the dust around.
Vacuum cleaning is the recommended method—
preferably a central vacuum system.

Personal Protective Equipment
The control measures previously discussed in this chapter can sig­
nificantly reduce exposure to asbestos fibers, and they must be employed
first.
If, however, these measures are not sufficient, or if an unex­
pected event creates a potential for exposure greater than the maxil
permitted, personal protective equipment will be necessary.
To reil
ate, respirators and protective clothing must always be available, I /t
they should never serve as a replacement for engineering control me|
sures.

Respirators
Respirators may always be necessary during the cleaning or
repair of exhaust ductwork or during manual shakedown of collection bags
in baghouses.
Also, this form of protection may be the only feasible
method of controlling asbestos exposures during the removal of thermal
insulation or the application of some asbestos products.
The use of respirators is not to be taken lightly, however.
Since the devices place a burden on the respiration of the wearer—and,
at best, are a nuisance—a determination must be made as to whether an
individual can use the equipment and perform whatever work it is that
he is assigned to do.
Factors that must be considered in such a detert:lon include:
physiologic/physical ones such as oxygen needs for
th^taskv^-hair, beards, and glasses; medical conditions that may be
pregent such as pulmonary or cardiovascular disease; and psychological
disposition toward wearing a respirator.
The type of respirator needed—for example, powered versus
man-powered—will be dictated by the preceding factors as well as by the

78

01 061 0641

concentration of airborne asbestos fiber.®

(The concentration of fiber

should always Be rechecked whenever there are significant changes in
process, contrqil^ worksite, or climate.)
Respirators require proper
fitting, maintenanfo and cleaning to be effective.
The elements of an acceptable respirator program are set fort..
by the American National Standards Institute (New York) in ANSI Standard
Z88.2-1969 "American National Standards Practices for Respiratory
Protection."

Protective Clothing
Special clothing, not to be worn outside the workplace, should
be worn by all asbestos workers—not only to protect them, but to curtail
exposure of other persons.
The most satisfactory basic protection is afforded by coveralls,
preferably made of cotton-polyester material—cotton alone cannot be
used, because static build-up causes fibers to adhere to the cloth
tenaciously.
Disposable paper coveralls, although they are compara­
tively inexpensive and they eliminate the potential for exposure of
laundry workers, are easily torn or perforated by body movement, chemi­
cal action, or sparks.
Moreover, some types of paper suits are hardfinished and nonporous, almost airtight, and they can lead to heat
stress if worn over street clothes.
The coverall garment should be onepiece, without pockets, cuffs, or rolled edges, and with adequate clo­
sures for necessary openings.
Coveralls should be clean each day and
must never be worn away from the plant.
A head covering is also required, and lightweight paper
surgical-type caps are satisfactory.
Hard hats do not prevent the accu­
mulation of fibers in the hair, and, where the hats are required, a paper
cap should be worn under them.
Foot coverings, in the form of canvas booties, rubber galoshes,
or safety shoes, are also needed.
Either form is satisfactory as long
as they are not worn away from the plant.
Street clothes and personal effects should be kept in a "clean
conditions" room, and work clothes and protective equipment should be
kept in a "contaminated locker" room.
(See Figure VII-1.)
When personnel
leave a restricted work area they should enter the "contaminated locker"
room and remove^Tihging’ asbestos fibers by using a vacuum equipped with
a filtered exhauLt. system.
Protective equipment should be removed

79
r•

01 061 0642

(respirators last) and deposited in the "contaminated locker" room lockers.
The worker should then shower and put on his personal outer clothing in
the "clean conditions" room.
fcf -laundering of work clothing is done by an outside launderin
serv^fcflm
than in the plant, the laundry service should be advj
in writing of the asbestos hazard.
When collected for laundering,
clotlving should be vacuum-cleaned, dampened, packed in plastic bags,
sealed, and clearly marked "Asbestos Contaminated Clothing—Wet Befbre
Handling."

Control in Specific Manufacturing and Consuming Industries
Following are some observations on exposure control as it relates
specifically to several major asbestos manufacturing and using indus­
tries and to demolition and rip-out.
Generally speaking, control of
asbestos exposure outside of mining, milling and manufacturing indus­
tries is difficult—persons at risk are less aware of the hazard and of
proper work practices, and, moreover, engineering controls and personal
protective equipment may be lacking.

Asbestos Textile Production
Control of asbestos exposure during production of asbestos textij
has presented a greater problem than during the manufacture of other
asbestos products.
In part, this may be due to the use of machiner
that was originally designed for processing other, less toxic, fibrous
materials.
Fiber preparation—which involves fluffing, grading, beating, and
combing and which generates heavy concentrations of dust—is followed
by the mixing of asbestos with another material such as cotton or rayon.
Dust from these operations must be controlled by enclosures and venti­
lation.
Carding, twisting, spinning, weaving, and braiding of fibers are
dry processes which, by their physical arrangement, are very difficult
to enclose and ventilate, and it appears that current technology cannot
eliminate excessive exposure from these operations.
Control of tempera­
ture and humidity and general room ventilation have been used to reduce
exposures.
It is usual practice to keep the ventilated room at a
slightly positive pressure to help maintain proper temperature and
JiuuT^JLty^ and since the rate of air change is often as frequent as

80

01 061 0643

_

one complete change every 6 minutes, it is necessary to recycle the air
before cleaning.

Asbestos P
Since much.of the paper-making process involves wet materials,
little dust is created.
Drying is usually accomplished by passing the
wet sheet over steamheated rollers, which gradually remove the moisture.
The low-pressure, high-exhaust-volume hoods that are used to collect
'
the water vapor and to transport it away from the drying paper also
serve to remove any asbestos dust that may be released during the dry­
ing operation.
Bulk packaging of paper products by winding them on spools, reels,
or beams is a dry operation, but local exhausts and vented area hoods
are effective dust-control measures for this operation.
In general, the use of hydropulpers with pulpable bags; proper
ventilation rates; and the control measures mentioned previously will
serve to maintain asbestos exposure in paper making at acceptable
levels.

Asbestos-Cement Pipe and Sheet
The prime point for application of control procedures in the
manufacture of asbestos-cement pipe and sheet are at the mixing vat
into which dry asbestos is introduced and in which the asbestos is
agitated and at the final stage where the finished product is cut,
machined, buffed, and packaged.
(The addition of water, sand, and
cement curtails dust exposure in the interim stages.)
Local exhaust
ventilation with carefully designed enclosures are essential for proper
dust control at the critical exposure points.

Automotive Brake and Clutch Repair
The greatest exposure to asbestos during repair of automotive
brakes and clutches occurs when brake drums are cleaned by blowing them
with compressed air and when brake linings are ground and beveled.
Brake drums should be vacuumed instead of blown out.
Grinding and
beveling operations will have to be controlled by enclosure and exhaust

Construction

—

Control of exposure to asbestos fibers in building construction is
difficult since few operators are sufficiently localized to permit the

81

01 061 0644

use of enclosures or exhaust ventilation.
General room ventilation
coupled with respiratory protection are the only means of preventing
excessive exposure to fibers that may occur during necessary on-site
- sawing or shaping of asbestos products such as insulation; mixing and
apjgtication of asbestos patching, taping, or spackling compounds; and
sai®y«gs”StRl finishing of spackling, tape, or floor tile.
Generally, the application of floor tile, roofing, and siding
does not require extraordinary control procedures, since asbestos fibers
are securely embedded in the product and little or no dust is created.
A vacuum device installed on the periphery of a sanding wheel to evacu­
ate dust and fibers would help maintain low levels of exposure and
recharging of fibers into the air from the work area can be controlled
by careful housekeeping.
Much of the exposure in the building industry has been reduced by
substitituions for asbestos-containing materials, and further emphasis
on using alternative materials is anticipated as awareness of.the health
hazard of asbestos fibers increases.

Demolition and Rip-out of Asbestos-Containing Insulation
The potential for exposure to asbestos fibers during demoliticflJBfef.
ships and buildings and during rip-out of asbestos thermal insulaticfc^
is high.
Insulating materials that contain asbestos have been used
and less in recent years but, because there is so much asbestos matAtal
already in place and because dust control during demolition and rip^ot
is difficult, these operations will remain potentially hazardous for
years to come.
The following measures will help to reduce the hazard:
•

Airborne dust can be reduced considerably by soaking the
insulation—nonabsorbent surfaces punctured to permit water
to be introduced, and absorbent surfaces soaked by a fine,
low-pressure water spray so that dust does not arise from
the impingement of the water upon the surface.

•

Insulation should be removed, if possible, by sawing or
cutting with tools fitted with dust collecting devices
rather than by tearing away.

•

Materials removed should not be allowed to fall to the
ground but should instead be placed in bags for disposal.

•

Slurries of waste that fall must not be allowed to dry—
they should be removed while still wet.

» •

If possible, a high-capacity exhaust system should be
employed at the work site.

■—•

Where wetting and exhaust ventilation are not possible,
control efforts should be directed toward isolating the
hazardous operations.

82

01

061 0645

Control of Emissions to the General Environment
Air Pollution Control
Methods for <^g££aU4ng asbestos emissions to community air are
similar to those for controlling any particulate matter, with some
variations due-to.The special characteristics of asbestos.
Since oper­
ations that generate asbestos fibers are usually conducted under nega­
tive pressure, careful cleaning of the air in the ventilating system
will adequately control general air pollution.
However, while the
air-cleaning methods mentioned below may be adequate for many asbestosrelated activities, they are not practical for use in demolition or
rip-out.
Control of general air pollution in this case is limited to
use of water sprays.
The most useful control method is fabric filtration, and design
parameters for successful systems have been published.9-12 The effi­
ciency of fabric filter units used to collect asbestos fibers ranges
from 95% to 99.9% on the basis of weight.
These units operate dry, and
removing the filters and packaging them for disposal can be a dusty
operation, requiring the use of personal protective equipment.
Wet collectors—wet dynamic scrubbers and Venturi-type collectors—
range in efficiency from 50% to 90%.
The fibers collected are in a
slurry and may pose a water pollution problem.
Usually, the slurry is
filtered and the wet fibers disposed of in a suitable container.
Mechanical collectors (cyclones) generally operate with the same
efficiency range as wet scrubbers, the actual efficiency depending on
the size, design, and energy expended.
Although the fibers collected
are dry, many of them are fractured, thereby limiting their further use.
Because the fibers are dry, personal protective equipment may be required
when they are removed from the collectors for disposal.
Because they
require no power other than to move air and they have no parts to wear
out other than the collector shell,2 mechanical collectors are econom­
ical to operate and maintain.
Electrostatic precipitation has proved to be less effective than
other air-pollution-control means for asbestos fibers—yielding, at
the best, 70% efficiency.

Until recently little attention was directed toward
waters associated wjjjfch asbestos manufacturing, and there is virtuaxxy
no published information on such waters.
The number of plants is not
\
large, and the VQ^HSes of wastes have been relatively small.
Further­
more:
a significant amount of process water in manufacturing operations
is recirculated, most plants have some form of waste treatment, and
many plants are situated where they can discharge the process waste

83

01 061 0646

waters to municipal sewers.
Recently, however, increased concern over
asbestos fibers in the air has resulted in (1) conversion of some dry
processes into wet ones and (2) use of water sprays to control dust from
mining and from piles of tailings or gob (low-grade ore), thereby
increasing the potential for water pollution.

Waste Water Treatment Processes
The standard processes for removing suspended-solid wastes from
water have been found to be satisfactory for removing asbestos fibers:
•

Pretreatment—removal of oil, grease, and the larger
aggregates of solid matter.

•

Primary treatment—sedimentation and chlorination

•

Secondary treatment—biological processes such as
aerated lagoons

•

Tertiary treatment

Tertiary treatment—sometimes referred to as "advanced waste
water treatment" or "physical-chemical treatment"—is required if^the
effluent from secondary treatment is not considered satisfactory. •*■
The several means of removing suspended solids in tertia
treatment including microstraining, diatomaceous earth filtration,
chemical clarification, and deep-bed, granular media filtration.
In microstraining, the waste water is strained through a woven
mesh screen on the surface of a rotary drum that revolves on its hori­
zontal axis.
As the drum rotates, the solids are strained out of the
water and to a position from which they are removed from the drum.
Diatomaceous earth filtration is a form of mechanical separa­
tion that utilizes diatomaceous earch, a finely powdered filter-aid that
is built up (coated) on a supporting medium, to trap solid material.
The fibers removed are mixed in with the filter medium, and both must
be disposed of.
In the chemical clarification process, chemicals such as
aluminum, iron, or calcium oxides are added to the water to coagulate
fine solids.
Coagulation is followed by a flocculation phase, in which
particulates are aggregated into larger dumps that will settle.
This
process if followed by sedimentation, in which the floes that have been
prev^Ssiyr^formed are allowed to settle to the bottom of a settling tank.
While*some of the solid material will have been removed by sedimentation,
the nltfcerial remaining must be removed by filtration, usually carried

84

01 061 0647^

out in beds of a porous medium such as sand or coal, or a combination of
media such as sand and coal, or sand, coal, and garnet.

Contr^^^—Asbestos Fibers in Potable Water Supplies
The extent of asbestos in the nation's water supplies has not
been established conclusively, and it has not been established to what
extent ingested asbestos might be harmful to humans.
In the meantime,
it is the opinion of some researchers that oral intake of asbestos
should be reduced as much as possible.
^

1%
9 V

9 2

x -a •
Q O U
(A 9 U
Q MO
(A £.
D * •

One method of reducing asbestos concentrations in potable water
involves minor modification of standard coagulation/filtration techniques
as practiced in most water-treatment plants.
Preliminary results show
that the number of asbestos fibers could be consistently reduced to
below-detectable limits (<20,000 fibers per liter).
Even simple filtra­
tion systems have been shown to be partially effective and could prove
useful as a low-cost interim measure in areas of high fiber concentra­
tion. ^
The results of one study indicate that both alum and polyelec­
trolyte coagulation optimize fiber removal and that they can be used
with sand filters.
This is a definite advantage, since sand filters are
used in the majority of filtration plants in North America, and Europe
as well.
During 1974, two diatomite-filter pilot plants operating at 10
gallons per minute removed over 80% of amphibole asbestos fiber from a
drinking water source.
The turbidity of the finished water was 0.05 or
0.06 FTU (Formazin Turbidity Units), with over 95% of the fiber removed.
Removal of amphibole fiber seemed to be significantly better than that
of chrysotile fiber.^ The pilot plant study suggests the following
conclusions applicable to the filtration of Lake Superior Water at
Duluth:
Several filter operating conditions can result in 95%
to 98% removal of asbestiform fibers.
Conditions pro­
viding the best filtered water would involve the use
of either alum-coated Hyflow Super Cel (or equivalent
grade) as body feed and precoat, or alum-coated C-512
filter aid (or equivalent grade) as precoat plus a
continuous coagulant feed of Cat-Floe B polymer to
The Operating data indicate that vacuum diatomite
^Tfiltgfs are significantly more expensive as a means
of producing filtered water and that they would be
very difficult to operate under conditions of high
turbidity.

f

•

fct - -

m* 1

A least-cost-design analysis of several alternative
plants suggests that a plant designed for a 20-year
life and for a turbidity of 1.9 FTU equalled or ex­
ceeded only 5% of the time could produce 30,000,000
gallons of water per day at a cost of 5.56q per 1000
gal.
It is suggested in the study that the best pro­
tection against price increases for filter-aid would
occur if the filtration plant were designed for a
water turbidity of about 2.5-3.5 FTU.

Waste Disposal
The greatest hazard associated with asbestos solid waste is the
potential for air emissions arising from improper handling and from
improper final disposal.
At each step in the handling of the solid
waste material—whether the waste is to be concentrated, isolated, dis­
posed of, reused, or otherwise treated—hazards to the waste handlers
may arise.
Hence, asbestos-containing wastes must be treated with the
same respect accorded asbestos products and their production.
The most desirable general waste management options, in order of
priority, are;l®
•

Waste reduction—by reducing the amount of asbestos used,
substituting less-hazardous material, and making the proce;
more efficient.

•

Waste separation and concentration—segregating hazardous
and nonhazardous wastes.

•

Waste recovery—reusing the material.

•

Secure ultimate disposal—disposal to landfill in a way
that precludes future reentrainment.

The most important aspects of controlling asbestos solid waste are
discussed in the paragraphs that follow:
(a) identification, (b) sep­
aration, (c) secure transport, and (d) secure ultimate disposal.

Identification
Obviously, there can be no control measures directed at asbestos
solid waste if asbestos has not been identified as part of the solid
was-fee stream issuing from a plant—identification and then tracking

V
86

01 061 0643

The source of asbestos-containing waste having been identified,
that waste shoufepbe separated from nonhazardous wastes, taking care to
prevent exposur«»»wtrorkers during separation.
For holding small quan­
tities of dry asbestos wastes, the most generally satisfactory containers
are heavy-gauge, impervious plastic bags.
Asbestos may also be disposed
of as a slurry, provided the slurry does not dry between collection and
disposal.

Secure Transport
Waste must be transported to the ultimate disposal site with­
out producing emissions.
In practice, this means that community (public
or private) disposal services cannot be relied upon unless they are
aware of the hazard and of proper handling procedures, and unless they
can provide closed conveyance to the ultimate disposal site.
If waste
is disposed of on the premises of a plant, employees of the facility
will likely be familiar with handling precautions.
The integrity of the waste container must be maintained.
Care
must be taken not to rip or tear plastic bags, and more-permanent waste
containers such as cans or bins must have tight-fitting lids that will
not come off during transit.

Secure Ultimate Disposal
The only disposal of asbestos waste that can be considered
"secure ultimate disposal" is depositing it in a site that is covered
with a layer of nonasbestos-containing waste or earth that is at least
15 centimeters deep if an adequate vegetative cover is also established
and maintained, or 60 centimeters deep if there is no such vegetative
cover.
Emissions from waste may also be controlled by (1) maintaining
a resinous or petroleum-based dust-suppression cover at the site, or
(2) by wetting the waste with water and sealing it in an impermeable
container before disposal.^
Covering waste with soil and planting vegetation does not
require as much care as is needed for maintaining a disposal site with
dust-suppression agents; hence, it is the more desirable control method
in most cases.

Control Dur4ng Iltensportation

<4

The transportation of asbestos ore from mine to mill is generally
not a significant source of airborne asbestos fibers, although private^?*1
*
See Chapter IV, Occupational Exposure,
applications.
87
•• t

for additional details and

mine-mill roads may be paved with tailings from which fibers can be
liberated when trucks pass by.
Some of these emissions can be reduced
by tarring, sprinkling, or treating the roads with dust-suppressing
chem^fcals.
EPA regulations permit no visible emissions from mine or mill
road£fi^i«o«p^anufactured asbestos products not firmly embedded in a
■1x7* such as asbestos textiles or spray asbestos materials, should
matrix,*
be either:
•

Transported and stored in enclosed, impermeable, sealed
areas

•

Wetted and covered with tarpaulin or similar material to
prevent drying

•

Appropriately packaged—packaging that is leakproof and
durable enough to withstand abrasion or puncture during
normal handling, and that bears easily visible labels
that warn persons about the hazard.

Areas used to transport or store asbestos not appropriately pack­
aged should not be used at the same time to transport or store other
goods.
Such areas should be posted with signs warning of the asbestos
hazard.
Before the areas are used to transport or store goods, accu
ulations of asbestos fiber should be removed thoroughly, preferably
with a vacuum cleaner having a high-efficiency filter.
Personnel working in or near areas used to transport or store
regulated asbestos that is not appropriately packaged should follow
the protective procedures outlined earlier in this chapter.

*

Manufactured products containing asbestos firmly embedded in a matrix—
asbestos cement, asphalt, plastics, and the like—may not reasonably be
expected to result in asbestos air concentrations that are high enough
to warrant packaging.
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01 061 0651

kzChapter VII
CONTROL OF THE ASBESTOS HAZARDMEDICAL MANAGEMENT

A means of limiting, in the industrial population, diseases that
can be somehow related to asbestos is to recognize during a preemploy­
ment examination persons who have increased risk for these diseases by
virtue of other attributes they possess and to recommend that they not
be hired for jobs involving asbestos exposure.
Those workers necessarily
exposed to asbestos should be enrolled in a medical monitoring program.
In this way, hopefully, asbestos-'related diseases, disorders predispos­
ing to these diseases, and conditions likely to be aggravated by asbes­
tos exposure can be detected early enough so that removal from'exposure
or medical intervention may successfully limit their course.
Neverthe­
less, asbestosis may progress even after removal from asbestos expo­
sure, and screening programs for the early detection and treatment of
lung cancer have not yet proved to be more than marginally beneficial.

Composition of the Workforce
The extent to which discovering and not hiring certain high-risk
persons for jobs involving asbestos exposure can be put into effect in
any particular situation will be limited, inevitably, by social and
political considerations.
Each industrial physician must develop his
own program for dealing with these matters in relation to preemployment
examination policy.
The desired net effect of the employment screening approach is to
assemble and maintain a workforce whose combined average risk of devel­
oping disease, with exposure to asbestos, is less than what it would be
were it to include persons whose individual risks, even without occupa­
tional asbestos exposure, are relatively higher.
The approach would be
expected to be most effective in relation to those diseases for which
evidence of a causal role of asbestos is most convincing and the magni­
tude of the problem is greatest—lung cancer, mesothelioma, and asbes­
tosis.
Summarized below are some considerations for applying control

89

t

01 061 0652

over the industrially exposed population by excluding from employment
certain individuals on medical grounds.

Tjung cancer is the most frequent of cancers related to asbestos
exposure and today exacts the heaviest mortality of any asbestosrelated disease.
Several risk factors for lung cancer have been
identified:
•

Cigarette smoking greatly increases the mortality from lung
cancer, and, based on present knowledge, it is the most impor­
tant single risk factor.

•

A history
siblings,
magnitude
cigarette

of lung cancer in a first-degree relative—parents,
offspring—has been shown to confer almost the same
of risk of lung cancer for the general population as
smoking, and, together, both factors are synergistic.

Prior occupational exposure to carcinogens affecting the lung
also may reasonably be expected to enhance the risk of lung
cancer in an asbestos worker.
Such carcinogens include arsenic;
chloromethyl ethers; chromium; coal tar, petroleum, and by­
products; creosote; mustard gas; nickel; radium; and uranium.
Nonmalignant respiratory disease may increase the risk of lungi
cancer.
Pulmonary fibrosis has been noted in association with'
lung cancer in persons with scleroderma3»4 ancj certain rare
hereditary diseases of the lung such as fibrocystic pulmonary
dysplasia5>6 antj congenital cystic disease of the lung.? Several
reports have associated an excess risk of lung cancer with
chronic bronchitis, after taking into account differences in
smoking habits.
However, such studies have often employed
broad smoking categories and have neglected such important vari­
ables as duration of smoking and extent of inhalation.^ Perhaps
most convincing was the finding of a substantial excess mortality
attributed to nonmalignant respiratory diseases among nonsmoking
blood relatives of lung cancer cases that was not present among
case spouses.And significantly higher rates of impaired
•forced expiration have recently been found among never-smoking
relatives of patients with lung cancer or chronic obstructive
pulmonary disease when compared with neighborhood controls.
Experiments with animals indicate that individuals with asbestosis may be at increased risk of lung cancer, regardless of
,J.evel and duration of asbestos exposure.13
Possible laboratory measures of lung-cancer risk include inducible
levels’^? aryl hydrocarbon hydroxylase and the condition of exfoliated
cells itt-sputum.
Aryl hydrocarbon hydroxylase (AHH) is an inducible

01 061 0653'

enzyme thought to be responsible for converting, hydrocarbon carcinogens
such as are found in tobacco smoke to an active form.
One team of
investigators has reported that levels of inducible AHH activity in
human tissues appear.to be genetically regulated and that patients with
bronchogenic car^paaa»have higher levels of inducible activity than
controls.16,17 inducible enzyme levels, therefore, might indicate
among cigarette smokers those individuals at greatest risk of develop­
ing lung cancer.
At present, however, there are numerous difficulties
with the assay technique even in the most experienced laboratories, and
the method is not ready for general use.18 Furthermore, the associa­
tion between levels of inducible AHH activity and cancer has not yet
been firmly established.1^
Examination of exfoliated cells found in sputum has been used to
assess the state of the human tracheobronchial tree.
Cancer has been
observed to develop after a series of gradual cytological changes occur­
ring over several years.
These changes have been categorized into
stages of regular squamous cell metaplasia, various degrees of a typical
squamous cell metaplasia, carcinoma in situ, and invasive carcinoma.20
The more severe the cellular changes, the greater is the likelihood of
developing lung cancer.21 Cytological examination of sputum can be used
to complement the use of risk factors listed above since, at any one
time, the condition of exfoliated cells must reflect the interrelated
effects of all operating risk factors, age, and latency.
A great limi­
tation to the widespread use of this technique at present is the paucity
of laboratories capable of accurate cytologic interpretation of sputum
samples.22
Persons with any of the risk factors for lung cancer or whose
sputum examination reveals cytopathology of severity equal to or greater
than moderate atypical squamous cell metaplasia would best not be hired
for jobs involving asbestos exposure.*

Mesothelioma
Little is known about susceptibility to mesothelioma, an important
cause of mortality in asbestos workers.
Persons who have had an

*

The evidence that asbestos is causally related to laryngeal cancer is
highly suggestive, but not as overwhelming as it is for lung cancer and
mesothelioma.
the exclusion from employment of individuals
with other risk^factors for this disease would probably be less bene­
ficial.
IE sho'fe'd be noted, however, that except for family history,
the risk factors—identified for lung cancer generally apply to cancer
of the larynx?*" Risk of laryngeal cancer has, in addition, been corre­
lated with alcohol consumption.23-25 xhis cancer is rare, and most
susceptible persons will have been screened from employment in efforts
to exclude persons with elevated risk of lung cancer.
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01 061 0651

asbestos-related pleural effusion may be at great risk,
asbestos exposure should be prevented.

2 ft

and further

'Asbestosis
Exclusion from employment of those persons most susceptible to
disease would likely prove more efficient for asbestosis, for which
exposure to asbestos is a necessary factor, than for lung cancer or
mesothelioma, for which it is not.
However, despite suggested effects
of cigarette smoking,27 immunological response,2°,29 an(j specific HL-A
antigens,30 risk factors for asbestosis have not been established,31
and there is to date no method for identifying from medical testing or
questioning those individuals who are more susceptible to asbestosis.
Because of the potential adverse effects of further respiratory
disability from asbestosis in individuals with existing chronic res­
piratory disease, it would be prudent not to hire such persons for jobs
involving asbestos exposure.

Early Detection and Treatment of Asbestos-Related Diseases
In general, treatment of asbestos-related diseases, even when
detected early, is far from satisfactory.
Cure is rarely possible, Ei
oftentimes death or severe disability supervenes despite the best oflij
efforts.
Furthermore, programs for early detection and treatment rim
the risk of instilling a false sense of security, which may detract
from more primary efforts to prevent disease by controlling exposures.
This must be kept in mind during the subsequent discussion.
A suggested
protocol for preemployment and follow-up medical examinations of asbes­
tos workers is given in Table 7.

Lung Cancer
Screening programs, which rely on roetgenograms and symptom ques­
tionnaires at intervals of six months have been notably unsuccessful in
improving the changes of survival from lung cancer.32, 33 The Phila­
delphia Pulmonary Neoplasm Research Project reported a 5-year survival
rate of only 12% of individuals whose tumors were detected within 6
months of a negative roentgenogram, as against 4% in those whose tumors
were detected more than 6 months afterward.
•
estrannual screening program conducted among residents of
Veterans Administration domiciliaries and consisting of stereoroentgen
f-ilms'jFriuestionnaires, and sputum cytology slides reported a 3-year post
operative survival of only 12%.21 This study documented a considerable

92

01 061 0655

Table 7
. MEDICAL EXAMINATIONS FOR ASBESTOS-EXPOSED WORKERS
Preemployment
Questionnaire: mfedig^Jj^story, family history, history of smoking* and consumption of
alcoholic beveraj^S*, occupational history
Physical Examination:
concentrating on the oral cavity, chest, and abdomen and including
a digital examination of the rectum
Spirometry:
including measurements of vital capacity, forced vital capacity, and forced
expiratory volume at one second
Chest X-ray:

posteroanterior and lateral views (14 x 17 inches)

in H a rt v . Owens CorDlOg

Follow Up
Nonsmokers, Ex-Smokers, and Smokers Who do not Inhale
•

No More Than Mild Atypical Sputum Cytopathology:
ometry, chest X-ray, and sputum cytology

•

More Than Mild Atypical Sputum Cytopathology:
a yearly questionnaire and spir­
ometry; chest X-ray and sputum cytology every 4 months

•

40 Years Old and Older, At Least 20 Years from Onset of Asbestos Exposure:
add
fecal occult-blood testing and an examination of the oral cavity every 6 months

P ib e r o ia a . « t

a yearly questionnaire, spir­

Smokers Who Inhale
•

Less than 15 years from Onset of Asbestos Exposure:
-No more than mild atypical sputum cytopathology—a yearly questionnaire, spir­
ometry, chest X-ray, and sputum cytology
-More than mild atypical sputum cytopathology—a yearly questionnaire and spir­
ometry, chest X-ray and sputum cytology every 4 months

•

15-20 Years from Onset of Asbestos Exposure:
-No more than mild atypical sputum cytopathology—a yearly questionnaire and
spirometry; chest X-ray and sputum cytology every 6 months
-More than mild atypical sputum cytopathology—a yearly questionnaire and spir­
ometry; chest X-ray and sputum cytology every 4 months

•

More Than 20 Years from Onset of Asbestos Exposure:
-Less than 40 years old—a yearly questionnaire and spirometry; chest X-ray and
sputum cytology every 4 months
-40 years old and older—add fecal occult-blood testing and an examination of the
oral cavity every 6 months.

t l.

P ro d u c e d u n d e r C o u rt O rd e r

, USDC SD H it s :

n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t's o r d e r .

C o n f id e n t ia l in fo r m a tio n ,

Sputum Cytology

Since smoking jis sJBX^n-siiigiqptant risk factor, breath should be sniffed for tobacco
odor; and in s1tuat^5>ns where the reliability of smoking histories is in doubt, levels
of expired air carb^^-monoxide or serum thiocyanate may be used to distinguish cigarette
smokers from nonsmoirers.^
Sources:

Protocol mattlfled from the Mt. Sinai School of Medicine, Environmental Sciences
Laboratory Pulmonary Surveillance Program for Asbestos Exposed Workers.

93

01 061 0656

amount of inter- and intra-observer variability in the interpretation
of sputum smears and chest X-ray films, but noted that the addition of
positive and suspect sputum cytopathology increased the sensitivity of
the screening method by about 50% without significantly compromising
its ^gec.ificity. 21,34,35
fcu“rrently, large detection and follow-up programs are under way at
the Trayo Foundation, Johns Hopkins University, and Memorial SloanKettering Cancer Center to evaluate the efficacy of sputum cytologic
examinations, chest X-rays, and questionnaires administered every four
months.
At the Mayo Lung Project each chest X-ray is reviewed by three
physicians individually; and check roentgenography for patients having
follow-up examinations at the Mayo Clinic itself consists of posteroanterior (PA) stereoroentgenograms and 350-kV PA views, as opposed to
conventional PA and lateral films.36,37
In the presence of normal chest X-rays, if a single sputum speciment contains frankly cancerous cells or if repeated specimens from
the same individual contain markedly atypical cells, procedures to
localize a tumor are set into motion.
Detailed radiologic and radio­
isotope studies are undertaken, and a thorough otolaryngologic examina­
tion is made to rule out cancer of the upper respiratory tract.
If
localization is not achieved, a meticulous endoscopic investigation
follows utilizing fiberoptic bronchoscopy, succeeded if necessary by
bronchographic studies.36
■fcfc**!'
Initial results from the Mayo Lung Project suggest that no more JKthan a third of detected cases of lung cancer may be expected to sur-'
vive five years or more.
However, more observation is needed in order
to determine actual rates of survival.
Roentgenographically occult
tumors, which are likely to be centrally placed, were generally smaller
and had a better postoperative prognosis. Most newly diagnosed lung
cancers (64%) were detectable by chest X-ray alone, and only 13% of
cancers detected after an initially negative screen were first noted as
the result of clinical symptoms.36,37
Whatever the outcome of the current detection and follow-up pro­
grams, certain limitations will apply:
•

Some individuals should be ineligible for screening because
of inability to tolerate pulmonary resection or unwillingness
to undergo operation if it becomes necessary.38-40 To screen
such persons not only would be wasteful, but also might
ultimately contribute to lowering the morale of other parJiicigants in the screening program—that is, whether or
^P'ho’r'the death of a screening participant was due to inability
^or unwillingness to be operated on, it might be regarded by
- others as a failure of the program.

y>

94

01 061 0657

•

A considerable number of persons may discontinue participation
in the screening program because of retirement, termination of
employment, or other reasg^s.
Since the incidence of lung
cancer Increases with age
and has been found in one study to
be higtoy^agjaBg screening dropouts,38 there is reason to believe
that persons who discontinue participation in a screening pro­
gram may in fact be at greater risk.

•

A certain proportion of screening examinations will be found to
be incomplete or technically unsatisfactory.^

•

Once a cancer has been detected, there will inevitably be a delay
until localization and operative resection.
The greater this
delay, the less the potential benefit that can accrue from the
screening program.

•

It will be difficult to extrapolate from results obtained at
premier centers of medical care to likely results in an average
industry program.
(The difficulty in finding laboratories cap­
able of accurate sputum cytologic diagnosis has already been
mentioned.)

•

The considerable financial expense of a screening program and
the drain on available time of medical care personnel should
not be overlooked.

•

Despite screening, some cancers will not be detected early; and
despite early detection, certain cancers will be inoperable or
have a poor prognosis.

•

A not-inconsiderable percentage of persons who will have been
successfully operated on to remove a lung cancer will develop
a second tumor.38

Despite these limitations, medical screening remains the only
means of assisting the unfortunate individuals destined to develop
asbestos-related diseases and should not be abandoned.
The use of
sputum cytology to distinguish persons of heightened susceptibility
to lung cancer for removal from asbestos exposure or for motivation to
quit smoking deserves to be tested.
Screening examinations remind the
workers of the health hazards of his job and may be used to enlist
his cooperation in improving work practices as well as in changing
detrimental personal habits.
It is suggested that programs for early detection of lung cancer
in asbestos workers consist of periodic sputum cytologic examinations,
chest X-rays, -awd^symptom questionnaires administered according to a
schedule which 'Bfcigs-'wi'th age, risk of lung cancer, and time elapsed
since first exposure to asbestos (see Table 7).
Available medical
facilities that are competent in localizing and resecting lung cancer
should be identified in advance of the program to minimize time taken
from detection of cancer to operation.
Emphasis must be placed on
proper check roentgenography, since chest X-rays alone should detect

01 061 0658

21

37

the majority of lung tumors;
’
sputum cytology is more effective in
detecting centrally placed tumors36 whereas asbestos workers may more
likely develop peripheral lung cancers (adenocarcinomas).41 Each chest
film must be read independently by more than one physician especially
trailed to detect early lung cancer and qualified in the ILO/U/C
clas^£^afc4on of radiographs of pneumoconioses.^

Laryngeal Cancer
Asbestos workers with clinical symptoms of hoarseness or pain or
soreness of the throat should be referred to an ear, nose, and throat
specialist for a detailed otolaryngologic examination of the upper
respiratory tract.

Mesothelioma
At present, mesotheliomas are uniformly fatal.
Neither radical
surgery, radiation, nor chemotherapy prolongs survival; in fact, these
modes of treatment may be harmful.
Since no useful therapy is avail­
able, screening for early detection beyond what may be done to detect
lung cancer is of no clinical value.
Invasive diagnostic procedures
should be kept to a minimum and management restricted to the relief
of pain and breathlessness.^3,44

Cancers of the Alimentary Tract
Fecal occult-blood testing has been used an an annual screening
device to detect colorectal cancer in asymptomatic men and women 40
years old and older.45 Positive tests have been obtained from persons
with cancer of the stomach, small intestine, colon and rectum, and, to
a lesser extent, from persons with benign gastrointestinal lesions.46*
Persons with positive results should be referred to a gastroenter­
ologist for further studies, which may include endoscopy, cytology,
biopsy, and radiology.
Early detection and excision of a colorectal
and gastric cancer, it has been noted, may result in 5-year survival
rates as high as 90%, compared with overall national averages of 40%
and 10%, respectively.49,50

-t—y

-

False ifcit ives can be reduced considerably by using guaiac-impregnated
filter fibber slides in conjunction with a diet high in residue (to
stimwiate bleeding- from existing lesions) and free of red meat and high
peroxidase foods (e.g., horseradish and beets).
Vitamins and aspirincontaining medications should also be avoided.45,47,48

96

01 061

Asbes tosis
Periodic comparative chest X-rays and pulmonary function tests
(see Table 7) wi^1 improve the chances of detecting early asbestosis.
Many abnormalitiflgf^lUWever, are nonspecific, and it will be difficult
to determine .if these reflect early asbestosis or are merely related to
smoking or aging.51 Pleural thickening or plaques in an asbestos
worker must always be suspected as evidence of a biological effect
related to inhaled asbestos.52 Persons with early asbestosis or with
pleural thickening should be removed from asbestos exposure and referred
to a chest physician for careful follow up.

97

01 061 0660

jL , - Chapter VIII
CONTROL OF THE ASBESTOS HAZARD—EDUCATION

Asbestos was the subject of the first occupational safety and
health standard issued by the Department of Labor, following passage of
the OSHA Act of 1970.
But although the standard has been amended since
(to change the allowable airborne exposure concentration), no specific
directive has been included regarding education or training of super­
visors or employees.
However, in standards subsequently promulgated for a number of
carcinogens—including vinyl chloride, the subject of another control
monograph by the National Cancer Institute*—there are particular
requirements specified for employee training and indoctrination in,
for example, the following: nature of the carcinogenic hazard, nature
of the operation involving the carcinogenic agent; recognition of
conditions that may release the agent; purpose and application of
decontamination practices; emergency practices and procedures and the
employee's specific role in them; and purpose and application of the
medical surveillance program.1 It would appear that a comparable
mandate should exist for work with asbestos.
Goals of Education
Implicit in the fundamental goal of controlling the human carcino­
genic hazard from asbestos are several goals of education—increased
knowledge of:
•

Work processes involving asbestos and the potential for fiber
emissions

•

The physical characteristics of asbestos, so as to understand
its dispersion and potential for inhalation

•

Diseases that may result from exposure to asbestos fibers and
how these diseases are manifested

The reader is ^dvised to read the section on "Educational Control" in
the cancer^con^fiTL-mcaaagraph Vinyl Chloride, since some of the infor­
mation presented there complements the material presented here with
regard to The dffbestos-control situation.
Among the topics discussed
there are "Understanding 'Risk;'" review of a National Academy of
Sciences study on informing workers and employers about occupational
cancer; and an outline of an on-going vinyl chloride education program
that embodies some of the approaches discussed here with regard to
asbestos.
.dS j ^
vr
99

Oi 061 0661

«

The concept of "risk"

«

Reasons for, and methods of, environmental monitoring

•
-

The purpose and nature of engineering and work practice control
methods as discussed in the previous chapter (exhaust ventilapersonal protective devices and clothing, personal hygiene,
etc.)

•

The elements of medical surveillance and the reasons for it

•

The role of related factors in disease production, such as
smoking.

1
-

ric h t h i i C o u r t '* o r d « r .

Modes of Education—The Written and the Spoken Word

( o a
: ov

Of the two modalities employed in delivering health messages, the
written word and the spoken word, the written word is far less effective.
It lacks the elements of concern, warmth, dedication, and personal in­
terest of the instructor, and there is no opportunity for question and
discussion.
Furthermore, the efficacy of the written word depends on
the reading skills of the reader.
However, if one must reach hundreds
of employees at once the written word might have to be used but, even
then, it should be as a reinforcement to the oral mode of communicatmn.
One good opportunity for oral communication is when the physici«jfci»**
and an employee review the results of the employee's periodic medicaf~- '•
examination.
Attention is then focused on one individual—one who i
at the same time, full of foreboding and apprehensiveness, nurtured by
misunderstanding, folk beliefs, inadequate information, and rumor.
The
physician at this time can clarify medical terms, give meaning to test
results, and suggest changes in work habits and life styles.
Most oral communication will take place at group education sessions.
In some employment jurisdictions, such sessions may be required by
labor-management contracts or by law.2 The subjects for presentation
may be mandated; selected solely by the occupational health staff; or,
perhaps most effective, chosen through joint consultation of health
personnel with department heads, plant manager, and trade union offi­
cials .
Education must go beyond a pro forma attempt to meet mandated
requirements.
As recommended by a special committee of the National
Research Council,2 provision must be made for the worker to acquire
more information than is provided by the "package" of educational
_ge, the worker, must be assured that his questions will be
answSed, if not during the information session, then later by telephone,

letter, or consultation with a member of the occupational health staff
or someone equally knowledgeable.

P ro d u c e d u n d e r C o u rt O ro e r in H a rt, v . Owens C o rn in g
P ib e r o if lg . a t a l . . USDC SD M is s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is c o u r t 's o r d e r -

An excelleiy-forum for group health education is during the orien­
tation of new eirfpJU^eesL.
The occupational health staff should use the
occasion to dis®Ss the purposes of the preplacement medical examina­
tion recently completed, to describe available health services, and to
explain engineering controls, work practices, and use of personal pro­
tective equipment.
Pursuit of a health problem in the future will be
facilitated by this initial introduction.

The Educators
Persons from a variety of backgrounds may be involved in the educa­
tion effort—physcians, nurses, health educators, industrial hygienists,
safety specialists, and others.

Physicians
Physicians that teach usually do so in institutions of higher
learning, where they can remain comfortable with a technical lexicon
and oral shorthand.
It takes greater effort and more time to describe
medical disorders and risk factors to a layman in terms he can under­
stand, yet this must be the charge of the physician, particularly the
specialists in occupational medicine pulmonary disease.
Pulmonary disease specialists, in particular, as they become more
knowledgeable about asbestos-related diseases, must inform their col­
leagues in the medical community of diseases.
For in spite of a growing
body of pertinent literature, many physicians remain uninformed about,
and unsuspecting of, asbestos-related diseases.
Many chest physicians
are members of lung associations, and such membership can provide many
opportunities for the education of fellow medical practitioners as well
as lay community leaders.
Also, when necessary, the pulmonary disease
specialist could assist the occupational physician in educational pro­
grams for industry.

Nurses
Health education has long been recognized as a primary function of
the occupationaijjh^alth nurse and an area in which she can make a
cons iderable-conStibifti'tCtT. ~ The nurse often has a closer relationship
with the employee^Jthan does the physician and therefore may have greater
influence on changing the employee-patient’s behavior.
Whereas the
advice of the meddreal director might be interpreted as the biased word

101

01 061 0663

of management, a skilled nurse utilizes every patient visit as an
opportunity for presenting material relevant to health behavior.

tefealth Educators (Communication Specialists)
“Professionally trained health communicators may be found in the
larger occupational health programs of industry.
As full-time personnel
in the medical facility, they have been able to learn the mission of the
organization, to become acquainted with work processes, to identify
problems or concerns peculiar to the work population, and to absorb the
"shop patois." This background puts the health educator in an excellent
position to communicate successfully with the employee.

Industrial Hygienists
The industrial hygienist is an integral part of the occupational
health staff. Whereas the occupational physician has expertise in the
recognition, evaluation, and control of diseases relating to environ­
mental hazards in the workplace, the industrial hygienist is trained to
recognize, evaluate, and control the environmental hazards themselves.
One aspect of this responsibility is the education of the working com­
munity.
The industrial hygienist informs workers about measures to
control physical hazards and motivates them to do what they can to mi
imize personal exposure and to assist in improving the work environme

Union Health and Safety Specialists
In recent years, a small but increasing number of trade unions have
appointed full-time staff persons in the area of occupational safety and
health.
These individuals may be extremely influential, because they
know the issues and supporting data well and can communicate information
to their locals by means of periodic letters, memoranda, newsletters,

Industrial Safety and Other Training Specialists
Ever since the birth of the safety movement in the United States,
specialists in accident prevention have conducted educational programs
for employees.
Although most of these efforts have related to physical
trauma, some slight redirection could channel them toward the preventIon^asbestos-caused disease.
Ijfc-addition to training in safety, there may be company training
programs, -in other subject matter, from management skills to technical

102

01 061 0664

craft apprenticeship information.
Training specialists who conduct such
programs might also assist in health-hazard education.

Science/Mei

cai Writers

Medical writers on the staffs of large daily newspapers and other
periodicals might be asked to a plant to be made familiar with the con­
tent of a medical surveillance program, to be apprised of health survey
results, and to be updated on general occupational health activities.
If a good working relationship evolves, chances will be improved that
reports are in-depth and accurate, and the result could be yet another
avenue for education of the worker.

Target Groups for Education
As indicated, there are many target groups within industry for whom
instruction in prevention of asbestos disease is needed.
The language
in the OSHA occupational safety and health act of 1970 direct training
toward both the employer and the employed and, in addition, there are
trade union officials, retirees and other former workers, workers'
families, and miscellaneous persons in the community at large.

Managerial and Supervisory Personnel
Managers should be as familiar, or even more familiar, with the
risks of the materials they ask their workers to handle and with preven­
tive measures, medical surveillance, and the other areas of knowledge
listed ac the beginning of this chapter under "Goals of Education."
There is often an unusual climate in which to educate managers
about asbestos-related disease.
That is, a number of executives and
line managers have risen from the ranks, so that at the inception of
their careers they, themselves, worked with asbestos fiber.
Hence, any
occupational health procedure draws special attention because such
managers know of the latency period before manifestation of disease.
Their concern is as great as that of newly employed mechanics' helpers,
while, at the same time, their literacy level is probably higher.
However, while they may know that the fiber is hazardous, they might
not be as familiar with aspects of the problem as they should be, and
they should receive as much medical and industrial hygiene information
as they can ab&osfe.
W *■«*- -Because he is at the level of management closest to the worker,
a well-informed supervisor should be particularly effective in

103

01 061 0665

modifying the behavior of workers since he will be in a position to
motivate rather than commanding or invoking the sanction of regula­
tions .

■LTWITters in the Asbestos, as Well as Other, Trades
While workers in the asbestos trades are obvious targets of
educational efforts, there are other workers who may be exposed to
asbestos and who, therefore, should be informed of the asbestos hazard
and how to minimize it.
These workers include those who dismantle ships
and buildings, welders, painters, electricians, carpenters, marine
machinists, shipfitters, machinists, and automotive brake and clutch
repairmen.

Petirees and Other Former Workers
Because of the long delay in manifestation of asbestos-related
disease, it is necessary to maintain contact with retirees and with
persons who have left work with asbestos to obtain employment else­
where.
The asbestos worker cannot be permitted to depart with the
misapprehension that if he no longer has contact with that material
he is no longer at risk of development asbestos-related diseases.
Exit interviews provide an opportunity to emphasize the need f Jr'
life-time contact and to stress the need for continued medical surv«S^~
lance. Wherever possible, former asbestos workers should be includ"ffi^
in plant programs of health education, smoking cessation, and medical
surveillance.

Workers 1 Families
In addition to learning about asbestos-related disease, the
families of asbestos workers should be informed about the importance
of smoking cessation and about the potential contamination by fibers
brought home on clothing, equipment, lunchboxes, and automobiles, and
in the form of souvenir ore samples.
Also, it has been observed that
wives who visit with their employee-spouses at the plant physician's
office often ask more astute, more penetrating questions than their
mates.
Communication is good with mixed audiences, and the program
of prevention will be strongly reinforced by informed families.
*—»•_ ? Occupational Health Professionals
“-Be cause there are so many substances, combinations of substances,
industries, levels of industry (raw materials, intermediate manufac­
turing, finished product manufacturing and distribution), occupational

<$>

104

01 061 0666

health personnel are not all-knowing about all hazardous substances cur­
rently in use.
For example, with the possibility of asbestos insulation
in innumerable buildings being removed during renovation or demolition,
it is possible
the health personnel of a company or institution not
in the asbestos^yj^j^try may suddenly be faced with the inauguration of
a project to pr^ect personnel against the untoward effects of fiber
inhalation.~ Finally, the ubiquity of asbestos is such that it could be
present in a plant without a company's health personnel's knowledge—
i.e., through the reworking of asbestos-containing parts or raw materials
manufactured elsewhere.
Information on the asbestos hazard will sharpen
the health professional's index of suspicion, and he will seek out the
material's presence throughout the workplace.

Assessment of Education's Value
Every health education program should be validated as to its worth.
While a rigorous evaluation may not be possible, there are means by
which the effectiveness of an education program might be judged.
Although for a work force as a whole, some workers are retiring and
some workers are leaving for other employment, small groups can be
tested informally before and after various education segments in which
they participated as follows:
•

Compliance in engineering controls and safe work practices—
without giving great visibility to the check-off procedure,
workers could be observed prior to and after the educational
program to determine if there is a change in their use of
engineering control devices or in their compliance with safe
work practices.

•

Compliance in medical surveillance programs—workers often
report for chest radiography or pulmonary function testing
only after innumerable telephone calls and notices, and im­
proved compliance rate would indicate some success in education.

•

Basic knowledge appropriate to target group—groups can be preand post-tested for retention of common knowledge expected of
workers in daily contact with asbestos.
Differences in reading
ability, cultural differences and anxiety levels will influence
test results, but there should be at least some rough indication
of added information or altered behavior.

105

1

01 061 0667

Appendix A
ASBMJOS tRCLATED AND -ASSOCIATED MINERALS

Minerals Other Than Asbestos that May Exhihit Fibrous Structure
Mineral Species3

Morphological Characteristics

Pyrophyllite

Sometimes occurs as radiating needlelike
crystals in feldspars, kyanite, and in
quartz veins from reef mines.

Vermiculite

Normally exhibits a flaky structure, but
fibrous varieties have been reported.

Attapulgite
(a clay)

Commonly crystallizes in well-defined
fibrous forms.

I.epidolite
(a mica)

Normally fibrous or granular when present
as overgrowths on muscovite micas.

Minnesotaite
(a talc)

Commonly fibrous rather than platy.

Charaosite

Sometimes occurs in the form of minute
fibrous crystals, associated with sedi­
mentary iron formations (ironstones)

Halloysite
(a clay)

Frequently occurs with kaolinite and is
characterized by elongated tubular crys­
tals, similar to needles.

Holmquistite
(an amphibole)

Commonly occurs in aggregates and some­
times displays an asbestiform texture.

Richterite
(an amphibole)

Commonly exhibits a fibrous crystallo­
graphic habit similar to asbestos.

aThe firat tlipel "fcanre-important industrial applications; the others
are found in ’connection with commercial mineral operations, where
they arff notfelly considered an impurity.

4'-$-

A-l

01 061 0669

Minerals and Rocks Possibly Associated With Asbestos
Mineral or Rock

Uses

Talc3

Ceramic applications (whiteware, wall tiles, electrical
porcelain); extender for paints and pigments; lubricant
and filler for cosmetics, and in the preparation and
packaging of foods.

Phlogopite

A member of the mica family, used in a number of electric
and electronic applications, such as insulation in air­
craft sparkplugs, and as a thermal insulator.*3

Chlorite

A common constituent of metamorphic rocks; due to its
green coloration, is used in construction for aesthetic
purposes.

Kaolinitic clays

Used in ceramics (whitewares, thermal insulators); as a
filler or extender in the rubber, paint, and plastics
industries; in the paper industry to impart gloss, opacity,
brightness, and printability; and in medications.

Bentonitic clays
(Montmorillonite,
Fuller's earth)

Drilling muds; as a binder for iron ore pelletizing; in
filtering applications; and a filler for paints, cosmeo
pharmaceuticals, and ceramics.

Vermiculite

Used primarily in the construction industry as an insul
but is also employed in the agricultural and horticultu
industries as a soil conditioner.

Taconite and simi­
lar metamorphic
iron deposits

A primary source of iron for the steel industry.

Magnesite and
Brucite

Used as a raw material for magnesia-containing refractories,
fluxes, and miscellaneous chemicals and can be used in the
production of magnesium metal.
Brucite is often associated
with magnesite and, as such, is used as a source of magnesia.

Marblec

Metamorphic carbonate rock used for polished stone and other
applications in construction and for sculpture

aAlso known as steatite or soapstone.
^Most phlogopite is imported into the United States.

Its occurrence in this

country is resticted mostly to small, noncommercial deposits and as an impurity
in certain marbles.

I>■

CThe term "marble" is sometimes used indiscriminately to describe other rocks
thajjtfian be polished and that have a pleasing appearance; such rocks include the
so-alleif'Verde antique or serta green, some onyxs, and slates. Verde antique
(serta- green) is commonly a serpentine and is therefore likely to include
chrySotile contaminants.
Sou^dgsT'

W.A. Deer, et al. "Rock-Forming Minerals," Longmans Green & Co., 1961
N.W. Hendry, "The Geology, Occurrences and Major Uses of Asbestos," New
York Academy of Sciences, 132, Dec. 31, 1965.
Malcolm Ross, "Geology, Asbestos and Health," Environmental Health
Perspectives, 9, 1974, pp. 123-4.
Robert L. Bates, "Geology of the Industrial Rocks and Minerals," Dover^U?
^y
*
Publications, Inc., N.Y., 1969.
A-2

01 0G1 0670

6V,A

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Appendix C
MONITORING AND MEASURING ASBESTOS CONTAMINATION

Although i_he role of asbestos as a cause of cancer and other
diseases is clear, the mechanisms underlying disease causation are not
well understood, and this impedes efforts to measure and, subsequently,
control human exposures to the substance.

As if the technical and

economic difficultier of measuring asbestos concentrations—the subject
of this chapter—were not enough, two other facets of the hazard are
murky:

(1) Which attr.ibute(s) of asbestos it is that actually causes

disease and which therefore must be measured accurately; and (2) the
amount of asbestos that is hazardous, and over what period of time.
The attributes of asbestos that have been implicated in various
*
hypotheses on asbestos carcinogenesis include:
1
•
Size and shape of individual fibers

2

•

Number of fibers

•

Total mass of asbestos

•

Type of asbestos

•

Trace metal content

•

Trace organic content

•

Surface charge

•

Surface adsorptive characteristics

,

3

2
4
5

6
6

Because of the inordinate difficulties of separating the last four
attributes from nonasbestos "background", these four are not suitable
indices of exposure for routine monitoring situations.

In addition,

hypotheses based on trace metal or organic content have fallen out of
favor.

Because there is no consensus on the attribute(s) that cause

cancer and,

therefore, no consensus on the appropriate indicator of risk

from enviionmjStaT-tlxposure to asbestos, the "best" monitoring and
measuring;. metiitSl- will be that which permits the most detailed character­
ization of exposure through measurement of the first four variables—size
and shape of individual fibers; number of fibers; total mass of asbestos
and type of asbestos.
References will be found at the end of this Appendix.
C-l

01 061 0674

'In addition to the limitations just mentioned, it has not yet been
esta&i3lied whether the time-course of exposure, or dose rate,
sign

_

in determining carcinogenic risk.

is

This leaves open the

possibility that it may be just as important to determine peak exposures
as to determine time-weighted average exposures.
Because of these limitations, and because of the technical difficulties
and costs of measurement discussed below, the method of measuring
must be chosen judiciously to fit the circumstances:

occupational versus

general environment; measurement of asbestos concentrations in water
versus those in air; monitoring the environment at large versus determining
exposures to certain individuals.

Also, the methods chosen may differ

according to the fiber type that is of concern.

Monitoring Devices and Methods
The most desirable means of monitoring in general, would be one^PP^which a device could measure directly the asbestos concentration in aR*.**^
water, or in a bulk sample of material.

Such a device, which might WBfc-

used for continuous monitoring, is not available for most situations,
however.
Some Limited-Application Monitoring Devices
Some devices for measuring general particulate contamination of
8
9
fluids—based upon the piezoelectric balance.
Beta-attenuation,
or
light-scattering principles^—may be suitable for monitoring applica­
tions where the asbestos concentration is a known, constant, and relatively
large fraction of the general particulate contamination.

11

They are not

appropriate for such purposes as asbestos-pollution monitoring in
community air, where the total particulate loading will be several

12

orde^^i..largnitude greater than the asbestos loading.
Nor are they
^
'
appropriate in surveys of industrial sites, where the asbestos/total
loadii*g-ratio and the size of airborne asbestos fibers may fluctuate
"—

marlfedly.

2

Thus, continuous monitoring is generally not practicable.

and sampling will almost always be necessary.

C-2

01 061 0675

Monitoring by Membrane Filtration
The major method of monitoring in use for environmental media is
membrane filtration.

The membrane filter method is directly applicable to

air, stack gases, water, food liquids, and other fluid media.

With solid

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Q w e n i C o rn in c
F io e r o la a . e t a l . . USDC SD M is s : C o n fid e n tia l in f o r x a t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
e c c o rd e n c e w it h t h is C o u r t 's o r d e r .

media, it can be used as a final concentration step for fibers that remain
after some preliminary digestion procedure.
The procedure most commonly used is a single-step filtration, in
which all suspended particulate material in the medium is entrapped,
together with the suspended asbestos.

It is also possible, however, to

utilize a dual-filter set-up in which the first (coarser) filter entraps
the larger material while allowing much of the smaller material (including
most of the asbestos) to pass through to be collected on the second (finer)
filter for analysis.

12

Although this dual-filter method has some

advantages for applications in which the asbestos concentration is low
and concentrations of other particulate material

are high, the method

cannot be generally recommended because as filter loading increases,
the collection characteristics change causing an increasing amount of
asbestos fibers to be trapped on the first filter.
The filter best-suited for use in most environmental
sampling for asbestos is a mixed cellulose-ester membrane filter (similar
to those manufactured by the Millipore Corporation), with a mean nominal
pore size of 0.45 or 0.8 pm.

These filters will remove, from water,
13
99.9% of asbestos fibers present
and are estimated to be "...almost
14
100% efficient..." for removal of asbestos fibers from air.
For «omSS»ni.i£ations, the "Nuclepore" membrane filters manufactured
-

by General

*

-- -----------------

E^gctric are most appropriate.

12

They are more suitable

for scanning alectron microscopy of collected samples because of their
relatively TTat surface and their relative stability in an electron beam.
However, they are difficult to use in direct environmental monitoring,
because they have a high pressure drop at normal sampling rates and a
0-3

.Tvisfr law

&
01 0G1 0U76

tendency to develop static charges,which makes them difficult to handle
*

after sampling.
Measuring Asbestos in Air
is most probable that inhalation of airborne asbestos is
attSftded by greater carcinogenic risk than is ingestion (as discussed
in-Chapter III).

Hence, it is most important that present knowledge of

exposure to airborne asbestos, as a function of time for various popula­
tion groups, be refined so that those groups at greatest risk can be ascer­
tained.
The biologically effective concentration and deposition characteris­
tics of the particles available for inhalation (in the breathing zone
of the individual) are the critical parameters to be measured.

The

biologically effective concentration will be some complex function of
fiber number, size, shape, mass, and type of asbestos best correlated
with disease.

Deposition characteristics

(deposition in the airways of

of man) are complex and are discussed elsewhere in this monograph (Ch&te'r. Ill),
Suffice it to say that the diameter of the individual fiber is the priraigai
controlling variable in deposition, but length is important

enough t&K both

should be measured, although this is difficult in practice.
Measuring Asbestos in Water
The sampling of water to determine asbestos content requires
special care if the results are to be representative of potential hifjilri^'
exposures.

As with air, there are seasonal effects on sources of

asbestos and on the distribution of asbestos in a given body of water.
Stream flow rates, thermal stratification, sedimentation, and differing
source flow rates may all have an effect, as may (for drinking water) the
characteristics of the distribution system.
The Environmental Measurements Advisory Committee of the EPA has
recen^jj. beeji studying the question of measuring asbestos in drinking
water.» As part of this effort, the Athens (Georgia) Environmental
Research-Laboratory has developed a preliminary method for such assessment.

K
For discussions of membrane filtering that are much more thorough, see
References 14, 20, 24, 25, and 26.
c ^

01 061 06*77

In part, the guidelines given there include:
"It is: beyond the scope of this procedure to furnish detailed
instruction^or field sampling; the general principles of sampling
waters. arf_applicable.

There are some considerations that apply to

asbestos fibers, a special type of particulate matter.
are small, and in water range from .1 ym or more.

These fibers

Because of the

range of size there may be a vertical distribution of particle sizes.
This distribution will vary with depth depending upon the vertical
distribution of temperature as well as the local meteorological
conditions.

Sampling should take place according to the objective

of the analysis.

If a representative sample of a water supply is

required a carefully designed set of samples should be taken,
representing the vertical as well as the horizontal distribution,
and these samples composited for analysis.
The sampling container shall be a clean polyethylene, screw-capped
bottle capable of holding at least one liter.

The bottle should be

rinsed at least two times with the water that is being sampled
prior to sampling.

(Note:

sampling containers.)

Glass vessels are not suitable as

A minimum of approximately one liter of

water is required and the sampling container should not be
filled.

It is desirable to obtain two samples from one location."^

When the bulk water sample has been collected, it is filtered through
a membrane filter and the filter prepared further for analysis.
Measuring Asbestos in Food
The most critical, and yet unresolved issue in measuring asbestos
in food is a method to be used in preparing solid or semi-solid food
for separation of any asbestos that may be contained.
such generally'J^jM-tatil.e^ method exists.

At present, no

Surface contamination (e.g. on

rice) may be measured relatively easily by straightforward washing and
—
4L—
filtration techniques.
For liquid foods and beverages, simple filtration,
with membrane filters, is often appropriate, followed by treatment to
remove organic co-contamination of the filter surface.^

c-5
i.

vj

10

01 001 0678

Analysis of Samples—Some Technical and Economic Constraints
The most valid analytical methods for complete assessment of
asbestos contamination are those methods based upon electron microscopy.
This

ticularly true for assessment of general community exposure

from^air or water.

In some cases, where the fiber-size distributions of

asbestos exposures are constant and already known

from electron microscopy,

the use of optical microscopy, or the methods of continuous monitoring
referred to earlier, may be justified for routine

surveillance.

Technical Constraints
Individual asbestos fibers can be identified by phase-contrast
optical microscopy.

However, without using electron microscopy it is not

always possible to distinguish asbestos fibers from amorphous inorganic
(fibrous glass or mineral wool), natural organic (plant or animal), or
synthetic organic (nylon, orlon, etc.) fibers.

Moreover, in most

monitoring situations the majority of fibers will be below the resolution of the phase-contrast microscope.

Complete characterization an
1

identification of such fibers requires the following information:
•

Dimensions and morphology

•

Electron diffraction pattern

•

Elemental composition

For samples such as community air and water, for which more than one
fiber type cannot be ruled out a priori, obtaining this information is
no simple matter.

Each fiber must be identified separately by using

electron microscopes,^ equipped with X-ray fluorescence and selected
area electron diffraction capabilities, for the determination of elemental
composition and crystallographic characteristics.

With any of the analytical methods, compromises are necessary because
o? th^^lafSvely "heroic" sample-preparation methods required, especially
for tr|psraission electronic microscopy.

Many of these methods--involving

such techniques as ashing, multiple transfers of liquid resuspensions, and
filtrations—tend to subdivide fibers into fibrils.

Thus, it is often

difficult to reconstruct the original size distribution.
0-6

01 061

For samples in which the concentration of asbestos fibers is low and
the size distribution small, size distribution analysis may be unreliable
because oniy a££gw fibers will be seen.

Economic Constraints
The equipment needed for complete analyses in a continuous monitoring
program will require a highly skilled and experienced operator and
extensive technical support.

The minimum initial capital investment

required for new equipment will be in the range of $100,000-$250,000,
and an annual operating budget of nearly $100,000 will be required.
This will cover the expense of purchasing and installing a scanning/transmission electron microscope, and the salaries, fringe benefits, and
overhead expenses for a microscopist and two or three technicians.
For an uncomplicated membrane filter sample—when only one type
of fiber is present, and other particulate material

is not excessive—

the number and mass of fibers and their size distributions may be obtained
for a cost of a few hundred dollars per sample.

If the sample is more

complex, the costs may run to several thousand dollars, and the sample
may require several weeks for analysis.^

Some progress has been made in automating the counting and sizing of
fibers, from photomicrographs,

20 21
’

but these automated methods are based

only upon recognition of fibrous morphology and are therefore unsuitable
for evaluation of "mixed" exposure by fiber type.

Reproducibility of Measurements
Because of the difficulties of measuring asbestos-fiber contamina
tion, there are large variations in the measurement of asbestos in
samples of afgffld water, both within and among laboratories.

p.c9
Several^^Cj^1
Sev^.a.^,
v

replicability and duplicability studies are summarized below.
Asbestos la-Water
Although the attainment of an intralaboratory precision of -30% fn
18
analysis of water has been reported,
it is not uncommon for results
C-7

01 061 0680

rrora duplicate samples analyzed by competent workers in independent
laboratories to vary by more than an order of magnitude.
-In a reproducibility study

reported in 1975, seven "competent"

laHt?9WFTes showed readings of below-detection-limit to 9 million fibers
pef*~liter for a water sample known to contain 7.5 million fibers per liter.
In another case where five replicate analyses were made in each of two
laboratories on an identical sample, one laboratory showed readings of
0.79 to 4.0 million fibers per liter, while the other showed readings of
8. to 29. million fibers per liter.^
In another study, reported in 1976, investigators evaluated
variation among and within nine laboratories that analyzed samples of
water from five different sites on Lake Superior.

The averages for

the nine laboratories varied from 1.6 million to 78.7 million fibers per
liter.

The within-laboratory coefficient of variation (standard deviation

22

divided by the average) ranged from about 50% to 100%.''
Asbestos in Air

There is also considerable variability in measurements of atmos
asbestos concentrations, especially of ambient air, both within and
among laboratories.

Data on duplicate analyses of ten ambient air

samples from measurements by the Mount Sinai Department of Environmental
Medicine and the California Department of Health are given in Table

C-l

Differences between the two laboratories may be two orders of magnitude
or more.

No one laboratory's readings were consistently higher.

The

Mount Sinai group also conducted replicate analyses of four samples.
These results, shown in Table C-2,
order of magnitude.

show differences of less than an

The authors of the study in which these findings^*^^

were reported state that an individual value may be accurate within^^O^<3*
23

GvV O

factor of two or three of a sample mean.
'^Thfi^rnaccuracy in values obtained from a specific analysis can
»
<
.res uit from several circumstances:
(1) statistical variation in the
nurab&t-of fibrils found in given grid squares,
tion in volume of these fibrils,
bundles,

(2) a much greater varia­

(3) incomplete dispersal of chrysotile

(4) variability in the amount of material lost during processing,

and (5) low-level contamination of the sample at various points during
its preparation.and analysis.
C-~8

01 061 0681

Table

C-l

DUPLICATE ANALYSIS OF TEN AMBIENT AIR SAMPLES

Asbestos Concentration (nanograms/meter )
Calif.Dept, of Health
Mount Sinai

Sample Number
74-000-003

0.6

120.0

74-000-012

44.0

0.4

74-000-023

0.0

13.0

74-000-032

2.7

0.0

73-003-038

2.6

0.0

73-003-046

7.3a

73-003-054

7.3

0.0

73-003-064

21.0

0.0

74-000-110

46.0

14.0

74-000-119

1.4

2.2

^ith an annotation:

"Disregard, only 2 fibers observed."

Source:

(end of this Appendix) •

Reference 23

C-9
V?

<800.0

H r :;; ‘

{

01 061 0682

Table C-2
REPLICATE ANALYSIS OF FOUR AMBIENT AIR SAMPLES

3
Sample Number

Asbestos Concentration (nanograms/meter )
1st Analysis
2nd Analysis
Average

73-003-038

0.0

5.3

2.6

73-003-046

7.6

7.1

7.3

73-003-054

3.2

11.4

7.3

73-003-064

12.0

30.0

21.0

Source:

Reference 23 (end of this Appendix).

Although the phase-contrast microscopic method has been demonstfcjg^Lv
to be useful for evaluation of occupational asbestos exposures, and
coefficient of variation (for sampling and analysis) of 22% has been
reported for trained technicians,^ it should be recognized that there may
be a two-fold variation between results (for reference samples) from
experienced and novice microscopists for amosite, and a four-fold
25
variation for chrysotile.
It is also important to recognize that the
fraction of fibers in a sample of airborne asbestos that will be visible
in using this method will vary by type of asbestos and also (within
each type) by the particular industrial process being evaluated.
Conversions Between Counts by Different Methods and Between Number of
Fibers and Mass.
Because of the large variations in measurements, it is generally not
gossjjjjeJt%cpnvert counts by the phase-contrast optical method to
equivalent electron microscopic counts, except within very wide margins
of errPTT

Indications of the error that may be introduced by uncritical

acceptance of any constant factor for conversion may be found in (a)
a study of size distributions for airborne asbestos exposures in

-o ^
!/»

Cp

c-io
061

0683

various asbestos processes

2

and (2) a comparison of optical and electron

microscopic methods applied to samples of air taken from inside public

Nor can cotffits of visible dust particles by the midget impinger method
be equated with fiber levels determined by phase-contrast microscopy, as
illustrated in another study which gives measurements of both methods for
one job at four asbestos textile plants

Within a plant, asbestos levels

increased with midget impinger counts; but if comparisons are made across
plants, it is clear that the limits of uncertainty are approximately an
order of magnitude.
In a 1974 study, there were differences of several orders of magni­
tude between fiber/mass ratios in emission streams of asbestos processing
plants and mills, making any attempt to apply a constant conversion factor
26
between number and fibers and mass uncertain at best.
Some important conclusions can be drawn:
•

The ratios of electron-microscope-visible to optical-microscopevisible fibers vary among plant emissions, the workplace, and the
general environment, as well as within each of these categories.

•

No universal ratios or factors for conversion of optical micro­
scope results to electron microscope results exist.

In this

monograph, when needed, a factor of 50 has been used to convert
occupational fiber levels from optical-microscope-visible to
electron-microscope-visible fibers.

The factor is based on a

conservative estimate that 2% of total fibers are optical-microscopevisible.
• No single factor for conversion of mass emissions to fiber emissions
exists.
• Fiber/fl®S^rar$ips differ markedly from the occupational to the
generalgenvironments, and they also differ markedly within each
envirormTfnt.

The number of electron-microscope-visible fibers

per nanogram might well range from 100-10,000.

Based on the observed

data available and for convenience sake, 1000 fibers per nanogram

c-u

01 061 0684

has heen used in this monograph tor atmospheric levels near plants,
and 250 fibers per nanogram for ambient urban air.
fr-_•

The monitoring method chosen will be different for each application
’"'but must depend upon electron microscopy as a reference method.

•

Because mass of asbestos can be directly calculated from asbestos
type and electron-microscope-visible fiber size and number, it is
recommended that these indices be recorded whenever possible.

The

fiber size distribution can be completely stated by the geometric
means and standard deviations of fiber length and diameter, assum­
ing that fiber length and diameter vary independently of each other.

REFERENCES
1.

Stanton MF, et al: Carcinogencity of fibrous glass:
pleural response
in the rat in relation to fiber dimension.
J Nat Cancer Inst
587-603, 1977.

2.

Gibbs GW, Hwang CY:
Physical parameters of airborne asbestos :
in various work environments—preliminary findings. Am Ind Hy;
36(6):459-466, 1975.

I

3.

SRI International:
1976.

Personal communication with Nicholson WJ, October

4.

Cralley LJ, Keenan RG, Lynch JR:
Exposure to metals in the manufacture
of asbestos textile products.
Am Ind Hyg Assn J 28(5):452-461, 1967.

5.

Harrison JS, Roe FLC:
Studies of carcinogenesis of asbestos fibers
and their natural oils. Ann NY Acad Sci 132:439-450, 1965.

6.

Gorski CH, Stettler LE:
The surface energetics of asbestos minerals.
Am Ind Hyg Assn J 35(6):345-353, 1974.

7.

Cooper WC (Ed.):
The Need for and Feasibility of Controls of Asbestos
Air Pollution.
National Acadeny of Sciences, Washington, D.C., 1971.

8.

»Sem GJ, Tsurubayaski K: A new mass sensor for respirable dust measure­
ment. Am Ind ifyg Assn J 3(11):791-800, 1975.

9^. * AImlch B, Soloman M, Carson GA: A theoretical and laboratory evaluation
of a portable direct-reading particulate mass concentration instrument.
U.S. Dept. Health, Education and Welfare, Public Health Service. CDfl.
NIOSH, July 1975.

C-12

061 0685

10.

Mercer, TT:
Aerosol Technology in Hazard Evaluation, Academic
Press, New. York, 1973.

11.

Harwood CI^- Asbestos Air Pollution Control.

Chicago, State of

Illinois T»|< niws for Environmental Quality, 11 EO Document
#71-8,-1971.
12.

Spurney KR, et al: The sampling and electron microscopy of asbestos
aerosol in ambient air by means of Nuclepore filters.
J Air Pollut
Control Assoc 26(5): 496-498, 1976.

13.

Manalan DA:
Asbestos removal by membrane filter.
Presented at the
Spring meeting of the Parenteral Drug Association, Inc. , Dorado Beach,
Puerto Rico, April 5, 1974.

14.

Lynch JR, Ayer HE: Measurement of asbestos exposure.
10(1): 21-24, 1968.

15.

Anderson CH: A Preliminary Interim Procedure for Determining Fibrous
Asbestos.
Athens, GA, U.S. Environmental Protection Agency,
Environmental Research Laboratory, July 28, 1976.

16.

McGrath PP, Ewell JB: Application of electron microscopy to the
problem of particulate contaminants in food, drugs and biologicals.
Scanning Electron Microscopy 1976 (Part III).
Proceedings of the
Workshop on Techniques for Particulate Matter Studies in SEM.
Chicago, ITT Research Institute, April 1976.

17.

Pooley FD:
The identification of asbestos dust with electron microscop
microprobe analysis.
Ann Occup Hyg 13(3): 181-186, 1975.

18.

Beaman DR, File DM:
Quantiative determination of asbestos fiber
concentration.
Anal Chem 48(1): 101-110, 1976.

19.

Langer AM:
Approaches and constraints to identification and quanti­
fication of asbestos fiber.
Environ Health Perspect 9: 133-136, 1974.

20.

Harness I: Airborne asbestos dust evaluation.
397-404, 1973.

21.

Paylidis T, Steiglitz K:
The automatic counting of asbestos fibers
in air samples.
Presented at the 3rd Joint Conf on Pattern Recog­
nition, IEEE Computer Society, Nov. 8-11, 1976.

22.

Brown,* Jr.^AL, Taylor WF, Carter RE: The reliability of measures
of amphiboly fiber concentration in water, Environ Res 12(2): 150-160,
October 19?6“r-

23.

Nicholson WJ, et al: Asbestos Contamination of the Air in Public
Buildings.
Research Triangle Park, NC, U.S. Environmental Protection
Agency Pub. #450/3-76/004, Oct. 1975.

J Occup Med

Ann Occup Hyg 16(4):

C-13

01 061 0686

Leidel NA, Bayer SG, Zumwalde RD: Membrane Filter Method for
Evaluating Airborne Asbestos Fibers.
U.S. Public Health Service,
^JJIOSH, TN 84, 1973.
25 .~T3eckett ST, Attfield MD:
Inter-laboratory comparisons of the
— counting of asbestos fibers.
Ann Occup Hyg 17(2):85-96, 1974.
Ayer HE, Lynch JF, Fanney JH: A comparison of impinger and
membrane filter techniques for evaluating air samples in asbestos
plants.
Ann NY Acad Sci 132:274-287, 1965.
Harwood CF, Siebert P, Blazsak TP: Assessment of Particle
Control Technology for Enclosed Asbestos Sources.
Research
Triangle Park, NC, U.S. Environmental Protection Agency Pub
#650/2-74/008, Oct 1974.

F ib e r o la a . a t

33

.-■•H-fo-W*-* -

Appendix D
ANIMAL-STUDIES RELATED TO CARCINOGENIC EEFECTS
OF FIBERS

Inhalation
Mice
Hybrid mice (AC/F^) were exposed to a commercial preparation of
chrysotile dust at a concentration of 150-500 mppcf 40-60 hours per
week for 17 months and were sacrificed after exposure.

A high incidence

of multiple pulmonary adenomas* was observed in the exposed group
160+(45.7%, or 58/127), than in controls (36.0%, or 80/222).
Rats
White rats, some of whom had received an intratracheal application
of caustic,

(reportedly to impede mucociliary clearance), were exposed

to chrysotile dust 30 hours per week for 62 weeks at a mean concentration
3
of 86 mg/m .
Of 72 rats surviving 16 months or more, 25 developed
malignanat thoracic tumors (adenocarcinomas, squamous cell carcinomas,
fibrosarcomas, and a mesothelioma).

The incidence of animals with cancer

was twice as great among caustic-treated survivors (15/31 or 48%) as
among those who had not been treated (10/41 or 24%).

There were no
113
tumors in 39 caustic-treated and untreated control animals.
Squamous carcinomas of the lung were found in 2 of 31 Charles River

3

CD rats surviving exposure to crocidolite at a concentration of 49 mg/m
16 hours a week for two years.

No malignant tumors were observed among

rats exposed to chrysotile or amosite, but 5 of 40 exposed to chrysotile
--nu
106
developed multiplfepulmGjijiry adenomas.

*Benign tumors of -the lung.
+Chapter III references—see Apendix H.

D-l
:i<

01 061 0688

Groups of 69 Charles River CD rats were exposed to crocidolite,
amosite, or chrysotile at mean concentrations of about 50 mg/m
pe^week for two years.

3

16 hours

Among the group exposed to crocidolite, four

deffcjhJpeiP'malignant lung tumors (squamous cell carcinomas and an adeno­
carcinoma) .

Three of the group exposed to amosite developed thoracic

cancers (a broncoalveolar carcinoma, a fibrosarcoma, and a pleural meso­
thelioma) .

Two pulmonary carcinomas (a squamous cell and a papillary

carcinoma) and one pleural mesothelioma developed in the animals
exposed to chrysotile.
In a similar experiment, exposure for six months to two years
produced a 5% incidence of thoracic malignancies among groups exposed to
chrysotile and amosite, but a 14% incidence among the group exposed
to crocidolite.

While mass concentrations of the three types of asbestos
3
were all about 50 mg/m , counts of optically visible fibers were 54, 864,
and 1105 million per cubic meter, respectively.^^
In another study, C/D Wistar rats were exposed to amosite, antlfcs-.^
phyllite, crocidolite, and chrysotile (Canadian or Rhodesian) at a (mo=-centration of 12 mg/m^ respirable dust 7 hours per day for varying )Sngths
of exposure.

All fiber types produced asbestosis, which progressed after

removal of the rats from the dust.

Lung carcinomas and pleural meso­

theliomas were found in groups exposed to each of the four fiber types,
and a single peritoneal mesothelioma was observed among animals exposed
to crocidolite.

Forty percent of animals exposed for two years developed

malignant tumors of the lung and pleura.

No such cancers were found

among control animals.^
A dose-response relationship between asbestos and cancer was noted—
with increasing duration of exposure there was an increasing incidence of
observed malignancies.

As little as one-day exposure was sufficient to

-m prol^reei--lniig carcinomas and pleural mesotheliomas.

There was significant-

ly njpre asbestosis (taking severity of asbestosis and length of survival
intq'account') among animals with lung tumors than among those without
tumors.

In addition, among groups exposed for only one day, there were

D-2

01 061 0689

3 it-. '

in­

significantly more lung tumors among animals with asbestosis than among
those without asbestosis.^

Intratracheal InfcHL’lefKRats
White rats received 1, 2, 3, 4, or 6 intratrachael injections of

P ro d u c e d u n d e r C o u rt O rd e r

in M a rt v , Owens Co rn in g
F ib e r o la a . a t a l . . USDC SD H is s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

3.5 mg chrysotile in aqueous suspension.

Among 16-month survivors, 3

of 19 developed Dulmonary adenocarcinomas.
Two of these had received
,
’
113
4 intratracheal injections, and one had received 6 injections.
After administration of 3 injections of 2 mg chrysotile containing
0.14 mg benzo(a)pyrene (a carcinogen in cigarette smoke) at monthly
intervals, or a single injection of 2 mg chrysotile and 5 mg benzo(a)pyrene,
lung papillomas, epidermoid carcinomas, reticulosarcomas, and pleural
mesotheliomas were noted in 6/21 and 6/11 animals, respectively, within
28 months.

No tumors occured in 49 rats given 3 monthly injections of

2 mg chrysotile alone or in 19 rats administered a single dose of
,
,
, ,
108
5 mg benzo(a)pyrene.
Hamsters
Eight pulmonary adenomas, 9 tracheobronchial papillomas, and 6
pulmonary carcinomas developed among 31 LVG/LAK hamsters receiving a
dose of 4.5 benzo(a)pyrene and 12 mg chrysotile over a period of 12 weeks.
No tumors were observed in 17 animals administered chrysotile alone.
Among 34 receiving benzo(a)pyrene alone, 9 tracheobronchial papillomas
161
and 1 pulmonary carcinoma were reported.
The effect of intratracheal instillation of asbestos with oral or
subcutaneous administration of nitrosodiethylamine (NDEA) was studied
in Syrian golden hamsters.

Aqueous NDEA was administered per gastric

tube twice v&eki^lot^O-weeks (total dose 60 mg), or 3.5 mg aqueous
NDEA was iniecte^tS.ubcutaneously once a week for 12 weeks (total dose,
42 rag).

One mg cErysotile asbestos in polyglucin suspension was injected

intratracheally once weekly for 6 weeks (total dose, 6 mg), beginning
one month after the start of NDEA treatment.

After 8-10 months of 21/52

D—3

] av

1 0

01 061 0690

and 14/51 animals developed benign and malignant pulmonary tumors among
the groups receiving asbestos and oral NDEA or subcutaneous NDEA, respec­
tably.

Among control groups receiving oral NDEA, subcutaneous NDEA,

oMSWtos alone, only 1/50, 3/47, and 0/50 developed pulmonary tumors.

Intrapleural Injection
Mice
Two of 75 BALB/c mice receiving intrapleural inoculations of 10 mg
crocidolite in aqueous suspension developed pleural tumors, but no
tumors were observed among 75 mice injected with 10 mg chrysotile.

163

Rats
A single dose of 20 mg of crocidolite, amosite, anthophyllite, or
chrysotile from various sources administered to CD Wistar rats produced
an incidence of pleural mesothelioma ranging from 19% to 70%.

Yet as

little as 0.5 mg chrysotile or crocidolite was sufficient to indue
mesotheliomas. ^7
Various asbestos types have induced mesotheliomas following intra­
pleural injection in Osborne-Mendel, Sprague-Dawley, CFY and Wistar/Alderly
ICI rats.107’108’161’1

The carcinogenic response to chrysotile and
107,117
crocidolite appeared to be dose-related.'
Oil-extracted asbestos gave results similar to untreated samples,107,164
2.65
thus casting doubt upon the hypothesis that natural oils and waxes,
166,167
contaminant oils from the milling process
or organic materials
168
originating from storage in plastic or jute bags
contribute to the
carcinogenicity of asbestos.
It has also been suggested that metal contaminants added during
113
processing of fiber play a role in asbestos carcinogenesis.
Sv^sequent experiments using rats^^^ ’7’7*7 have demonstrated that (1) treatme£E~with acid, base, and ethylene diamine tetra-ascetic acid to remove
-metal contaminants;

(2) selecting asbestos samples from among interior

fibers not exposed to containminating hammermills; or (3) using^d£?i^e$ent

n®
D-4

01 061 0691

■

samples of the same asbestos type containing different quantities of
trace metals dic^not produce different tumor yields.

By way of contrast,

heating samples 5&r"'two”hours at 900-1000°C resulted in a substantial
—
169
loss of carcinogenic activity in rats.
Fiber diameter and length, in addition to shape, may be important
determinants of carcinogenic potency.

Eight subsamples of U.I.C.C.

chrysotile were milled individually to a finer powder than the standard
mixture.

Injection of each subsample intrapleurally resulted in a

higher yield of mesotheliomas in Wistar rats than did the pooled refer­
ence material.

The highest tumor yield of all was produced by a separate

superfine chrysotile prepared by water sedimentation of Grade 7 commer­
cial asbestos.

Carcinogenicity was correlated with number of fibers
107
less than 0.5ym in diameter and greater than 10pm long.

■

On the other hand, pulverizing asbestos before applying it to the
pleura of Osborne-Mendel rats by means of a coated glass pledget reduced

it

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . Owens C o rm n c
F ib e r o la a .
a l. USDC SD M ie s : C o n fid e n tia l in t o n a t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

(Union Internationale Contre le Cancer) standard reference Canadian

carcinogenicity.

Fibers of diameter less than 0.2pm and length 5-10pm,

which were present in greater numbers in pulverized specimens, were
considered to be less effective carcinogens than fibers of greater size.

118

By contrast, after intraperitoneal injection (see "Intraperitoneal
54

Injection" below), fibers less than 5pm long were fully potent in inducing
tumors.

It must be kept in mind that prolonged milling may alter the

crystalline structure of asbestos and thus influence biological effects.
Hamsters, Guinea Pigs, and Rabbits
Pleural mesotheliomas developed in Golden Syrian hamsters after
intrapleural injection of 10 mg chrysotile, amosite, anthophyllite, or
crocidolite.. TSgj^ppargnt dose-response relationship was observed for
^ ” chrysolite, with^O, 4, and 9 mesotheliomas induced among 50 animals by
injection of 1, fib-Or 25 mg, respectively.

Prolonged milling, which

reduced the maT&rity of fibers to submicroscopic dimensions, eliminated
109
carcinogenic effects and greatly reduced fibrogenic activity.

~<r\
<;

0&
D-5
V V;

' r

01 061 0692

One pleural tumor was observed among 50 guinea pigs inoculated with
l^"m

crocidolite in an aqueous suspension, but none were observed in

a~similar group inoculated with chrysotile.
Of 3 rabbits surviving at least 12 months following injection with
16 mg crocidolite, 2 developed pleural mesotheliomas, one at 22 and
,
106
one at 24 months.

Intraperitoneal Injection (Mice and Rats)
Peritoneal mesotheliomas occured in 20 of 60 BALB/c mice within
18 months of injection with 10 mg crocidolite.
Peritoneal mesotheliomas were reported in Charles River CD, Sprague
Dawley, and Wistar rats following intraperitoneal injection of crocicolite^^,^^’^^,^2 and in Charles River CD and Wistar rats fol^wing
injection of chrysotile.'*'^,'*''^,^2 Although the incidence of perifcnesal
tumors among groups of 40 animals was virtually identical, the tim^from
injection to observation of the earliest tumor was 276 days for 25=^6g
173
chrysotile as opposed to 343 for 6 mg chrysotile.
Tumors were produced
by four 25 mg injections of powdered chrysotile (99.8%) of the fibers
less than 5pm long), although the incidence was somewhat less than for
standard chrysotile (12/37, or 32%, vs. 18/33, or 55%)

112

Subcutaneous Injection (Mice and Rats)
CBA mice developed injection-site sarcomas and pleural and peritoneal
mesotheliomas (2+5/17, 2+2/13, 1+1/12) after three sets of bilateral
inguinal injections of 10 mg crocidolite, amosite, or chrysotile at inter­
vals of 5 weeks.
No tumors were observed among 15 controls injected with
174
s®toeThe investigators, however, have been unable to duplicate their
filings and believe that, in their experiments, asbestos either was in­
jected directly into the pleural or peritoneal cavities or ulcerated into
175
""tKese cavities through the overlying tissues
A single local tumor was observed following injection of 75 mg
™«.U2
chrysotile to 33 Wistar rats.

D-6

01 061 0693

Oral Administration (Rats and Hamsters)
One gastric-, leiomyosarcoma developed among 32 Wistar SPF rats
fed 100 mg/day clyysotile 5 days per week for 100 days in a 6-raonth
period.

No tumo^ggAJLQTVed among 16 controls.

Among 42 animals examined after an average of 441 days on a diet
containing 50 mg/kg body weight per day asbestos filter material (52.6%
chrysotile asbestos), 12 malignant tumors were observed:

4 kidney

carcinomas, 1 lung carcinoma, 3 reticulum cell sarcomas, and 4 liver
cell carcinomas.

Seven benign tumors including 1 lung adenoma, 2

cholangiomas, 2 stomach papillomas, and 2 mammary fibroadenomas were
also noted.

Among 49 untreated controls surviving an average of 702

days, 2 liver cell carcinomas and 5 mammary fibroadenomas occurred.

The

increased incidence of malignant tumors in the group fed asbestos filter
material was statistically significant (p <0.01)

> however, the meaning

of this study as regards asbestos is uncertain since asbestos comprised
only half of the filter material administered.
Ten rats fed a diet containing chrysotile, 5% by weight, for 21
months did not develop malignancies.

Groups of 28-35 rats fed 10 mg

chrysotile or crocidolite in butter once weekly for 16 or 18 weeks de­
veloped no malignant lesions which, when compared with a control group,
could be related to the ingested asbestos. ^
No tumors of the gastrointestinal tract were observed in groups of
45 hamsters fed a diet containing 1% chrysotile or amosite by weight
for their lifespans.

Carcinogenicity of Other Mineral Fibers
Jiineral fibers other than asbestos have been shown to be carcino­
genic by the intrapleural or intraperitoneal routes of administration—
but only wheir of *^diaine£er_ similar to that of asbestos fibers (less
than 5v—) •

-

•IE—

In groups Trf- 32 rats, mesotheliomas occurred in 18 of those injected
intrapierurally with fibrous brucite or "nemalite," which may be contaminatfed with chrysotile, in 3 of those injected with a ceramic fiber,

.

-e.Cbv

0
D-7

01 061 0694

and in 1 each of those injected with fibers of barium sulfate, glass
powder, and aluminum oxide.107 In studies by another team of investiga­
te^?,- the following results were noted:

intraperitoneal injection of

pafygorscite (attapulgite) and nemalite--3 doses of 25 mg and 4 doses
of 25 mg, respectively—resulted in tumors in about 75% of Wistar rats
(26/34, 25/34).

Gypsum, although fibrous, gave a low tumor yield (3/35),

pethaps because it dissolves in tissue.

Non-fibrous dusts (pectolite,

sanidine, talc, biotite, hematite) produced few or no tumors.

A dose-

response relationship was observed for glass fibers—intraperitoneal
injection of 2 mg, 10 mg, and 2 doses of 25 mg results in tumors in 27%
«3
C O •
I III

i -q 2

(21/73), 53% (44/77), and 71% (55/77), respectively.

No tumors appeared

among 72 control animals.

..a
a
op
m

h x -d •

U0 MQ 0a *>u
ua o -53
0o

OQUU
M 0.
HD * •
M
MW

M

< • J3

W *i

■o0 1-« (Iw
o>

0

Appendix E
AIR AND DRINKING WATER ASBESTOS CONCENTRATIONS
FROM SOME PUBLISHED STUDIES

±z -

Table E-l

P ro d u c e d u n d e r C o u rt O ro e r in H a rt v . Owens C o rn in g

F ib e r a la a . . t a l. . USDC SD M ie s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
e c c o rd e n c e w it h t h is C o u r t '* o r d e r .

Atmospheric Concentrations of Asbestos
In Some U.S. Urban Areas

Concentration
(Nanograms/m3)
Average
Range
Berkeley, CA

6.8

Source
(Chapter V
Reference)

2.1-12

67

Boston, MA

5.0

Chicago, IL

24

9.5-200

67

Dayton, OH

6

0.4-11

14

Frankfort, KY

0.09

0.02-0.15

14

Houston, TX

5

4-6

14

Los Angeles (freeway)

27a

13

Los Angeles (control)

43a

13

New York City, NY

13.2

8.2-41

67

Manhattan, NY

30 3

8-65

32

Brooklyn, NY

19a

6-39

32

Bronx, NY

12*

2-25

32

Queens, NY

9a

3-18

32

Staten Island, NY

8a

5-14

32

Pittsburgh, PA

4

2-8

14

Philadelphia, PA

70a

45-100

15

Port Allegany, PA

15a

10-20

15

Ridgewood.

20a

15

15

San FrinciStfo, C£

25

8.7-68

67

Washington.lfec

21

1.6-40

14

a

67

Identified as chrysotile asbestos by the authors.

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01 061 0700

Appendix F
SMOKING CESSATION PROGRAMS

Although a BUSS'e'F'of different program strategies may reduce smoking
rates, significant long-term cessation of smoking is rare.

Most reviews

indicate that the greatest rate of recidivism occurs between 1 and 5 weeks
following treatment, when only 30% of those who had been abstinent at the
end of treatment report continued abstinence.

Follow-up at 3-18 months

indicates approximate cessation rates of 20%-30%.

One report noted 18%

cessation at 5 years after treatment.^"
Most smoking cessation programs have enrolled volunteers, who may
have been motivated to quit on their own.

Since 16% of persons who quit

by themselves have been reported to remain abstinent one year,

2

the 20%

to 30% rates of abstinence achieved 3 to 18 months after smoking cessation
programs suggest that formal cessation programs may be only of modest benefit.
Such programs, however, may be substantially beneficial for persons who might
not have been able to quit on their own.
The discussion in this Appendix is intended to provide a broad per­
spective of the available options.

There are several published works that

provide a more comprehensive review of the subject.^^

Counseling by Health Professionals
When they advise patients to quit or reduce smoking, health profes­
sionals, particularly physicians, serve as agents of behavior change.
One report described the results of a physician counseling program in
which 100 surgical patients were seen for a brief interview during which
the health hazards and financial burdens of smoking were discussed.
one year, 30% of males and 11% of females had stopped smoking.

After

Following

another such prSJ^amj.jghich included medical lectures, physical examinations,
group discussion^and films, the quit rate was 58%, and 29% were still
—
8 9
abstinent a year-iater. ’

F-l

01 061 070

A number of health organizations have developed visual aids—pamphlets,
'films and posters—to assist physicians and others in counseling patients
-smoke.

These organizations include the American Lung Association,

BaSrican Cancer Society, National Clearinghouse for Smoking and Health,
.and the American Heart Association.

Titles of a number of the visual aids

offered by these organizations are given in the National Cancer Institute's
The Smoking Digest (in press).

Addresses of the organizations will be

il.

n o t t o e e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t '* o r d e r .

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owen* C o rm n Q
F ib a r o ia a . « c
. OSDC SD M i* s :
C o n fid e n tia l in fo r m a tio n

found in Table F-l.

Self-Help Program
A recent Gallup poll (1974) Indicated that only 34% of smokers
expressing a desire to quit were interested in attending cessation clinics.
The majority of smokers who became abstinent quit without the use of formal
smoking-cessation interventions.^
There appears, however, to be a great deal of interest in self-help
manuals and kits as judged by the amount of such materials requesEd-'during
11
■B*~~ ~ r ~
antismoking campaigns.
A typical self-help manual includes a bpfavioral
interpretation of smoking, a general explanation of the principle
behavior change, and specific instructions for implementing self-control
procedures directed at smoking cessation.

12

For example, the smoker might

be instructed to:
•

List positive reasons for quitting
Record the time each cigarette is smoked
Note feelings and behavior prior to and during each smoke
Reduce gradually the number of cigarettes smoked
Impose circumstantial barriers to smoking, such as not
carrying matches
Change brands twice weekly, choosing each time a brand
lower in tar and nicotine

-q

.jfU._Increase physical activity
«=-

•

Refrain from smoking for 48 hours

•

Avoid situations most closely associated with smoking

•

Find substitute behaviors for smoking

The effectiveness of self-help programs has not been established.

01 061 0702

Table F-l

P ro d u c e d u n d e r C o u rt O rd e r

in M a rt v .. Q w ent C o rm n c

F ib a r n la a . a t a l . . USDC SD M ie s : C o n iid e n t ia i in io n s e tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

•POTENTIAL SOURCES OF ADDITIONAL INFORMATION
Action on SmojjHealth (ASH)
2000 H Street £_NW
Washington, D.C.
20006

(202) 659-4310

American Cancer Society
777 Third Avenue
New York, New York 10017

(212) 371-2900

American Health Foundation
Department of Behavioral Sciences
1370 Avenue of the Americas
New York, New York 10019

(212) 489-8700

American Heart Association
7320 Greenville Avenue
Dallas, Texas
75231

(214) 750-5300

American Lung Association
1740 Broadway
New York, New York 10019

(212) 245-8000

Canadian Council on Smoking and Health
343 O'Connor
Ottawa, Ontario K-2P-1V9

(613) 236-6035

Cancer Information Clearinghouse
7910 Woodmont Avenue
Suite 1320
Bethesda, Maryland 20014

(301) 565-5955

General Headquarters
5 Day Plan to Stop Smoking
Seventh Day Adventist Church
Narcotics Education Division
6840 Eastern Avenue, N.W.
Washington, D.C.
20012

(202) 723-0800

Kaiser Foundation Research Institute
1956 WebsterStreet, Room 310B
Oakland, £alljjpmLa~_94612
»
National ^As so citation on Smoking and Health
4155 East Jewe‘t~~Avenue
Denver, Cole*ado 80237

(415) 645-5000

(303) 753-0777

■ssfr

(Continued, next page)

£ S> x‘ f>

: H

s h

F-3

01 061 0703

Table F-l (continued)

National Clearinghouse for Smoking and Health
Pifelic Health Service
U ifc ^Jewrtment of Health, Education & Welfare
Center for Disease Control
Atlanta, Georgia 30333

(404) 633-3311
X 3235 - Tech. Info.
X 3145 - Public Info.

National Interagency Council on Smoking and Health
419 Park Avenue South
New York, New York

(212) 532-6035

Occupational Health and Safety Administration
U.S. Department of Labor
Constitution Avenue and Third Street, N.W.
Washington, D.C.
20210

(202) 523-7081

Schick Center
4101 Frawley Drive
Fort Worth, Texas
76118

(817) 268-1157

Smoking and Health Information Program
P.0. Box 2003
Tyler, Texas
75710

(214) 877-3011

SmokEnders
Memorial Parkway
Phillipsburg, New Jersey

08865

The Tobacco Institute
1776 K Street, N.W.
Washington, D.C.
20006

(202) 457-4800

Tyler Asbestos Workers Program
P.0. Box 2003
Tyler, Texas 75710

(214) 877-3011

Source:

Adopted from The Smoking Digest, National Cancer Institute
' (in press).

F-4

01 061 0704

*

Group Therapy and Five-Day Plan
Various health organizations have sponsored community group
smoking cessa^on clinics, which provide health information, encourage­
>,
o.

ment, and crrmjj.

Groups typically involve 8-18 persons and a

group leader, jneeting once or twice weekly for a month.

Participants

in the group are informed of smoking risks, asked to describe why they
smoke and to detail their smoking habits, and are then encouraged to
Estimates of the effecX3
tiveness of these programs after one year range from 18%-25%.
’

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . Owens C o rn in g

F iQ e r o U g , «f. a l. . USDC SD H ie s : C o n fid e n tia l in f o r * a t io n ,
n o t t o t>e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t's o r d e r .

follow one of several procedures for quitting.

Higher success rates result from programs stressing formal long-term
maintenance support.
One variant of group therapy is the Five-Day Plan, which consists
of five daily meetings, 1-1/2 to 2 hours each.

Up to several hundred

volunteer participants may be treated at these sessions.

Intervention

strategies range from lectures and inspirational messages to fear-arousing
stimuli and behavior modification procedures.

One such program—a live-in

clinic including lectures, exercise, and individual as well as group therapy—j
reported 21%-40% quit rates at a three-month follow-up.
Isolated use of the nonspecific treatment factors characteristic of
the smoking clinic approach (e.g., suggestion, high expectation of success
in quitting) result in post-treatment cessation rates similar to those of
3 15
clinics that use specific planned intervention strategies. *
A follow­
up of a group of 559 volunteers who had attended such a smoking clinic
(pharmacologic agents, health education, and brief suggestions to use
certain techniques for quitting) indicated that only 18% remained abstinent
at five years.^"

Behavior Therapies
The beha«Aor therapy approach assumes that problematic behavior
*
- is a function of a person's learned pattern of interacting with the
environment.

fire goal is to teach more adaptive means of responding.

The initial-atep is a "behavioral assessment," an evaluation that in­
cludes identification of antecedent events that trigger smoking; determin­
ation of thoughts and feelings that influence smoking behavior; analysis of

F-5

01 061 0705

personal smoking behavior (frequency, situations); and identification
of the psychological consequences of smoking.

A number of techniques

may ttfaen be used to teach the individual new patterns of interacting
*
"___
4 12
withggmi'llWfmental smoking stimuli. *
These techniques can be grouped
into-five major categories; systematic desensitization, punishment and
aversive conditioning, stimulus control, reinforcement of nonsmoking, and
multicomponent interventions.
Assuming that it is anxiety that elicits the urge to smoke, attempts
have been made using relaxation techniques to desensitize smokers system16 17 18
_~
atically to anxiety-evoking stimuli.
’
’
However, no substantial effect
on smoking behavior has been reported.
•3
V 3

A number of aversive conditioning techniques have been employed to

Hi
modify smoking behavior.

Loud noises or electric shocks have been coupled

to smoking or to the urge to smoke, generally with little effect.
■a X V m
9 UQ U **
tun o u

Sul?

12

Two techniques incorporate cigarette smoke as the aversive stimii

oo u o
in a

*J D • •

•/ Rapid smoking, which requires the individual to smoke rapidly
and continuously, sometimes in conjunction with drafts of waning*
smoky air
3W
S

•

Satiation, which requires increasing cigarette consumption
over a certain period of time (e.g., smoking double or triple
the usual amount for a week)

In the context of a persuasive interpersonal relationship between
patient and therapist, the rapid smoking technique appears to result
in about 50% abstinence three to six months following termination.

12

While one report of a satiation program indicated 62% cessation four months
19
12
following treatment,
other programs have not been as successful.
Before implementing the rapid smoking method, a medical screening should
be required of participants due to the possible deleterious effects of
increased carbon monoxide levels.

20

Another behavioral technique is stimulus control. This may involve
forbidjding smoking in situations where smoking would habitually occur
(eno smoking while drinking coffee, watching TV, or following a
meal) as well as gradually restricting the number of situations where
smoking is permitted.

Whilej(a) .there appears to be no clear cessation

effect from using this method and (b) a high attrition has been reported
frequently, reduction in the rate of cigarette consumption does result.^
The reinforce^nt of abstinence through the use of social or monetary
incentives has beeflCfBTSTTvely successful.

An example of a technique

incorporating a moifSttary incentive is the use of a deposit made prior to
initiation of the program.

The money is returned in portions made con­

tingent upon progressively longer periods of abstinence.

Fifty percent

cessation has been reported at six months as opposed to 24% in a group
not employing the incentive.

21 22
*

Multicomponent interventions have been designed by combining these
techniques.

A number of reports indicate that this approach may yield

high abstinence rates (65% to 100% immediately; 55% to 65% after one
year).23*27

Miscellaneous Individualized Techniques
There are a series of cigarette filters designed to assist smoking
cessation by gradually reducing levels of inhaled tar and nicotine.

The

extent to which this method has been effective has not been evaluated.^
A diverse array of medications—including stimulants as well as
tranquilizers, nicotine substitutes as well as antagonists, and anti­
cholinergics—have been prescribed to assist smokers in overcoming
withdrawal symptoms.

With regard to actual cessation, however, none of
28
these pharmacologic agents has shown any more promise than placebos.

In fact, several studies have suggested that placebo groups may have
higher quit rates.
Very little research is available on the effects of acupuncture
as a smoking cessation tool.

In one study, 50% of subjects were reported
29
abstinent six weeks following auricular acupuncture.
This cessation
rate is similar tdSHidSiS^&btained using less invasive techniques, and,
at the present- tim4f~the use of acupuncture does not appear to be just. lied.
Hypnotic techniques have included attempts to reveal personality
conflicts assumed to be major underlying causes of the smoking habit as
30 31
well as direct suggestions to quit.
’
While certain investigators

> U

\ a

F-7

01 061 0707

have reported positive initial results ,
studies.

32 33
’
there have been few controlled

Furthermore, initial successes have not been maintained at

follow-up.

One report of the results of a single session self-hypnotic
34
ti ££^nRffSTrtr noted a cessation rate at one year of 20%.
Using this approach.
another investigator has observed significantly higher rates of recidivism
than with group counseling.
Three issues related to smoking cessation—monitoring of smoking

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . Owens fio rm n a
r ih e r o ia a . a t * 1 . . USDC SO M i* 6 : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e v it b t h is C o u r t 's o r d e r .

behavior, the "successful quitter," and gain of weight—are summarized
briefly in Tahle F-2.

Smoking Cessation Programs in Industry
Industry provides an ideal setting for smoking cessation programs.
Industrial programs often have the advantages of:
•

An existing system of occupational health care, which affords
a means of careful health surveillance and follow-up
An established network of communications, which permits thq
rapid dissemination of health information
Peer and management interaction, which provides for social
incentives
Readily perceived benefits in terms of diminished illness and
absenteeism, which can be assessed against program costs.

While the plant physician may wish to refer workers to smoking
cessation programs outside the workplace, on-site programs reduce lost
time and inconvenience.

The local chapter of the American Cancer Society

would be an excellent resource for information on available outside
programs.

(See also other information resources in Table F-l.)

A number of imaginative industry-based smoking cessation programs
have been established, but as yet there have been no published reports
of their effectiveness.

Several programs have been described

IfitSfinatic Incorporated (Detroit) has a no-smoking "parimutuel"
window where employees can bet up to $100 on their ability to
stop smoking for a year.
The company has contributed $1,000 to
be divided among successful participants.
Persons not remaining
abstinent donate their bet to the American Cancer Society.

01 061 0708

Table F-2
MONITORING SMOKING BEHAVIOR, THE SUCCESSFUL
QUITTER, AND WEIGHT GAIN

•

Monitorlrrg Smoking Behavior
As with any intervention, monitoring of treatment effectiveness is
critical.

Although self-support has been the major measure used to

date, it lacks precision for a variety of reasons which include the
desire to please, denial of shortcomings, or inconsistent motivation
to maintain accurate records over reporting intervals.

Such objective

measures as serum thiocyanate or expired-air carbon monoxide, along
36
with self-support, might be useful for monitoring.

•

The Successful Quitter
The successful quitter is likely to be a man, to be concerned about
his health, to be older, to report fewer neurotic or psychosomatic
symptoms, to smoke less and to have begun smoking at a later age, to
have a supportive social milieu, and to have tried to quit on several
1 37
previous occasions. *
The behavior of spouses appears to be a
significant factor.

Smokers with nonsmoking spouses, spouses who also

quit, or spouses who "made it easier to quit" were more likely to
remain abstinent at 5-year follow-up.

•

Weight Gain
A frequent concern expressed by those planning to stop smoking is
whether or not they will gain weight.

Indeed, three out of four
38
persons in one study gained weight after giving up cigarettes.
Specific attention to the possibility of weight gain—i.e., a
special^iefiKy ""Sr^behavioral weight management program—might pos-

%

sibly be usejtto good, advantage in cessation programs.

Source:

Appendix References cited.

F-9
\ ■

01 061 0709

The Aluminaire Standard Glass Company (Phoenix) has established
a program in which a dollar amount equivalent to what abstinent
smokers would have spent for cigarettes is deducted from paychecks,
i At the end of one year the company matches the total deductions
^~and pays the entire sum to the worker providing he has remained
m wbreinent.
Sears Roebuck and Company (New York) encourages employees to take
outside smoking cessation courses by rebating a portion of course
fees to those remaining abstinent for six months or more.
An interesting program package including education and social
monetary incentives was implemented at the Dow Chemical Company
(Freeport, Texas) in collaboration with the American Cancer Society.
Abstinence was rewarded by a dollar each week, and abstinent workers
were enrolled in monthly and quarterly lotteries for prizes that
included a boat and motor as well'as cash awards.
Ex-smokers were
used to recruit program participants.
For each recruited participant
who remained abstinent for one month, the recruiter was awarded a
chance in a lottery.
(Recruiter incentive is thought to provide a
useful source of social mobilization.)39 Of 395 participants, only
15 (less than 4%) continued to smoke at program termination; however,
the lack of adequate follow-up precludes an assessment of long-term
effects.
While these programs are useful in providing rationale and moti­
vation for smoking abstinence, some persons do not possess the skills
needed to quit.

It would be useful to assist such persons through the

use of behavior therapies.

REFERENCES
1.

West DW, et al: Five year follow-up of a smoking withdrawal clinic
population.
Public Health 67:536-544, 1977.

2.

Guilford J: Factors Related to Successful Abstinence from Smoking:
Final Report. Los Angeles, American Institute for Research, 1966.

3.

Bernstein DA: Modification of smoking behavior:
review.
Psychol Bull 71:418-440, 1969.

4.

Bernstein DA, McAlister A: The Modification of Smoking Behavior:
Progress and problems. Addict Behav 1:89-102, 1976.

An evaluative

W Hunt WA, Matarazzo JD: Three years later:
recent developments in
■Khe^^sperimental modifications of smoking behavior. Abnorma
Psychol 81:107-114, 1973.
6. —Schwartz JL: A critical review and evaluation of smoking control
*~methods.
Public Health Rep 84:489-506, 1969.

F-10

01 061 0710

7.

Schwartz JL, Rider G: Smoking cessation methods in the United States
and Canada:
1969-1974. In: Steinfeld J, Griffiths W, Ball K,
Taylor Rm,(-eds.) Proceedings of the 3rd World Conference on Smoking
and Health.. DHEW Publication No. (NIH) 77-1413, 1977.

8.

Handel
Med J 4_

Postgrad
, ____

9.

Delarue NC:
A study in smoking withdrawal:
the Toronto smoking
withdrawal study centre: description of activities.
Can J Public
Health 64:2,5-19, 1973.

10.

National Cancer Institute.
The Smoking Digest:
a Nation Kicking the Habit (in press).

11.

Dubren R: Evaluation of a televised stop-smoking clinic.
Rep 92:81-84, 1977.

12.

Lichtenstein E, Danaher BG: Modification of smoking behavior: A
critical analysis of theory, research and practice.
In Hersen M,
Eisler RM, Miller PM, (eds.) Progress in behavior modification
(vol 3) New York: Academic Press, 1976.

13.

National Clearinghouse for Smoking and Health.
1975. HEW Public Health Service, 1976.

14.

Schwartz JL, Dubitzky M: One-year follow-up results of a smoking
cessation program.
Can Public Health 59:161-165, 1968.

15.

Lichtenstein E, et al: Comparison of rapid smoking, warm, smoky
air, and attention placebo in the modification of smoking behavior.
J Consult Clin Psychol 40:92-98, 1973.

16.

Koenig KP, Masters J: Experimental treatment of habitual smoking.
Behav Rese Ther 3:235-243, 1965.

17.

Pyke S, McK Agnew N, Kopperud J; Modification of an overlearned
maladaptive response through a relearning program: A pilot study
on smoking.
Behav Rese Ther 4:197-203, 1966.

18.

Wagner JK, Bragg RA: Comparing behavior modification approaches
to habit decrement-smoking. J Consult Clin Psychol 34:258-263, 1970.

19.

Resnick JH: Effects of stimulus satiation on the overlearned
maladaptive response of cigarette smoking.
J Consult Clin Psychol
32:501-505, 1968.

20.

Miller LC, ^t al: Potential hazards of rapid smoking as a techni­
que foe th|(Bedific.ation of smoking behavior.
N Engl J Med
297:59t)-59f? 1977'."

.

Progress Report on

Pub Health

Adult use of tobacco:

21

Tiche TJ, Elliott R: Breaking the cigarette habit: effects of the
technique invulving threatened loss of money.
Paper presented at
the annual meeting of the American Psychological Association, 1967.

22.

Winett RA: Parameters of deposit contracts in the modification of
smoking. Psychol Rec 23:49-60, 1973.

F-ll

01 0G1 0711

23.

Harris MB, Rothberg C: A self-control approach to reduced smoking.
Psychol Rep 31:165-166, 1972.

24i

Chapman RF, Smith JW, Layden TA: Elimination of cigarette smoking
by punishment and self-management training.
Behav Res Ther
B^i»iWfr-264, 1971.

25T~ Morrow J, et al: Elimination of cigarette smoking behavior by
stimulus satiation, self-control techniques, and group therapy.
Paper presented to the meeting of the Western Psychological Asso­
ciation, Los Angeles, April 1973.

P ro d u c e d u n d e r C o u rt O ra e r

Pomerleau OF, Ciccone P: Preliminary results of a treatment pro­
gram for smoking cessation using multiple behavior and modification
techniques. Paper presented to the meeting of the Association for
Advancement of Behavior Therapy, Chicago, November 1974.

N)

CD

Tooley JT, Pratt S: An experimental procedure for the extinction
of smoking behavior. Psychol Rec 17:209-218, 1967.

■

in H a rt v , Owens c o rn in c
F ifa e ro la a . > t a l . . USDC SD H is s : C o n t id e n t ie l in to rm e tio n
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d ee rr..

wja

sn
29.

HIh

Gritz ER, Jarvlk ME: Pharmacological aids for the cessation of
smoking.
In Steinfeld J, Griffiths W, Ball K, Taylor RM, (eds
Proceedings of the 3rd World Conference on Smoking and Health,
DHFU
■p’SV'
DHEW Publication
Publication No
No. fNIHl
(NIH) 77-1413
1413, 1974
? &. ClG*
°
C*
1 nk al 4c
ulODK^do

Aiit*i attl oi*
nUllLUXdi

nn.i n< inpfnv*m
aLUpUUL
LUL c

ann
dUU

b
nn
LUC

cmnV ■(
o
olllUf.XUg

nflnl f- •
UaUlL

M
m i xt
LiUUV

30.
Bryan WJ:

awM

A*
A<

Presse Med p. 980, 1974.
Hypnosis and smoking,

J Am Inst Hypn 5:17-37, 1964.

31.

Johnston E, Donoghue JR: Hypnosis and smoking: A review of the
literature. Am J of Clin Hypn 13:265-272, 1971.

32.

Korger WS: Clinical and Experimental Hypnosis.
Thomas, 1963.

33.

von Dedenroth TEA: The use of hypnosis in 1000 cases of "tobaccomaniacs." Am J Clin Hypn 10:194-197, 1968.

o

u

4HmH|

9m

ShH

34.

35.

JǤm9

36'

Springfield:

Spiegel H: A single-treatment method to stop smoking using ancillary
self-hypnosis.
Int J Clin Exp Hypn 18:235-249, 1970.
Shewchuk LA: A comparison of smoking cessation techniques:
Initial
success and eventual recidivism.
Submitted to Public Health Reports,
1976.
Vogt TM, et al: Expired air carbon monoxide and serum thiocyanate
as objective measures of cigarette exposure. Am J Public Health
^67:545-549, 1977.

37 ? ^Pederson LL, Lefcoe NM: A psychological and behavioral comparison
*~of ex-smokers and smokers. J Chronic Dis 29:431-434, 1976.

MBH1

-a»r Hammond EC,Percy C:

Ijlggl ,

39.

Ex-Smokers.

NY State J Med 58:2956-2959, 1958.

Janis IL, Hoffman D: Facilitating effects on daily contact between
partners who make a decision to cut down on smoking. J Pers
and Soc Psychol 17:25-35, 1970.

F-12

01 061 0712

Appendix G
SOURCES OF EDUCATIONAL MATERIALS

1.

Sources of^wtfLTVlied Educational Materials

Asbestos Information Association/NA
Materials:

Brochures on work practices, fact books, reprints of

P ro d u c e d u n d e r C o u rt O rd e r

in H a rt v . Owens Co rn in g
F ib a r o ia a . « t a i . . USDC SO H ie s : C o n fid e n tia l in f o r H e t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

scientific articles, conference proceedings, and films;
reference library.
Address:

1835 "K" Street, N.W.
Washington, D.C.
20006

Asbestos Information Committee
Materials:

Brochures on work practices, health effects, and
control procedures.

Address:

10 Wardour Street
London, W1V 3HG
England

Asbestos Research Council
Materials:

Brochures on work practices, ventilation, control
procedures, protective devices, and disposal methods.

Address:

P.0. Box 18 Cleckheaton
West Yorkshire, BD19 3UJ, England

Congress of the United States
Materials:

Pertinent Public Laws

Address:

Document Room, Congress of the United States,
Washington, D.C.

Johns-Manville Corporation

....

W

Materials:? Brochures on work practices, health effects, films,

^

It-.

siidps with sound, slides with script, video tapes,

newspaper, bulletins, letters, reports, and reprints
of scientific articles.

G-l
> < i 7' i
s

i

01 061 0713

Address:

Health, Safety and Environment Department
Ken-Caryl Ranch
Denver, Colorado 80217

ffational Institute of Occupational Safety and Health, U.S.
J^artment of Health, Education and Welfare
'Materials:

"Criteria Document" on Asbestos; reports of occupational
disease research and epidemiologic investigations.

Address:

Robert A. Taft Laboratories
4676 Columbia Parkway
Cincinnati, Ohio 45226

National Safety Council
Materials:

Reprints of articles, safety data sheets; reference
library.

Address:

425 North Michigan Avenue
Chicago, Illinois
60611

Occupational Safety and Health Administration, U.S. Department
of Labor
Materials:

Occupational Safety and Health Standard:
Subpart Z, Sec. 1910.1001, Asbestos
Brochures on OSHA 1970

Address:

Occupational Safety and Health. Administration
U.S. Department of Labor
Washington, D.C.
20210

Oil, Chemical and Atomic Workers International Union, AFL-CIO
Materials:

Poster, slide-tape cassette presentation

Address:

Citizenship-Legislative Department
1126-16th Street, N.W.
Washington, D.C.
20036

ebec Asbestos Mining Association
Imperials

Brochures on work practices, health effects, and
control procedures.

Address:

5 Place Ville Marie
Montreal 113, Quebec, Canada
G-2

01 061 0714

2.

Possible Sources of Published Educational Materials

American Association of Poison Control Centers
~c/o"Academy of Medicine of Cleveland
Poison Information Center
10525 Carnegie Avenue
Cleveland, Ohio 44105
American Medical Association
535 North Dearborn Street
Chicago, Illinois 60610
American Public Health Association
1015-18th Street, N.W.
Washington, D.C, 20036
Center for Science in the Public Interest
1757 "S" Street, N.W.
Washington, D.C. 20009
Companies mining asbestos ore
Consumer Federation of America
1012-14th Street, N.W., Suite 901
Washington, D.C. 20005
Consumers Union
256 Washington Street
Mount Vernon, New York

10550

Health Research Group
2000 ”P" Street, N.W., Suite 708
Washington, D.C. 20036
Insulation Industry Hygiene Research Program
'
"

•F'" ‘Environmental Sciences Laboratory
?
Mount Sinai School of Medicine of the City University
of New York
■-----Fifth Avenue and 100th Street
New York, New York 10029

G-3
■l ' i ■

H0

j I

01 061 0715

Local affiliates of American Cancer Society, American Lung
Association, and National Safety Council
^ _. Manufacturers or fabricators of asbestos products
"iming Enforcement and Safety Administration
U.S. Department of Labor
Washington, D.C.
20210

CIA1!®?,

Scientist's Institute for Public Information

oc*

49 East 53rd Street
New York, New York 10022
SOURCE, Inc.
P.0. Box 21066
Washington, D.C.

20009

State Bureaus of Mines
State Departments of Health
State Workers' Compensation Authorities
Vitalograph Ltd.
8347 Quivira Road
Lenexa, Kansas
66215
Workers' Compensation Insurance underwriters (casualty insurance
companies)
3.

Proceedings of Conferences

Public Information in the Prevention of Occupational Cancer.
Proceedings of a Symposium, December 2-3, 1976.

Washington,

D.C., National Academny of Sciences, 1977.
Proceedings of the Cancer in the Workplace Conference.
^

November 16, 1976.

Piscataway, New Jersey, College of Medicine

^"and Dentistry of New Jersey, 1977.

Appendix H
REFERENCES

Chapter I
Merewether ERA, Price CW:
Effect of Asbestos Dust on Lungs and
Data Suppression in the Asbestos Industry.
London, H.M. Stationery
Office, 1930.
Merewether ERA: Asbestosis and carcinoma of the lung.
In Annual
Report of the Chief Inspector of Factories for the Year 1947.
London, H.M. Stationery Office, 1949, p. 77.
Selikoff IJ:
Cancer risk of asbestos exposure.
In Symposium on
the Origins of Human Cancer.
Cold Spring Harbor, New York, Cold
Spring Harbor Laboratory, September 7-14, 1976.
Newhouse, ML, Berry G:
Predictions of mortality from mesothelial
tumours in asbestos factory workers.
Br J Ind Med 33:147-151, 1976.
Wagoner JK:
Occupational carcinogenesis—The 200 years since
Percivall Pott. Ann NY Acad Sci 271:1-4, 1976.
Minerals and their nonasbestos analogs.
In Electron Microscopy of
Microfibers, Mineral Fibers Session.
University Park, Pennsylvania,
Pennsylvania State University, August 23-25, 1976.
Stanton MF, Wrench C: Mechanisms of mesothelioma induction with
asbestos and fibrous glass.
J. Natl Cancer Inst 48(3):797-821, 1972.
Dreessen WC, et al: A Study of Asbestosis in the Asbestos Textile
Industry.
U.S. Treasury Department, Public Health Service. Public
Health Bulletin No. 241, Aug 1938.
SRI International.
Personal communication, Attorney John Hynan,
Occupational Safety and Health Administration, November 18, 1976.
U.S. Code^ef Federal Regulations, Title 40, Part 61.22.
U.S. Code

Federal Regulations, Title 40, Part 427.

Federal Register 41(15):3286-3287, January 22, 1976.
Federal Register 40(51):11865-11869, March 14, 1975.
Code of Federal Regulations, Title 21, Parts 133.8 and 133.9.

H-l
!

> >J

{ rl i*

l 4)

01 061 0717

(I)

(II)

(III)

15., U.S. Code of Federal Regulations, Title 21, Parts 121.101; and
*■ personal communication, Donald Miller, Food and Drug Administration,
fcWCfCBer 24, 1976.
16.

U.S. Code of Federal Regulations, Title 16, Part 1500.17(7).

17.

Nicholson WJ:
Case study 1:
asbestos —the TLV approach.
NY Acad Sci 271:152-169, 1976.

Ann

SfclVlU*?0
Chapter II

B*

1.

Canadian Mineral Yearbook.
Dept, of Energy, Mines and Resources,
Mineral Resources Branch, 1974.

2.

U.S. Census of Manufactures, U.S. Dept, of Commerce, Bureau of
the Census, 1972.

3.

Mineral Facts and Problems.
Mines, 1975.

4.

Commodity Data Summaries.
Mines, 1976.

5.

Asbestos Information Association of North America:
general information. Washington, D.C., 1975.

OCS

U.S. Dept, of Interior, Bureau of

U.S. Dept of Interior, Bureau of

Asbestos-

Chapter III
1.

Davis JMG, Conlam SW: Experimental studies on the effects of
heated chrysotile asbestos and automobile brake lining dust injected
into the body cavities of mice.
Exp Mol Pathol 19:339-353, 1973.

2.

Fondimare A, et al: Quantitative study of the deposition of asbestos
in the lung and pleura of subjects with diverse exposures.
Proceedings
of the Symposium on the Pathology of Asbestos.
Rouen, France,
Oct 28, 1975.

3.

Timbrell V:
Inhalation and biological effects of asbestos.
In
Assessment of Airborne Particles (Mercer TT, Morrow PE, Strober W,
.t eds.), Proceedings of the Third Rochester International Conference
■F§tt-i3avironmental Toxicity.
Springfield, Illinois, CC Thomas, 1972,
* pp 429-445.

4. "‘"Cross P, DeTreville RTP: The lung as an embattled domain against
inanimate pollutants.
Am Rev Respir Dis 106:684-691, 1972.
5.

Evans JC, et al:
Studies on the deposition of Inhaled fibrous material
in the respiratory tract of the rat and its subsequent clearance using
radioactive trace techniques.
Environ Res 6:180-201, 1973.
H-2

01 061 0718

Wagner JC, et al.: The effects of inhalation of asbestos in
rats.
Br J Cancer 29:252-269, 1974.
Allison^?: Experimental methods—cell and tissue culture:
effects
of asbeftod particles on macrophages, mesothelial cells and fibro­
blasts . ■WPiloiogical Effects of Asbestos CBogoyski, et al., eds.).
Lyon, Fsance,
International Agency for Research on Cancer, Scientific
Pub. No. 8, 1973, pp 89-93.
Godwin ML, Jagatic J:
(5-6)-.391-416, 1970.

Asbestos and mesotheliomas.

Environ

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Institute of Experimental and Clinical Medicine, Tullinn,
Estonian SSR (RA/74/011).
Abstract from International Agency for
Research on Cancer, Lyon, France, 1976.

163.

Davis JM: Histogenesis and fine structure of peritoneal tumors produced
Isi ar3B»la-iy_.injections of asbestos.
J Natl Cancer Inst 52: 1823, 1974.

164.

WagnejtJC, Berry G:
Mesotheliomas in rats following inoculation with
asbesCTJsr Br J Cancer 23: 567-581, 1969.

165.

Harington JS: Occurrence of oils containing 3:4-benzpyrene and
related substances in asbestos. Nature 193 (4810): 43-45, 1962.

Environ

’

•

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
F iO e r o i a a . a t a l . . U soc SO M ie s : C o n fid e n tia l in fo r m a tio n ,
n o t t o & • c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t s o r d e r .

asBestes.

Arch

>

H-13

01 061 0729

Cirri civ)
166.

Harington JS, Roe FJ: Studies of carcinogenesis of asbestos and
their natural oils. Ann NY Acad Sci 132 (Part I): 439-450, 1965.

167.

Rfr-FJC. Walters MA, Harington JS: Tumor initiation by natural
asbestos oils.
Int J Cancer 1: 491-495, 1966

168.

CdtBains BT, Gibbs GW: Contaminating organic material in asbestos.
Br J Cancer 23: 358-362, 1969.

169.

Gross P, Harley RA, Jr: Asbestos-induced intrathoracic tissue reac­
tions. Arch Pathol 96: 245-250, 1973.

170.

Wagner JC: Studies of the carcinogenic effect of fibre glass on
different diameters following intrapleural inoculation in experimental
animals. NIOSH Symposium Occupational Exposure Fibrous Glass, Univ.
of Maryland, MD, June 1974.

171.

Davis JMG, Bolton RE, Garrett J: Penetration of cells by asbestos
fibers. Environ Health Perspec 9: 255-260, 1974.

172.

Shin ML, Firminger HI: Acute and chronic effects of intraperitoneal
injection of two types of asbestos in rats with a study of the histopathogenesls and ultrastructure of resulting mesotheliomas. Am J
Pathol 70(3): 291-313, 1973.

173.

Pott F, Huth F, Friedrichs KH: Tumorigenic effect of fibrous dust
experimental animals. Environ Health Perspect 9: 313-315, 1974.

174.

Roe FJ, et al: The pathological effects of subcutaneous injections of
asbestos fibers in mice: migration of fibres to submesothelial tissues
and induction of mesotheliomata. Int J Cancer 2: 628-638, 1967.

175.

SRI International, Personal communication with. FJC Roe, March 23,
1977

176.

Wagner JC, et al: Animal experiments with talc.
In (Walton WC, ed)
Inhaled Particles and Vapours, IV. New York, Pergamon, 1977.

Chapter IV
1. Daley AR, Zupko AJ, Hebb JL:
Technological feasibility and economic
impact of OSHA proposed revision to the absestos standard. Roy F.
. Wegfcpn^Environmental Consultants-Designers, March 1976 (prepared for:
* AOTrestoS'Thformation Association/North America).
2.

^

41-

ScSutz LA, Bank W, Weems G:
Airborne asbestos fiber concentrations
in'asbestos mines and mills in the United States. U.S. Bureau of
Mines Health and Safety Program Technical Progress Report No. 72,
June 1973.

H-14

01 061 0730

(IV)

3.

Dement JM,, Zunwalde RD, Wallingford KM: Asbestos fiber exposures in
a hard ro<y~gold mine.
Ann NY Acad Sci 271: 345-352, 1976.

4.

Kleinfeld JL, Messite J, Langer AM: A study of workers exposed to
asbestiform minerals in commercial talc manufacture.
Environ Res
6: 132-143, 1973.

5.

Gldley MD, SRI International.

6.

Personal communication, 1977.

Curtis RA, Bierbaum PJ: Technological feasibility of the 2 fibers/cc
asbestos standard in asbestos textile facilities. Am Ind Hyg Assoc J
36(2): 115-125, 1975;

7.

Schneider T: Asbestos dust levels during work with cloths made from
liquid dispersed chrysotile.
Ann Occup Hyg 15: 425-426, 1972.

8.

SRI International Chemical Information data base, 1971.

9.

.

10

Balzer JL, Cooper WC:
The work environment of insulating workers.
Am Ind Hyg Assoc J 29(3): 222-227, 1968.
Harries PG: Asbestos hazards in naval dockyards.
135-145, 1968.

11.

Ann Occup Hyg 11:

Reitze WB et al: Application of sprayed inorganic fiber containing
asbestos: occupational health hazards.
Amer Ind Hyg Assoc J 33(3);
178-191, 1972.

.

12

Lloyd JW:
Communication regarding information indicating a potential
health hazard for persons exposed to asbestos during the servicing of
motor vehicle brake and clutch assemblies.
National Institute for
Occupational Safety and Health, Rockville, Maryland, August 1975.

13.

Rohl AN, et al: Asbestos exposure during brake lining maintenance and
repair.
Environ Res 12: 110-128, 1976.

14.

Castleman BC, et al: The hazards of asbestos for brake mechanics.
Public Health Rep 90(3): 254-256, 1975.

15.

Murphy RL, et al:
Floor tile installation as a source of asbestos
exposure.
Am Rev Respir Dis 104: 576-580, 1971.

16.

Rohl AN, et al: Exposure to asbestos in the use of consumer spackling,
patching, 46vd taping compounds. Science 189(4202): 551-553, 1975.

17.

Gibbs GW*-'~Fibre release from asbestos garments.
143-149, 1975.

18.

Lumley KPS: Asbestos dust levels inside firefighting helmets with
chrysotile asbestos covers.
Ann Occup Hyg 14: 285-286, 1971.

*

H-15

°c

Ann Occup Hyg 18:

01 061 0731

(V)

privileged

Chapter V

OCF
1. Asbestos:
The need for and feasibility of air pollution controls,
fciatl Acad Sci, Washington, D.C., 1971.
2_.

-Laamanen A, Noro L, Raunio V: Observations on atmospheric air pollu­
tion caused by asbestos.
Ann NY Acad Sci 132(1):
240-254, 1965.

3.

Cowherd C:
The Impact of Fugitive Emissions of Fine Particles.
Session III of the Symposium on Fugitive Emissions Measurement and
Control.
Hartford CT, EPA-600/2-76-246, May 1976.

4.

Harris RL, Jr., and Frazer DA: A model for deposition of fibers in the
human respiratory system.
Am Ind Hyg Assoc J 37(2): 73-89, 1976.

5.

United States of America vs. Reserve Mining Company.
Court Proceedings
No. 5-72, Civil 19, United States Court of Appeals, 8th Circuit, June
1974.

6.

Stewart IM: Asbestos in the Water Supplies of Ten Regional Cities.
U.S. Environmental Protection Agency, EPA-560/6-76-017, 1976.

7.

American Water Works Association:
A study of the problem of as
in water.
Am Water Works Assoc J 66(9 pt.2): 1-22, 1974.

8.

Harington JS>_ Allison AC, Badami DV: Mineral fibers:
Chemical
physiochemical, and biological properties.
Adv Pharmacol Chemot'
291-402, 1975.

9.

Clark SG, Holt PF:
Studies on the chemical properties of chrysotile
in relation to asbestosls.
Ann Occup Hyg 3: 22-29, 1961.

10.

Reimschussel G.
In Kramer JR, Mudroch 0, and Tihor S: Asbestos in
the Environment.
McMaster University, prepared for Research Advisory
Board, International Joint Commission and Environment Canada, June 5, 1974.

11.

Aaronson T, Kohl G:

12.

Thompson RJ, Morgan GB:
Determination of Asbestos in Ambient Air.
Presented at Identification and Measurement of Environmental Pollutants
Symposium, Ottawa, Ontario, Canada, June 14-17, 1971.

Papiermache.

Environ 14(10): 25-26, 1972.

13.
Murchio JC, Cooper WC, DeLeon A:
Asbestos Fibers in Ambient Air of
. -'ijgfulifornia. California Air Resources Board, March 1973.
14'

|pirv WM, et al: Development of a rapid survey method of sampling and
aaalysis for asbestos in ambient air.
Columbus, Ohio, Battelle Labora^ Tories. Contract No. CPA 22-69-110, February 29, 1972.

H-16

01 061 0732

CLAIMED

15.

Sellkoff IJ, Nicholson WJ, Langer AM:
Environ H^lth 25: 1-13, 1972.

Asbestos air pollution.

Arch

16.

Asbestos M.'ctte^Great Lakes Basin, International Joint Commission,
Great LakeX Research Advisory Roard, 1975.
*

17.

SRI International. Personal communication, representative of JohnsManville Corp, 1976.

18.

Harwood CF, Siebert P, Blaszak TP: Assessment of particle control
technology for enclosed asbestos sources.
IITRI, EPA-650/2-74-088,
October 1974.

19.

U.S. Environmental Protection Agency:
Background information on
national emission standards for hazardous pollutants - Proposed
amendments to standards for asbestos and mercury.
EPA-450/2-74-009a,
1974.

20.

Wesolowski JJ, et al: Asbestos measured in the California environment.
In Recent Advances in the Assessment of the Health Effects of Environ­
mental Pollution, Vol. 111.
Commission of the European Communities,
1975.

21.

John W, et al:
Experimental Determinations of the Number and Size of
Asbestos Fibers in Ambient Air.
California Dept, of Health, ARB 3-688,
1976.

22.

Federal Register.

23.

Brodeur, P:

24.

Harwood, CF:
Asbestos air pollution from the wear of brake linings.
IITRI, Chicago, April 1972.

25.

Jacko MG, Du Charme RT, Somers JH:
Auto Eng 81(6): 38-40, 1973.

26.

Lynch JR: Brake Lining decomposition products.
Assoc 18(12): 824-826, 1968.

27.

Anderson AE, et al: Asbestos emissions from brake dynamometer tests.
SAE Trans, May 14-18, 1973.

28.

Nichoison^JJ, Rohl AN, Weisman I:

P ro d u c e d u n d e r C o u rc O rd e r in H a rt v ._ O w e n t C o rn in c

■

P ib a r o ia a . a t a l . . USDC SD M ie s : C o n fid e n tia l in fo r m a tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

IVILEGED
3Y OCF

38(66):

8829-8830, April 6, 1973.

The Expendable Americans.

New York, Viking Press, 1973.

How much asbestos do vehicles emit?

J Air Pollut Control

Asbestos Contamination of the Air

of Public ifeildings.
Mt. Sinai School of Medicine.
Protection“Rgency, No. 450/3-76-001, 1973.
29.

New York Times, January 4, 1977, p. 31.

30.

Asbestos fallout.

C*"* • ....
'• • ?<*<.? ;'iK‘

t* '...•.1.*? ' ft1':

■*

Eng News Rec 193(13): 41, 1974.

U.S. Environmental

CLAIMED
PRIVILEGED
BY OCF
31-,

Sawyer RN:
Asbestos exposure in a Yale building.
146-169, 1977.

(V)

Environ Res 13:

32®J WTCKolson WJ, Pundsack FL: Asbestos in the environment.
In:
2- Biological Effects of Asbestos (Bogovski, et al., eds.). Lyon,
France, International Agency for Research, on Cancer, Scientific
Pub. No. 8, 1973, pp. 126-130.
33.

Harwood CF: Asbestos air pollution control.
Environmental Quality, PB-205208, 1971.

Illinois Institute for

34.

Harwood CF, Blaszak TP:
Characterization and control of asbestos
emissions from open sources.
IITRI, EPA-650/2-74-090, September 1974.

35.

Federal Register 39(208) 48292-48311, October 14, 1975.

36.

Newhouse ML, Thompson H:
Epidemiology of Uesothelial tumors in the
London area.
Ann NY Acad Sci 132-579, 1965.

37.

Millette JR: Analyzing for asbestos in drinking water. News of
Environ Res in Cincinnati. U.S. Environmental Protection Agency,
January 16, 1976.

38.

Hallenbeck WH, et al:
Is chrysotile asbestos released from a;
cement pipe into drinking water? J Amer Water Works Assoc, F<
1978, pp 97-102.

39.

Cook PM, Glass GE, Tucker JH:
Asbestiform amphibole minerals:
Detection and measurement of high concentrations in municipal
supplies.
Science 85(154): 853-855, 1974.

40.

Preliminary Assessment of Suspected Carcinogens in Drinking Water
(Appendices).
Interim Report to Congress, U.S. Environmental Pro­
tection Agency (June 1975).

41.

Beaman DR, File DM:
Quantitative determination of asbestos fiber
concentrations.
Anal Chem 48(1): 101-110,’ 1976.

42.

Cook PM,
Semi-Quantitative Determination of Asbestiform Amphibole
Mineral Concentrations in Western Lake Superior Water Samples.
In
Advances in X-Ray Analysis, 18, 1975.

43Jip^Geaper RC, Murchio JC,
Preliminary Studies of Asbestiform Fibers
? in Domestic Water-Supplies.
Berkeley, University of California,
I^AMRL-TR-74-125, Paper No. 5, 1974.
4^r

Nicholson, WJ: Analysis of amphibole asbestiform fibers in municipal
water supplies.
Environmental Health Perspectives 9: 165-172, 1974.

H-18

01 061 0734

t h is C o u r t's o r d e r .
a c c o rd a n c e w it h

P ro d u c e d u n d e r C o u rt O ra e r

in f t y r t v , Owens c o rn in g
F ib e ro l.e a . a t a \ . . US0C SD H ie s ; C o n f id e n t ia l in fo r m a tio n ,
n o t t o t>e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in

CLAIMED
PRIVILEGED

(v>

45.

SRI International.
Personal communication, P TolSC&jQS&ironmental
Protection Agency re Phase 2 data developed under contract with
McCrone ^sociates, 1976.

46.

FDA detains lima beans contaminated with asbestos after accident.
Food Chemical News, September 24, 1973.

47.

Code of Federal Regulations, Title 21, Section 121, Parts 2520,
2562, 2576, 2587, 1975.

48.

Wolff AH, Oehme FW;
Carcinogenic chemicals in food as an environ­
mental health issue.
J Am Vet Med Assoc 164(6); 623-629, 1974.

49.

National Institute for Occupational Safety and Health (NIOSH), Report
of Review Committee, NIOSH Pub No HSM-72-10267, 1972.

50.

Cunningham HM, Pontefract RD:
Symposium on industrial chemicals as
food contaminants.
J Assoc Off Anal Chem 56(4): 976-981, 1973.

51.

Wehman HJ, Plantholf BA: Asbestos fibrils in beverages.
Bull Environ Contam Toxicol 11(3): 267-272, 1974.

52.

Federal Register 40(51): 11866-11869, March 14, 1975.

53.

Bernstein IL, Mbteff J: Possible asbestos hazards in clinical allergy.
J Allergy Clin Immunol 57(5): 489-492, May 1976.

54.

Council on Dental Therapeutics, Council on Dental Materials and Devices:
Hazards of asbestos in dentistry.
J Am Dent Assoc 92: 777-778,
April 1976.

55.

SRI International.

56.

Schultz RZ, Williams CR:
Commercial talc—Animal and mineralogical
studies.
J Ind Hyg 24: 75-79, 1942.

57.

Kleinfeld M, Messite J, Langer AM: A study of workers exposed to
asbestiform minerals in commercial talc manufacture.
Environ Res 6:
132-143, 1973.

58.

Cralley LJ, et al:
Fibrous and mineral content of cosmetic talcum
products.
Am Ind Hyg Assoc J 29: 350-354, 1968.

59.

Rohl‘AN,^fet al:

PTI Gin.

Personal communication with an industry source, 1976.

Consumer talcums and powders:

mineral and chemical

characterization.. J Tox Environ Health 2: 255-284, 1976.
60.

Brobst-fiA, Pratt WP:
United States Mineral Resources.
Survey Professional Paper 820, 1973.

U.S. Geological

CLAIMED
PRIVILEGED
BY OCF
61.

(V)

(VI)

SRI International. Personal communication, R. Mickus, Rice Growers
Association, October 1976.

62.
_

temational. Personal communication, D. Miller, Food & Drug
administration, October 1976.

63.

Blejer HP, Arlon R:
Talc:
A possible occupational and environmental
carcinogen.
J Occup Med 15(2): 92-97, 1973.

64.

Eisenberg WV:
Inorganic particle content of food and drugs.
Health Perspect 9: 183-191, 1974.

65.

SRI International.
Co, October 1976.

66.

Federal Register 40(51): 11866-11869, March 14, 1975.

67.

Nicholson WJ, et al:
Occupational and community asbestos exposure
from wallboard finishing compounds.
Bull NY Acad Med 51(10): 11801181, 1975.

Environ

Personal communication, Pitco, Ford Gum and Machine

Chapter VI
1.

.. ACGIH:
Industrial Ventilation—A Manual of Recommended Practi
published yearly.

2.

U.S. Environmental Protection Agency: Asbestos:
A review of selected
literature through 1973 relating to environmental exposure and health
effects.
29, 1976.

3.

Smith, Winslow:
Composition for inhibiting asbestos fiber dust, US
Pat Off No. 3928000.

4.

Stanton MF:
Fiber darcinogenesis:
Is asbestos the only hazard?
J Natl Cancer Inst 52: 633-634, 1974.

5.

US Bureau of Mines: Asbestos—a materials survey.
Circular 7880, Washington, D.C.,

Information

6.
Engineering Equipment Users Association Handbook if33:
Recommendations
--in for Handling Asbestos, London, 1969.
V* --=*~
7. ’ Bruckman L, Rubino RA: Asbestos:
rationale behind a proposed air
~
Equality standard.
J. Air Pollut Control Assoc 25(12): 1207-1215, 1975.
8T*-

Federal Register 40(197), October 9, 1975, p 47662.

9. U.S. Environmental Protection Agency:
Control Techniques for Asbestos
Air Pollutants.
USEPA Publ //AP-117, Research Triangle Park, NC, 27711,
Feb. 1973.

H-20

01 061 0736

CLAIMED

(VI) (VII)

privileged

BY OCF
10.

Harwood CE, Siebert P, Blaszak TP: Assessment of Particle Control
TechnologjFfor Enclosed Asbestos Sources.
EPA Publ //EPA 650/2-74-

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v , o « a n « c o rn in g
F ib e r c la a . a t a l . . USDC SD M is s : C o n fid e n tia l in fo n s e tio n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

088, USEPMfcflRhSETarch Triangle Park, NC.
availablelas NTIS Publ 0PH239926).

October 1974.

(Also

11.

Harwood CF, et al:
Asbestos emissions from baghouse controlled
sources.
J Am Ind Hyg Assoc 36(8): 595-603, Aug. 1975.

12.

Seibert PC, Ripley TC, Harwood CF:
Assessment of Particle Control
Technology for Enclosed Asbestos Sources-Phase II.
EPA Publ #EPA 600/
2-76-065, USRPA, Research Triangle Park, NC, 27711, March 1976.

13.

Krenkel PA: Waste treatment methodology.
(Sax, ed.), 1974.

14.

Levy BS, et al:
Investigating possible effects of asbestos in city
water:
surveillance of gastrointestinal cancer incidence in Duluth,
Minnesota. Am J Epidemiol 103: 362-368, 1976.

15.

Lawrence J, et al:
Asbestos:
Res Dev Nov/Dec: 29-30, 1973.

16.

Lawrence J, et al:
Removal of asbestos fibers from potable water by
coagulation and filtration. Water Research 9: 397-400, 1975.

17.

Baumann RE:
Diatomite Filters for Asbestiform Fiber Removal from Water.
Proc of Am Water Works Assoc, 95th Annual conf, Minneapolis, 1975.

18.

Federal Register 40(6): 1873-1878, 1975.

19.

U.S. Environmental Protection Agency: National emissions standards for
hazardous air pollutants:
Amendments to standards for asbestos and
mercury.
Federal Register 40(199): 48292-48302, Oct. 14, 1975.

20.

Harwood CF, Ase P, and Stinson M:
Study of the Effect of Asbestos
Waste Piles on Ambient Air.
In Proc of Symp on Fugitive Emission
Measurement and Control. Washington D.C., Environmental Protection
Agency, EPA Publ //EPA-600/2-76-246, p. 183-202, Sept. 1976.

In Industrial Pollution

its removal from potable water.

Can

Chapter VII
1.

TokulrataijBS ^G*aeei of the lung: host and environmental interaction
In Cancer^Genetics (Lynch HT, Thomas CC, ed.), Springfield, Illinois,
1976r

2.

Cole P.—■Goldman MB:
Occupation.
In Persons at High Risk of Cancer
(Fraumeni Jr., F, ed.) New York, Academic Press, 1975, pp. 167-183.

H-21
» •

» .

<

01 061 0737

CLAIMED
PRIVILEGED
BY OCF

CVI1)

3.

Montgomery RD, Stirling GA, Hamer NA:
Bronchiolar carcinoma
fet progressive systemic sclerosis.
Lancet 1: 486-487, 1964.

4.

Godeau P, et al:
Carcinome bronchioloalveolaire et sclerodermie.
Sem Hop Paris 50: 116i-1168, 1974.

5.

Koch BL: Familial fibrocystic pulmonary dysplasia:
in one family.
Can Med Assoc J 92: 801-808, 1965.

.

observations

6

Swaye P, et al:
Familial Hamman-Rich Syndrome:
cases.
Diseases Chest 55: 7-12, 1969.

7.

McKusick VA, Fisher AM:
Congenital cystic disease of the lung with
progressive pulmonary fibrosis and carcinomatosis.
Ann Int Med 48:
774-790, 1958.

.

report of eight

8

Boucot KR, et al:
Cigarettes, cough, and cancer of the lung.
196: 985-990, 1966.

9.

Campbell AH, Lee EJ:
The relationship between lung cancer and
chronic bronchitis. Br J Dis Chest 57: 113-119, 1963.

.

JAMA

10

Dean G:
Lung cancer and bronchitis in Northern Ireland, 1960-2.
Br, Med J 1: 1506-1514, 1966.

11.

Van der Wal AM, et al:
Cancer and chronic non-specific lung disease.
Scand J Resp Dis 47: 161-172, 1966.

.

12

Wynder EL, Fairchild, Jr. EP: The role of a history of persistent
cough in the epidemiology of lung cancer.
Am Rev Resp Dis 94: 709-720,
1966.

13.

Tokuhata GK, Lilienfeld AM:
Familial aggregation of lung cancer in
humans.
J Natl Cancer Inst 30(2): 289-312, 1963.

14.

Cohen BH, et al: A common familial component in lung cancer and
chronic obstructive pulmonary disease.
Lancet ii: 523-526, 1977.

15.

Wagner JC, et al:
The effects of inhalation of asbestos in rats.
Br J Cancer 29: 252-269, 1974.

16.

-ffrellermann G, Luyten-KeHerman M, Shaw CR:
Genetic variation of aryl
JwfrrohSrbon hydroxylase in human lymphocytes.
Am J Hum Genet 25:
^2-331, 1973.

17.

ReHerman G, Shaw CR, Luyten-Kellermann M:
Aryl hydrocarbon hydroxylase
"'“inducibility and bronchogenic carcinoma.
N Engl J Med 289(18):
934-937, 1973.
H-22

01 061 0738

CLAIMED
PRIVILEGED
BY OCF

Shaw CR:
The microsomal mixed function oxidases and chemical
carcinogens. Jn Isozymes III Developmental Biology.
San Francisco,
Academic Press, If&t-.-, 1975.

19.

Paigen B, et al: Questionable relation of aryl hydrocarbon hydroxylase
to lung cancer risk.
N Eng J M&c 297(7): 346-350, 1977.

20.

Saccomanno G, et al:
in exfoliated cells.

21.

Lilienfeld A (Chairman), et al:
An evaluation of radiological and
cytological screening for early oetection of lung cancer.
A co­
operative pilot study of the American Cancer Society and the
Veterans Administration. Cancer Ses 26: 2083-2147, 1966.

•

P ro d u c e d u n d e r C o u rt O rd e r in H a rt v . Owens C o rn in g
E ib e r o la a . « t » ! . . USDC SD M is s : C o n fid e n tia l in f o r v e t io n ,
n o t t o b e c o p ie d , re p ro d u c e d o r d is t r ib u t e d e x c e p t in
a c c o rd a n c e w it h t h is C o u r t 's o r d e r .

18.

(VII)

.

Development of carcinoma of the lung as reflected
Cancer 33(1'): 256-270, 1974.

22

SRI International.

23.

Hammond EC:
Tobacco.
In Persons at Higji Risk of Cancer.
Jr., JF, ed.) New York, Academic Press, 1975.

24.

Rothman KJ: Alcohol.
In Persons at High Risk of Cancer. (Fraumeni,
Jr., JF, ed.) New York, Academic Press, 1975.

25.

Lynch HT:
Genetics.

26.

SRI International.

27.

Weiss W:
Cigarette smoking, asbestos, and pulmonary fibrosis.
Rev Respir Dis 104: 223-227, 1971.

28.

Tumer-Warwick M:
Immunology and asbestosis.
In Biological Effects
of Asbestos (Bogovski P, et al. , eds.).
Lyon, France, International
Agency for Research on Cancer, Scientific Pub. No. 8, 1973, pp. 258-263.

29.

Kang K-Y, et al:
735-736, 1974.

30.

Merchant JA, et al:
1: 189-191, 1975.

31

Becklake MR:
Asbestos-related diseases of the lung and other organs,
their epidemiolc®~^cLJ.mplications for clinical practice.
Am Rev
Respir Dis 114: ^7-227, 1976.

32.

Personal communication with G Saccomanno, November 1976.

Miscellaneous problems, cancer, and genetics.
Springfield, Illinois, CC Thomas, 1976.

(Fraumeni

In Cancer

Personal communication, EA Gaensler, October 1976.

T-lymphocytes in asbestosis.

Am

N Engl J Med: 291:

The HL-A system in asbestos workers.

Br Med J

4^
Brett GZ:
The va4«e of lung cancer detection by six-monthly chest
radiographs.
J&drax 23: 414-420, 1968.

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33.

BodWF"fc5^ Weiss W:
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34.

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of chest X-rays in the detection of lung cancer.
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Archer PG, et al: A study of variability in the interpretation of
sputum cytology slides.
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research project:
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The detection and treatment of early lung cancer.
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40.

Grzybowski S, Coy P:
Early diagnosis of carcinoma of the lung: simultaneous
screening with chest. X-ray and sputum cytology.
Cancer 23: 113-120, 1970.

41.

Whitwell F, Newhouse ML, Bennett DR:
A study of the histological
types of lung cancer in workers suffering from asbestosis in the
United Kingdom.
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42.

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ILO-U/C classification of radiographs
of pneymoconioses.
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Elmes PC:
The natural history of diffuse mesothelioma.
In Biological
Effects of Asbestos (Bogovski P, et al., eds.).
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Agency for Research on Cancer, Scientific Pub. No. 8, 1973, pp. 267-272.

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The clinical aspects of mesothelioma.
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45.

~WinJSer SJ, et al:

Feasibility of fecal occult-blood testing for

detection of colorectal neoplasia:
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46.

Quart J

debits and credits.

Cancer 40 (Sup 5):

Stephens FO, Lawrenson KB: The pathologic significance of occult blood
in feces.
Dis Colon Rectum 13(6): 425-428, 1970.

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(yii) cmi)
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BY OCF

47.

Greegor DH:-. Occult blood testing for detection of asymptomatic
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Gastric cancer.

Arch Intern

Chapter VIII
1.

Code of Federal Regulations.
Section 1910.1003-1910.1029.

Title 29, Chap. XVII, Subpart Z,

2.

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Cancer, Division of Medical Sciences, Assembly of Life Sciences, National
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medical department.
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5.

Felton JS:
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an atomic energy research laboratory—a four-year review.
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and Surg 21: 107-110, March 1952.

6.

Expert Committee on Health Education of the Public—First Report,
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Moser RH: Psychosemantics (On Speaking to Patients).
In Diseases of
Medical Progress: A Study of Iatrogenic Disease, Ed. 3.
(Moser RH,
ed.).
Springfield, Illinois, CC Thomas, 1969, p. 812.

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BY OCF

(VIII)

9.

Council on Occupational Health, American Medical Association:
The
fetole of Medicine Within a Business Organization.
JAMA 210: (Nov 24)
-1 nc-n

10.

/Joint Statement of the Role of the Registered Nurse in Employee
Health Programs—California Medical Association, California Nurses'
Association, California Hospital Association, in Joint Statements (of
the Associations).
Sacramento California Nurses' Association, 1972,
p 27.

11.

Samuels S:
In Public Information in the Prevention of Occupational
Cancer.
Proceedings of a Symposium held in Washington, D.C.
December 2-3, 1976. Washington, D.C., National Research Council,
National Academy of Sciences, 1977, p. 147.

12.

Mancuso, TF: Help for the Working Wounded. Washington, D.C.,
National Association of Machinists and Aerospace Workers, 1976.

J^U.S.

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