Figures
Abstract
Objective
We examined the association between occupational lifting during pregnancy and risk of fetal death and preterm birth using a job exposure matrix (JEM).
Methods
For 68,086 occupationally active women in the Danish National Birth Cohort, interview information on occupational lifting was collected around gestational week 16. We established a JEM based on information from women, who were still pregnant when interviewed. The JEM provided mean total loads lifted per day within homogeneous exposure groups as informed by job and industry codes. All women were assigned an exposure estimate from the JEM. We used Cox regression models with gestational age as underlying time variable and adjustment for covariates.
Results
We observed 2,717 fetal deaths and 3,128 preterm births within the study cohort. No exposure-response relation was observed for fetal death, but for women with a prior fetal death, we found a hazard ratio (HR) of 2.87 (95% CI 1.37, 6.01) for stillbirth (fetal death ≥22 completed gestational weeks) among those who lifted >200 kg/day. For preterm birth, we found an exposure-response relation for primigravid women, reaching a HR of 1.43 (95% CI 1.13, 1.80) for total loads >200 kg per day. These findings correspond to an excess fraction of 11% for stillbirth and 10% for preterm birth.
Conclusion
We found an increased risk of stillbirth among women with a prior fetal death, who lifted >200 kg/day, and an exposure-response relationship between occupational lifting and preterm birth among primigravid women. The study adds to a large body of prospective studies on occupational lifting and adverse pregnancy outcomes by refined exposure assessment.
Citation: Mocevic E, Svendsen SW, Jørgensen KT, Frost P, Bonde JP (2014) Occupational Lifting, Fetal Death and Preterm Birth: Findings from the Danish National Birth Cohort Using a Job Exposure Matrix. PLoS ONE 9(3): e90550. https://doi.org/10.1371/journal.pone.0090550
Editor: Shannon M. Hawkins, Baylor College of Medicine, United States of America
Received: October 14, 2013; Accepted: February 1, 2014; Published: March 10, 2014
Copyright: © 2014 Mocevic et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This study is part of the Danish collaborative MINERVA project addressing occupational risk to human reproduction, which is supported by a grant from the Danish Working Environment Research Fund (contract 20080016458). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
What Is New in the Paper
- A large body of prospective studies provides reassuring evidence that occupational lifting in general is not related major risk of fetal death and preterm birth
- This study refines assessment of occupational lifting by use of information from job and industry codes
- In relation to occupational lifting, the risk of fetal death was increased in women with a prior fetal death and the risk preterm birth was moderately elevated among primigravid women. In spite of reassuring evidence that occupational lifting in general infers a small risk, there seems to be good reason to limit high levels of occupational lifting during pregnancy
Introduction
In clinically recognized pregnancies, fetal death and preterm birth occur with a prevalence in the range of 10–14% and 5–10%, respectively [1]. Preterm birth is associated with an increased risk of perinatal and infant mortality [2] and the proportion of preterm birth seems to have increased by more than 20% among Danish women from 1995 to 2004, mostly attributable to primiparity and multiple births [3].
Among occupationally active pregnant women, the prevalence of physically demanding work is still rather high [4]. For example, 6% of pregnant women reported lifting or carrying burdens weighing >25 kg in a Dutch study [5] and 12% reported daily lifting of burdens weighing >20 kg in a Danish study [6].
The risk of miscarriage (i.e., fetal death before survival outside the uterus is considered possible) and preterm birth in relation to occupational lifting have recently been addressed in two reviews (7;8). For miscarriage, 10 epidemiological studies provided risk estimates for lifting in total ≥100 kg per day in comparison with women lifting less. The meta risk estimate was 1.32 (95% CI 0.93–1.87), but in a subset of five, the meta risk estimate was 1.02 (95% CI 0.73–1.44) [7]. For preterm birth, the median relative risk was 1.12 (interquartile range 0.90–1.30) across 17 epidemiological studies including 8 prospective cohort studies. In 11 studies with less likely bias and confounding, there was no increased risk (median relative risk 1.02, interquartile range 0.90–1.30) [8]. A formal meta-analysis of occupational lifting was not applicable because of large heterogeneity of exposure definitions across studies [8]. The review also focused on risk estimates for events appearing at different gestational ages and found no clear evidence for heterogeneity in risk related to the timing of exposures. Although this body of evidence is reassuring, the question is if true associations may have been overlooked. First, few studies have evaluated effects of lifting ≥200 kg per day, and as acknowledged by the reviewers, it therefore remains an unresolved issue if higher levels of occupational lifting confer a risk. Second, the majority of studies used individual- (as opposed to group-) based exposure assessment, which may have implied attenuation of exposure-response relations [9]. Third, exposure assessment was based upon retrospective self-reports in the majority of studies. This also partly applied to recent longitudinal studies within the Danish National Birth Cohort (DNBC), which were published after the reviews, and which reported an increased risk of fetal death [6] and preterm birth [10] with increasing total load lifted per day. Inclusion of retrospectively collected data from women who had experienced a fetal death implied a risk of overestimation of risks due to recall bias where women who already experienced pregnancy complications overestimated their lifting exposures. However, it remains to be shown if the observed risk elevations would disappear, were recall bias eliminated. Fourth, both reviews gave a lower quality assessment to studies that did not adjust for socioeconomic status, even though this might mean overadjustment due to correlations between social class and occupational lifting. Fifth, most previous studies have not evaluated spontaneous and induced preterm births separately (exceptions are Saurel-Cubizolles et al 1991 [11], Ahlborg et al 1990 [12], and Lawson et al 2009 [13]), although induced preterm birth due to severe illness of mother or foetus comprises 30–40% of preterm births [14]; inclusion of induced preterm births may have masked effects of occupational lifting on spontaneous preterm births because induced preterm births may have other causal networks than spontaneous preterm births. Sixth, the majority of previous studies have not distinguished between primi- and multigravid women. Women who have previously experienced difficulties during pregnancy or adverse pregnancy outcomes may reduce their occupational exposures when they get pregnant again, or otherwise differ from primigravid women; they may even choose not to risk another pregnancy. Thus, there is a need for exposure-response modelling using independent, group-based exposure assessment also of high levels of occupational lifting, while distinguishing between primi- and multigravid women and taking into account induced preterm births. In this study, we applied an industry and occupation specific job exposure matrix (JEM) based on means of self-reported lifting exposures within job groups. We compared self-reported exposure estimates with exposure estimates obtained using the JEM to evaluate the influence of non-occupational factors on exposure reporting in order to better understand potential bias in studies using individual-based self-reported exposure assessment. The aim of the study was to corroborate or refute the hypothesis that exposure-response relationships exist between occupational lifting and fetal death and preterm birth.
Methods
Ethics Statement
The DNBC has been approved by the Danish Data Protection Agency and by the National Committee on Health Research Ethics, which has also approved the consent procedure. The DNBC is a nationwide cohort of pregnant women and their offspring [15]. At their first antenatal care visit to the general practitioner in the period 1996 to 2002, women who intended to complete their pregnancy and who spoke Danish were invited to participate. The women were included in the cohort when they had signed and returned an informed consent form. The participants completed a telephone interview at on average gestational week 16. Women, who experienced a fetal death after enrollment but before the scheduled interview, were asked to answer a modified interview.
Study population
For each woman, we included the first pregnancy registered in the DNBC where the woman worked a minimum of 15 hours a week when interviewed or within the last three months. We excluded women with mola hydatidosa, extrauterine pregnancy, multiple pregnancies, and pregnancies with an invalid date of last menstrual period or with missing information on gestational age at recruitment or event. Furthermore, we excluded women with unknown occupational status and women without an occupational code according to the Danish version of the International Standard Classification of Occupations from 1988 (DISCO-88), Figure 1.
* Total daily loads >10,000 kg were considered outlying (n = 12).
Exposure assessment
The first step for construction of the JEM was grouping of jobs according to DISCO-88 and the Danish Industrial Classification of All Economic Activities obtained from Statistics Denmark. If ≥100 women had identical four digits DISCO-88 codes, they were subdivided according to industry codes. If the subdivision resulted in a group size of ≥10 women, the mean total load lifted per day was calculated and applied to all women within the group. The remaining women were allocated the mean load for groups defined by four digits DISCO-88 codes - and, again, if the group size was ≥10, the mean total load lifted per day was applied to all women within the group. Three or two digits DISCO-88 codes were used if <10 women had identical four digits DISCO-88 codes. The JEM was based entirely on prospectively collected data from the pregnancy interview, i.e., the women were pregnant when interviewed. They were asked “In your job, do you lift 11–20 kg at a time on a daily basis, i.e., less than a crate of beer and more than a bucket of water?” If they answered yes, they were asked “How many times a day do you lift 11–20 kg?” The women were also asked if they lifted more than 20 kg on a daily basis and how many times a day. For each woman, we calculated the total load lifted per day, with loads in the category 11–20 kg set to 15 kg, and loads above 20 kg set to 22.5 kg.
Outcome measurement
Pregnancy outcomes were identified by linkage between the Danish Civil Registration System, the Danish Medical Birth Registry, and the Danish National Patient Register (DNPR). From the Danish Medical Birth Registry we obtained data on live births and stillbirths and from the DNPR we obtained information on fetal deaths and induced or spontaneous preterm births, together with information on gestational age at pregnancy termination. We classified fetal death as early fetal death (≤12 completed gestational weeks), late fetal death (13–21 completed gestational weeks), and stillbirth (≥22 completed gestational weeks) [6].
Preterm birth was defined as delivery of a live born infant after 22 and before 37 completed gestational weeks, and we classified this outcome as extremely preterm (22–27 completed gestational weeks), very preterm (28–32 completed gestational weeks), and moderately preterm birth (33–36 completed gestational weeks) [3], [10]. An induced delivery was defined by induction of labour or cesarean section before spontaneous onset of labour.
Covariates
A priori, the following covariates were selected for inclusion in adjusted analyses: maternal age (15–24, 25–29, 30–34, 35–46 years), parity (nulliparous; yes/no), smoking in pregnancy (no smoking, ≤10 g of tobacco/day, >10 g tobacco/day), alcohol consumption in pregnancy (none, 0–1½ units/week, 2–3½ units/week, ≥4 units/week), and pre-pregnancy body mass index (<18.5, 18.5–24, 25–29, ≥30 kg/m2). For preterm birth, the following additional factors were selected: conic section before pregnancy (yes/no) and assisted reproduction (yes/no). In supplementary analyses of fetal death among multigravid women, we also included previous fetal death. We assessed socioeconomic status (SES) based on job titles and classified this variable as higher grade professional, lower grade professional, skilled worker, or unskilled worker. We only included SES in supplementary analyses because of expected high correlation with occupational lifting and because we already included other covariates related to SES [16]. Women with missing values for one or more covariates were included in the analyses in separate categories.
Data analysis
We compared self-reported exposure estimates with exposure estimates obtained using the JEM by means of multivariable regression with bootstrap to obtain regression coefficients and 95% confidence intervals (CI). We calculated hazard ratios (HR) for the association between occupational lifting and fetal death and preterm birth using Cox regression analysis with gestational age (number of days since beginning of the last menstrual period) as underlying time variable. In the analyses of fetal death, early and late fetal deaths and stillbirths were defined as events, while live births, induced abortions, maternal death during pregnancy, and emigration were censored. In the overall analyses, follow-up started at time of consent and ended at event or censoring. The analysis of early fetal death included women who were enrolled before day 84, while still pregnant, and had an additional censoring criterion, i.e. completion of gestational week 12 (at day 84). The analysis of late fetal death included women who were enrolled before day 154, while still pregnant, with follow-up starting at day 84 or at time of enrollment, whichever came last, with completion of gestational week 21 (at day 154) as an additional censoring criterion. The stillbirth analysis included women who were enrolled after day 154, while still pregnant, with follow-up starting at day 154 or at time of enrollment, whichever came last. For fetal death, we conducted subanalyses restricted to women who had been pregnant previously, stratified by previous fetal death (yes/no). Interaction between occupational lifting and prior fetal death was tested by general linear models (SAS PROC GLM). We also conducted separate analyses for primigravid women using Cox regression analysis.
By a similar approach, the preterm birth analyses were conducted for all preterm births, and for extremely, very, and moderately preterm births. Since earlier pregnancy experience might influence the choice of a new pregnancy and exposure circumstances in a new pregnancy, we also conducted separate analyses for primi- and multigravid women. To evaluate any influence of induced preterm birth, we finally carried out analyses with censoring in case of induced birth. Both for fetal death and for preterm birth, the proportional hazards assumption was fulfilled for most of the included covariates.
We estimated the potential for prevention of fetal death and preterm birth by multiplying the excess fraction, (HRadjusted-1)/HRadjusted, for each exposure category by the number of events within the exposure category, then summing up the excess numbers across all exposure categories, and finally dividing the sum by the total number of events and converting to percent. For fetal death the estimate was based on only one exposure group (201–975 kg).
Analyses for preterm birth were performed with STATA 12 software (StataCorp LP, College Station, TX, USA) and for fetal death with SAS Statistical Software v.9.2 (SAS Institute Inc, Cary, NC, USA) on Statistics Denmark's research platform.
Results
Characteristics of the total study population (N = 68,086) according to occupational lifting are listed in Table 1. The percentage who lifted >15 kg per day was 48%, when assessed using the JEM. Women, who lifted higher loads, were predominately unskilled workers, more likely to smoke in pregnancy, and had a higher body mass index. The subpopulation for the study of preterm birth (N = 65,530) did not differ from the total study population (results not shown). The most frequent job codes in the highest exposure category included waiters, manufacturing labourers, and transport and storage labourers accounting for 45% of the job codes in this category. Table 2 shows gestational age at recruitment and pregnancy outcomes for the total study population. For women, who experienced an early fetal death, only 4.3% of the data was collected prospectively, while for women, who experienced a late fetal death or stillbirth, these proportions were 39% and 99%, respectively.
Comparison of self-reported daily loads lifted with JEM-based measures revealed that higher gestational age at interview and higher maternal age were associated with reporting of lower loads lifted per day than estimated based on the JEM (around 10 kg lower). This would suggest that within a given job group, women with higher age or more advanced pregnancy lifted less than the average. Women who reported higher loads lifted per day were more likely to have a pre-pregnancy body mass index ≥30 kg/m2, smoke in pregnancy, and be multiparous (e.g. the coefficient for smoking >10 cigarettes per day as compared to no smoking was 32.1 kg; 95% CI 20.3, 43.9). Importantly, data collected retrospectively (i.e., after a fetal death) was associated with reporting of higher loads (coefficient 24.8 kg; 95% CI 6.6, 43.0), which would be consistent with recall bias.
Fetal death
In total 2,717 fetal deaths were identified in the cohort, Table 2. We found an increased risk of stillbirth in the highest lifting category (201–975 kg/day) – although the result was not significant when adjusted for potential confounders (HR = 1.40; 95% CI 0.92, 2.14), Table 3. There was no exposure-response relationship between occupational lifting and risk of fetal death, no matter if early or late fetal deaths or stillbirths.
In the analysis of women with a history of prior fetal death (n = 12,131), we found an almost three-fold increased risk of stillbirth among women who lifted 201–975 kg/day (HR 2.87; 95% CI 1.37, 6.01), Table 4. This particular group of women comprised mostly child-care workers. When the analysis was adjusted for SES, the adjusted HR was 1.90 (95% CI 0.78, 4.64). For previously pregnant women without a prior fetal death, fetal death and heavy lifting were not associated, Table 5. Corroborating these findings, we found a significant interaction (P = 0.02) between occupational lifting and prior fetal death. Based on the observed number of fetal deaths in the highest exposure category (201–975 kg) among women with a previous fetal death, we calculated an excess fraction of 11% in this group. Fetal death among primigravid women (n = 25,762) was not associated with occupational lifting (results not shown).
Preterm birth
A total of 3,128 preterm births were registered, of which 88% occurred in gestational weeks 33 to 36. Overall, we found an exposure-response relationship between total load lifted per day and risk of preterm birth (P-trend = 0.001) with a HR of around 1.25 for women lifting 101–975 kg per day, Table 6. Findings were quite similar for extremely, very, and moderately preterm birth. Table 7 shows the risk of preterm birth in relation to total load lifted per day among primi- and multigravid women. We found a clear exposure-response relation for primigravid women, reaching a HR of 1.43 for total loads of 201–975 kg/day. The adjusted HR for a one step increase in exposure category was 1.09 (95% CI 1.04, 1.14; P<0.001). With further adjustment for SES, the adjusted HR was 1.07 (95% CI 1.02, 1.12; P = 0.006). An exposure-response relationship was less evident for multigravid women, Table 7. Previous fetal death did not affect the association between occupational lifting and preterm birth (results not shown). Based on the observed number of preterm births in primigravid women lifting a minimum load of 15 kg per day, the excess fraction of preterm births was 10%. In total, 47% of the preterm births were induced and analyses using spontaneous preterm birth as the outcome (i.e., with censoring in case of induced birth) showed a little stronger association between total load lifted per day and preterm birth, reaching HR of 1.58 (95% CI 1.17, 2.13) among primigravid women lifting total loads of 201–975 kg/day. For induced preterm birth the corresponding HR was 1.28 (95% CI 0.88, 1.85). The excess fraction of spontaneous preterm birth among primigravid women lifting at least 15 kg was 11%.
Discussion
We studied the risk of fetal death and preterm birth in relation to occupational lifting as assessed by a JEM. For women with a prior fetal death, we found an almost three-fold increased risk of fetal death after week 22 among women lifting 201–975 kg/day. After adjusting for SES the association disappeared, which was expected as SES and exposure are highly correlated. Assuming a causal association, we estimated that 11% of the fetal deaths in this group could be prevented if these women avoided lifting total loads >200 kg/day. For preterm birth, we found an exposure-response relationship for primigravid women, reaching a HR of 1.43 for total loads of 201–975 kg/day, and for this group, we estimated that 10% of preterm births might be prevented by minimizing lifting exposure during pregnancy. Induced preterm births comprised 47% of all preterm births and were less clearly related to occupational lifting. Comparison of individual and JEM-based measures of lifting showed that women reported higher exposures if they were interviewed after a fetal death.
Besides a study population of more than 65,000 occupationally active pregnant women, the present study benefited from linkage of questionnaire data with nationwide registers and nearly complete follow-up. Importantly, the size of the study cohort allowed separate analyses for primigravid women, and we were able to conduct analyses with censoring of induced preterm births. We were also able to perform thorough confounder adjustment. We preferred using a JEM based on prospective data to individual self-reported exposures because we wanted to reduce the impact of individual differences in perception of lifting the same amounts; e.g. women with complications in the existing pregnancy might tend to overestimate their exposures, while being at a higher risk of preterm birth or fetal death. The JEM approach enabled us to allocate exposure measures to all women with known DISCO-88 code, despite incomplete information on lifting activities or retrospective data of lifting activities due to early pregnancy loss resulting in retrospective exposure information. In this way, we minimized the possibility of inflated effect measures due to recall bias. Furthermore, group-based exposure assessment is less subject to underestimation of exposure-response relationships than individual-based exposure assessment because attenuation of risk estimates is less in the former approach [9]. Still, our exposure-response estimates must be expected to be conservative to the extent that we unintentionally mixed job titles with high and low true exposures within the job groups.
This study has several limitations. First, information on lifting was collected only once around gestational week 16. This implied that we underestimated any true effect of lifting to the extent that women reduced or ceased lifting later in pregnancy due to adaptive measures in the workplace and/or early pregnancy leave or sick leave. In fact, our comparisons of individual and JEM-based measures of lifting supported a decreasing trend of lifting exposures with increasing gestational age. Second, we did not have the possibility to validate the JEM-based exposure estimates against estimates obtained by observation or technical measurements. Therefore the indicated exposure thresholds should be interpreted with caution. It seems plausible that relatively older women lift less than younger women within the same job group. It is harder to judge if women who smoke or have a high BMI actually lift higher loads or if they are more likely to overestimate their exposures because they experience them as more physically demanding. Therefore, these variables were not used for further modeling of the JEM-based exposure estimates. Third, the prevalence of fetal death in our sample was only 4%, i.e. lower than prevalence estimates of around 14% recorded by the DNPR with complete national coverage [17]. The low prevalence may be partly explained by late enrollment into the study so that pregnancies ending in early fetal death were not included. Women who experienced a fetal death between the first antenatal care visit and interview may also have been less likely to participate. However, fetal deaths that occurred after interview were identified through the DNPR which has a high validity of records of fetal death [18]. Therefore we believe that we had valid data on fetal death within in the study, but the risk of early fetal death escapes our evaluation.
A recent study based on almost the same cohort as the present study found an increased risk of fetal death during the first 12 weeks of gestation (with a HR of up to 2.02) for women who reported occupational lifting [6]. These results were not corroborated by our JEM-based analyses. We think that most likely, the explanation for this discrepancy is recall bias in the previous study because women who experienced a fetal death or considered their pregnancy to be at an increased risk of fetal death (e.g. due to pregnancy complications) overestimated their lifting exposures. The just-mentioned study [6] estimated the risk of recall bias by comparing the likelihood of reporting any occupational lifting (>10 kg/day) among women interviewed before and after a fetal death, and results were reassuring. However, these analyses disregarded the possibility that the absolute magnitude of recall bias (number of kg) increased with increasing true lifting exposure because women who lifted 10–20 kg/day were less likely to exaggerate their exposure by e.g. 100 kg than women who lifted >500 kg/day. Our comparison of individual and JEM-based measures of lifting corroborated the risk of recall bias in analyses relying on retrospective exposure data.
In cohort studies, it has not been possible to find a clear association between occupational lifting in pregnancy and the risk of fetal death (RR = 0.40–1.14) [12], [19], [20], but the examined total loads lifted per day typically did not exceed 100–200 kg, which means that the studies were not informative with respect to risks from heavy lifting [8]. However, one cohort study found an elevated risk of fetal death among women who had experienced a prior fetal death (n = 5) [19], which supports our result in this subgroup. Results from earlier case-control studies on lifting and fetal death are conflicting; some found an association between heavy lifting and the risk of fetal death (RR = 1.7–3.6) although the single loads lifted varied across studies (7.5–25 kg), just as the lifting frequency (lifting: yes/no, 6–50+ times/day), and others were not able to detect any effect of heavy lifting on fetal death [7]. The just-mentioned recent meta-analysis concluded that women with at risk pregnancies should receive tailored individual counseling [7]; in agreement with this, our results indicated that there is a special need to ensure low lifting exposures for women who have previously experienced a fetal death.
In our previous study, which was based on largely the same dataset, but used individual self-reported exposures [10], we found evidence of an increased risk of extremely preterm birth, with a HR of 4.3 (95% CI 1.4; 13.8) for women lifting more than 1000 kg [10]. In our present study, we did not find this association again, most likely because of our JEM-based approach to minimize recall bias together with the small number of extremely preterm births. The most recent review on preterm birth and occupational lifting concluded that large effects (i.e. RR>1.2) could be effectively ruled out, and a subsequent report from the Netherlands did not find significant associations between preterm birth and self-reported lifting [4], [21]–[23]. However, as was the case for fetal death, we think that the lack of associations may well be explained by low exposure contrasts between those categorized as heavy lifters and those categorized as non-lifters. Moreover, the review and most previous studies did not distinguish between primigravid and multigravid women; our results suggested that it is important to focus on primigravid women because otherwise associations may be underestimated.
In conclusion, our findings based on a JEM with prospectively collected lifting data did not support an exposure-response relationship between occupational lifting of up to 1 ton/day and fetal death. For women with a prior fetal death, the risk of fetal death was almost three-fold increased if they lifted >200 kg/day. Among primigravid women, we found an exposure-response relationship between occupational lifting and preterm birth, reaching a HR of 1.4 for total loads >200 kg/day. About 10% of spontaneous preterm births might be prevented by minimizing lifting exposure in this group, assuming that associations are causal. In spite of reassuring evidence that occupational lifting in general infers a small risk, if any, there seems to be good reason to limit high levels of occupational lifting during pregnancy.
Acknowledgments
The Danish National Birth Cohort has been created and supported by the Danish Epidemiology Science Centre, established by the Danish National Research Foundation. Additional support for the Danish National Birth Cohort was obtained from the Pharmacy Foundation, the Egmont Foundation, the March of Dimes Birth Defects Foundation, and the Augustinus Foundation.
Author Contributions
Conceived and designed the experiments: JPB SWS. Analyzed the data: EM PF. Wrote the paper: EM JPB SWS PF KTJ.
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