Vol. 1 - Pages 9.1-9.30 (Printed Version)
Reproductive System
MATERNAL OCCUPATIONAL
EXPOSURES AND ADVERSE PREGNANCY
OUTCOMES
Grace Kawas Lemasters
Paid employment among women is growing worldwide. For
example, almost 70% of women in the United States are employed outside the home
during their predominant childbearing years (ages 20 to 34). Furthermore, since
the 1940s there has been an almost linear trend in synthetic organic chemical
production, creating a more hazardous environment for the pregnant worker and
her offspring.
Ultimately, a couple’s reproductive success depends on
a delicate physiochemical balance within and between the father, the mother and
the foetus. Metabolic changes occurring during a pregnancy can increase
exposure to hazardous toxicants for both worker and conceptus. These metabolic
changes include increased pulmonary absorption, increased cardiac output,
delayed gastric emptying, increased intestinal motility and increased body fat.
As shown in Figure 9.5 [REP05FE], exposure of the conceptus can produce varying
effects depending on the phase of development—early or late embryogenesis or
the foetal period.
Transport time of a fertilized ovum before
implantation is between two and six days. During this early stage the embryo
may be exposed to chemical compounds that penetrate into the uterine fluids.
Absorption of xenobiotic compounds may be accompanied by degenerative changes,
alteration in the blastocystic protein profile or failure to implant. Insult
during this period is likely to lead to a spontaneous abortion. Based on
experimental data, it is thought that the embryo is fairly resistant to
teratogenic insult at this early stage because the cells have not initiated the
complex sequence of chemical differentiation.
The period of later embryogenesis is characterized by
differentiation, mobilization and organization of cells and tissue into organ
rudiments. Early pathogenesis may induce cell death, failed cellular
interaction, reduced biosynthesis, impaired morphogenic movement, mechanical
disruption, adhesions or oedema (Paul 1993). The mediating factors that
determine susceptibility include route and level of exposure, pattern of
exposure and foetal and maternal genotype. Extrinsic factors such as
nutritional deficiencies, or the additive, synergistic or antagonistic effects
associated with multiple exposures may further impact the response. Untoward
responses during late embryogenesis may culminate in spontaneous abortion,
gross structural defects, foetal loss, growth retardation or developmental
abnormalities.
The foetal period extends from embryogenesis to birth
and is defined as beginning at 54 to 60 gestational days, with the conceptus
having a crown-rump length of 33 mm. The distinction between the embryonic and
foetal period is somewhat arbitrary. The foetal period is characterized
developmentally by growth, histogenesis and functional maturation. Toxicity may
be manifested by a reduction in cell size and number. The brain is still
sensitive to injury; myelination is incomplete until after birth. Growth
retardation, functional defects, disruption in the pregnancy, behavioural
effects, transplacental carcinogenesis or death may result from toxicity during
the foetal period. This article discusses the biological, sociological and epidemiological
effects of maternal environmental/occupational exposures.
Embryonic/Foetal Loss
The developmental stages of the zygote, defined in
days from ovulation (DOV), proceed from the blastocyst stage at days 15 to 20
(one to six DOV), with implantation occurring on day 20 or 21 (six or seven
DOV), to the embryonic period from days 21 to 62 (seven to 48 DOV), and the
foetal period from day 63 (49+ DOV) until
the designated period of viability, ranging from 140 to 195 days. Estimates of
the probability of pregnancy termination at one of these stages depend on both
the definition of foetal loss and the method used to measure the event.
Considerable variability in the definition of early versus late foetal loss
exists, ranging from the end of week 20 to week 28. The definitions of foetal
and infant death recommended by the World Health Organization (1977) are listed
in Table 9.4 [REP04TE]. In the United States the gestational age setting the
lower limit for stillbirths is now widely accepted to be 20 weeks.
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Because the majority of early aborted foetuses have
chromosomal anomalies, it has been suggested that for research purposes a finer
distinction should be made—between early foetal loss, before 12 weeks’
gestation, and later foetal loss (Källén 1988). In examining late foetal losses
it also may be appropriate to include early neonatal deaths, as the cause may
be similar. WHO defines early neonatal death as the death of an infant aged
seven days or younger and late neonatal death as occurring between seven and 29
days. In studies conducted in developing countries, it is important to
distinguish between prepartum and intrapartum deaths. Because of problematic
deliveries, intrapartum deaths account for a large portion of stillbirths in
less developed countries.
In a review by Kline, Stein and Susser (1989) of nine
retrospective or cross-sectional studies, the foetal loss rates before 20
weeks’ gestation ranged from 5.5 to 12.6%. When the definition was expanded to
include losses up to 28 weeks’ gestation, the foetal loss rate varied between
6.2 and 19.6%. The rates of foetal loss among clinically recognized pregnancies
in four prospective studies, however, had a relatively narrow range of 11.7 to
14.6% for the gestational period up to 28 weeks. This lower rate, seen in
prospective versus retrospective or cross-sectional designs, may be
attributable to differences in underlying definitions, misreporting of induced
abortions as spontaneous or misclassification of delayed or heavy menses as
foetal loss.
When occult abortions or early “chemical” losses
identified by an elevated level of human chorionic gonadotrophins (hCG) are
included, the total spontaneous abortion rate jumps dramatically. In a study
using hCG methods, the incidence of post-implantation subclinical loss of
fertilized ova was 22% (Wilcox et al. 1988). In these studies urinary hCG was
measured with immunoradiometric assay using a detection antibody. The assay
originally used by Wilcox employed a now extinct high affinity, polyclonal
rabbit antibody. More recent studies have used an inexhaustible monoclonal
antibody that requires less than 5 ml of urine for replicate samples. The
limiting factor for use of these assays in occupational field studies is not
only the cost and resources needed to coordinate collection, storage and
analysis of urine samples but the large population needed. In a study of early
pregnancy loss in women workers exposed to video display terminals (VDTs),
approximately 7,000 women were screened in order to acquire a usable population
of 700 women. This need for ten times the population size in order to achieve
an adequate sample stems from reduction in the available number of women
because of ineligibility due to age, sterility and the enrollment exclusively
of women who are using either no contraceptives or relatively ineffective forms
of contraception.
More conventional occupational studies have used
recorded or questionnaire data to identify spontaneous abortions. Recorded data
sources include vital statistics and hospital, private practitioner and
outpatient clinic records. Use of record systems identifies only a subset of
all foetal losses, principally those that occur after the start of prenatal
care, typically after two to three missed periods. Questionnaire data are
collected by mail or in personal or telephone interviews. By interviewing women
to obtain reproductive histories, more complete documentation of all recognized
losses is possible. Questions that are usually included in reproductive
histories include all pregnancy outcomes; prenatal care; family history of
adverse pregnancy outcomes; marital history; nutritional status; pre-pregnancy
weight; height; weight gain; use of cigarettes, alcohol and prescription and
nonprescription drugs; health status of the mother during and prior to a
pregnancy; and exposures at home and in the workplace to physical and chemical
agents such as vibration, radiation, metals, solvents and pesticides. Interview
data on spontaneous abortions can be a valid source of information, particularly
if the analysis includes those of eight weeks’ gestation or later and those
that occurred within the last 10 years.
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The principal physical, genetic, social and
environmental factors associated with spontaneous abortion are summarized in
<Table 9.5 [REP05TE]. To ensure that the observed exposure-effect relationship
is not due to a confounding relationship with another risk factor, it is
important to identify the risk factors that may be associated with the outcome
of interest. Conditions associated with foetal loss include syphilis, rubella,
genital Mycoplasma infections, herpes simplex, uterine infections and general
hyperpyrexia. One of the most important risk factors for clinically recognized
spontaneous abortion is a history of pregnancy ending in foetal loss. Higher
gravidity is associated with increased risk, but this may not be independent of
a history of spontaneous abortion. There are conflicting interpretations of
gravidity as a risk factor because of its association with maternal age, reproductive
history and heterogeneity of women at different gravidity ranks. Rates of
spontaneous abortion are higher for women younger than 16 and older than 36
years. After adjusting for gravidity and a history of pregnancy loss, women
older than 40 were shown to have twice the risk of foetal loss of younger
women. The increased risk for older women has been associated with an increase
in chromosomal anomalies, particularly trisomy. Possible male-mediated effects
associated with foetal loss have been recently reviewed (Savitz, Sonnerfeld and
Olshaw 1994). A stronger relationship was shown with paternal exposure to
mercury and anaesthetic gases, as well as a suggestive but inconsistent
relationship with exposure to lead, rubber manufacturing, selected solvents and
some pesticides.
Employment status may be a risk factor regardless of a
specific physical or chemical hazard and may act as a confounder in assessment
of occupational exposure and spontaneous abortion. Some investigators suggest
that women who stay in the workforce are more likely to have an adverse
pregnancy history and as a result are able to continue working; others believe
this group is an inherently more fit subpopulation due to higher incomes and
better prenatal care.
Congenital Anomalies
During the first 60 days after conception, the
developing infant may be more sensitive to xenobiotic toxicants than at any
other stage in the life cycle. Historically, terata and congenital
malformations referred to structural defects present at birth that may be gross
or microscopic, internal or external, hereditary or nonhereditary, single or
multiple. Congenital anomaly, however, is more broadly defined as including
abnormal behaviour, function and biochemistry. Malformations may be single or
multiple; chromosomal defects generally produce multiple defects, whereas
single-gene changes or exposure to environmental agents may cause either single
defects or a syndrome.
The incidence of malformations depends on the status
of the conceptus—live birth, spontaneous abortus, stillbirth. Overall, the
abnormality rate in spontaneous abortuses is approximately 19%, a tenfold
increase in what is seen in the live born (Shepard, Fantel and Fitsimmons
1989). A 32% rate of anomalies was found among stillborn foetuses weighing more
than 500 g. The incidence of major defects in live births is about 2.24%
(Nelson and Holmes 1989). The prevalence of minor defects ranges between 3 and
15% (averaging about 10%). Birth anomalies are associated with genetic factors
(10.1%), multifactorial inheritance (23%), uterine factors (2.5%), twinning
(0.4%) or teratogens (3.2%). The causes of the remaining defects are unknown.
Malformation rates are approximately 41% higher for boys than for girls and
this is explained by the significantly higher rate of anomalies for male
genital organs.
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One challenge in studying malformations is deciding
how to group defects for analysis. Anomalies can be classified by several
parameters, including seriousness (major, minor), pathogenesis (deformation,
disruption), associated versus isolated, anatomic by organ system, and
aetiological (e.g., chromosomal, single gene defects or teratogen induced).
Often, all malformations are combined or the combination is based either on
major or minor categorization. A major malformation can be defined as one that
results in death, requires surgery or medical treatment or constitutes a
substantial physical or psychological handicap. The rationale for combining
anomalies into large groups is that the majority arise, at approximately the
same time period, during organogenesis. Thus, by maintaining larger sample
sizes, the total number of cases is increased with a concomitant increase in
the statistical power. If, however, the exposure effect is specific to a
particular type of malformation (e.g., central nervous system), such grouping
may mask the effect. Alternatively, malformations may be grouped by organ
system. Though this method may be an improvement, certain defects may dominate
the class, such as varus deformities of the feet in the musculoskeletal system.
Given a sufficiently large sample, the optimal approach is to divide the
defects into embryologically or pathogenetically homogenous groups (Källén
1988). Considerations should be given to the exclusion or inclusion of certain
malformations, such as those that are likely caused by chromosomal defects,
autosomal dominant conditions or malposition in utero. Ultimately, in analysing
congenital anomalies, a balance has to be maintained between maintaining
precision and compromising statistical power.
A number of environmental and occupational toxicants
have been associated with congenital anomalies in offspring. One of the
strongest associations is maternal consumption of food contaminated with
methylmercury causing morphological, central nervous system and
neurobehavioural abnormalities. In Japan, the cluster of cases was linked to
consumption of fish and shellfish contaminated with mercury derived from the
effluent of a chemical factory. The most severely affected offspring developed
cerebral palsy. Maternal ingestion of polychlorinated biphenyls (PCBs) from
contaminated rice oil gave rise to babies with several disorders, including
growth retardation, dark brown skin pigmentation, early eruption of teeth,
gingival hyperplasia, wide sagittal suture, facial oedema and exophthalmos.
Occupations involving exposures to mixtures have been linked with a variety of
adverse outcomes. The offspring of women working in the pulp and paper
industry, in either laboratory work or jobs involving “conversions” or paper
refinement, also had increased risk of central nervous system, heart and oral
cleft defects. Women working in industrial or construction work with
unspecified exposures had a 50% increase in central nervous system defects, and
women working in transportation and communication had two times the risk of
having a child with an oral cleft. Veterinarians represent a unique group of
health care personnel exposed to anaesthetic gases, radiation, trauma from
animal kicks, insecticides and zoonotic diseases. Though no difference was
found in the rate of spontaneous abortions or in birth weight of the offspring
between female veterinarians and female lawyers, there was a significant excess
of birth defects among veterinarians (Schenker et al. 1990). Lists of known,
possible and unlikely teratogens are available as well as computer databases
and risk lines for obtaining current information on potential teratogens (Paul
1993). Evaluating congenital anomalies in an occupational cohort is particularly
difficult, however, because of the large sample size needed for statistical
power and our limited ability to identify specific exposures occurring during a
narrow window of time, primarily the first 55 days of gestation.
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Small for Gestational Age
Among the many factors linked with infant survival,
physical underdevelopment associated with low birth weight (LBW) presents one
of the greatest risks. Significant weight gain of the foetus does not begin
until the second trimester. The conceptus weighs 1 g at eight weeks, 14 g at 12
weeks, and reaches 1.1 kg at 28 weeks. An additional 1.1 kg is gained every six
weeks thereafter until term. The normal newborn weighs approximately 3,200 g at
term. The newborn’s weight is dependent on its rate of growth and its
gestational age at delivery. An infant that is growth retarded is said to be
small for gestational age (SGA). If an infant is delivered prior to term it
will have a reduced weight but will not necessarily be growth retarded. Factors
associated with a preterm delivery are discussed elsewhere, and the focus of
this discussion is on the growth-retarded newborn. The terms SGA and LBW will
be used interchangeably. A low birth-weight infant is defined as an infant
weighing less than 2,500 g, a very low birth weight is defined as less than
1,500 g, and extremely low birth weight is one that is less than 1,000 g (WHO
1969).
When examining causes of reduced growth, it is
important to distinguish between asymmetrical and symmetrical growth
retardation. Asymmetrical growth retardation, i.e., where the weight is
affected more than the skeletal structure, is primarily associated with a risk
factor operating during late pregnancy. On the other hand, symmetrical growth
retardation may more likely be associated with an aetiology that operates over
the entire period of gestation (Kline, Stein and Susser 1989). The difference
in rates between asymmetrical and symmetrical growth retardation is especially
apparent when comparing developing and developed countries. The rate of growth
retardation in developing countries is 10 to 43%, and is primarily symmetrical,
with the most important risk factor being poor nourishment. In developed
countries foetal growth retardation is usually much lower, 3 to 8%, and is
generally asymmetrical with a multifactorial aetiology. Hence, worldwide, the
proportion of low birth-weight infants defined as intrauterine growth retarded
rather than preterm varies dramatically. In Sweden and the United States, the
proportion is approximately 45%, while in developing countries, such as India,
the proportion varies between approximately 79 and 96% (Villar and Belizan
1982).
Studies of the Dutch famine showed that starvation
confined to the third trimester depressed foetal growth in an asymmetric
pattern, with birth weight being primarily affected and head circumference
least affected (Stein, Susser and Saenger 1975). Asymmetry of growth also has
been observed in studies of environmental exposures. In a study of 202
expectant mothers residing in neighbourhoods at high risk for lead exposures,
prenatal maternal blood samples were collected between the sixth and the 28th
week of gestation (Bornschein, Grote and Mitchell 1989). Blood lead levels were
associated with both a decreased birth weight and length, but not head
circumference, after adjustment for other relevant risk factors including
length of gestation, socioeconomic status and use of alcohol or cigarettes. The
finding of maternal blood lead as a factor in birth length was seen entirely in
Caucasian infants. The birth length of Caucasian infants decreased
approximately 2.5 cm per log unit increment in maternal blood lead. Care should
be given to selection of the outcome variable. If only birth weight had been
selected for study, the finding of the effects of lead on other growth
parameters might have been missed. Also, if Caucasians and African Americans
had been pooled in the above analysis, the differential effects on Caucasians,
perhaps due to genetic differences in the storage and binding capacity of lead,
may have been missed. A significant confounding effect also was observed
between prenatal blood lead and maternal age and the birth weight of the
offspring after adjustment for other covariables. The findings indicate that
for a 30-year-old woman with an estimated blood lead level of about 20 mg/dl, the offspring weighed approximately 2,500 g
compared with approximately 3,000 g for a 20-year-old with similar lead levels.
The investigators speculated that this observed difference may indicate that
older women are more sensitive to the additional insult of lead exposure or
that older women may have had higher total lead burden from greater numbers of
years of exposure or higher ambient lead levels when they were children.
Another factor may be increased blood pressure. Nonetheless, the important
lesson is that careful examination of high-risk subpopulations by age, race,
economic status, daily living habits, sex of the offspring and other genetic
differences may be necessary in order to discover the more subtle effects of
exposures on foetal growth and development.
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Risk factors associated with low birth weight are
summarized in Table 9.5 [REP05TE]. Social class as measured by income or
education persists as a risk factor in situations in which there are no ethnic
differences. Other factors that may be operating under social class or race may
include cigarette smoking, physical work, prenatal care and nutrition. Women
between the ages of 25 and 29 are least likely to deliver a growth-retarded
offspring. Maternal smoking increases the risk of low birth-weight offspring by
about 200% for heavy smokers. Maternal medical conditions associated with LBW
include placental abnormalities, heart disease, viral pneumonia, liver disease,
pre-eclampsia, eclampsia, chronic hypertension, weight gain and hyperemesis. An
adverse pregnancy history of foetal loss, preterm delivery or prior LBW infant
increases the risk of a current preterm low birth-weight infant two- to
fourfold. An interval between births of less than a year triples the risk of
having a low birth-weight offspring. Chromosomal anomalies associated with
abnormal growth include Down’s syndrome, trisomy 18 and most malformation
syndromes.
Smoking cigarettes is one of the primary behaviours
most directly linked with lower weight offspring. Maternal smoking during
pregnancy has been shown to increase the risk of a low birth-weight offspring
two to three times and to cause an overall weight deficit of between 150 and
400 g. Nicotine and carbon monoxide are considered the most likely causative
agents since both are rapidly and preferentially transferred across the
placenta. Nicotine is a powerful vasoconstrictor, and significant differences
in the size of umbilical vessels of smoking mothers have been demonstrated.
Carbon monoxide levels in cigarette smoke range from 20,000 to 60,000 ppm.
Carbon monoxide has an affinity for haemoglobin 210 times that of oxygen, and
because of lower arterial oxygen tension the foetus is especially compromised.
Others have suggested that these effects are not due to smoking but are
attributable to characteristics of smokers. Certainly occupations with
potential carbon monoxide exposure, such as those associated with pulp and
paper, blast furnaces, acetylene, breweries, carbon black, coke ovens, garages,
organic chemical synthesizers and petroleum refineries should be considered
possible high risk occupations for pregnant employees.
Ethanol is also a widely used and researched agent
associated with foetal growth retardation (as well as congenital anomalies). In
a prospective study of 9,236 births, it was found that maternal alcohol
consumption of more than 1.6 oz per day was associated with an increase in
stillbirths and growth-retarded infants (Kaminski, Rumeau and Schwartz 1978).
Smaller infant length and head circumference also are related to maternal
alcohol ingestion.
In evaluating the possible effects of exposures on
birth weight, some problematic issues must be considered. Preterm delivery
should be considered as a possible mediating outcome and the potential effects
on gestational age considered. In addition, pregnancies having longer
gestational length also have a longer opportunity for exposure. If enough women
work late in pregnancy, the longest cumulative exposure may be associated with
the oldest gestational ages and heaviest babies purely as an artifact. There
are a number of procedures that can be used to overcome this problem including
a variant of the Cox life-table regression model, which has the ability to
handle time-dependent covariables.
Another problem centres on how to define lowered birth
weight. Often studies define lower birth weight as a dichotomous variable, less
than 2,500 g. The exposure, however, must have a very powerful effect in order
to produce a drastic drop in the infant’s weight. Birth weight defined as a
continuous variable and analysed in a multiple regression model is more
sensitive for detecting subtle effects. The relative paucity of significant
findings in the literature in relationship to occupational exposures and SGA
infants may, in part, be caused by ignoring these design and analysis issues.
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Conclusions
Studies of adverse pregnancy outcomes must
characterize exposures during a fairly narrow window of time. If the woman has
been transferred to another job or laid off work during a critical period of
time such as organogenesis, the exposure-effect relationship can be severely
altered. Therefore, the investigator is held to a high standard of identifying
the woman’s exposure during a critical small time period as compared with other
studies of chronic diseases, where errors of a few months or even years may
have minimal impact.
Uterine growth retardation, congenital anomaly and
spontaneous abortions are frequently evaluated in occupational exposure
studies. There is more than one approach available to assess each outcome.
These end-points are of public health importance due to both the psychological
and the financial costs. Generally, nonspecificity in the exposure-outcome
relationships has been observed, e.g., with exposure to lead, anaesthetic gases
and solvents. Because of the potential for nonspecificity in the
exposure-effect relationship, studies should be designed to assess several
end-points associated with a range of possible mechanisms.
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