The authors declare they have no competing financial interests.
Despite the endocrine system activity exhibited by polychlorinated biphenyls (PCBs), recent studies have shown little association between PCB exposure and breast cancer mortality.
To further evaluate the relation between PCB exposure and breast cancer risk, we studied incidence, a more sensitive end point than mortality, in an occupational cohort.
We followed 5,752 women employed for at least 1 year in one of three capacitor manufacturing facilities, identifying cases from questionnaires, cancer registries, and death certificates through 1998. We collected lifestyle and reproductive information via questionnaire from participants or next of kin and used semiquantitative job-exposure matrices for inhalation and dermal exposures combined. We generated standardized incidence ratios (SIRs) and standardized rate ratios and used Cox proportional hazards regression models to evaluate potential confounders and effect modifiers.
Overall, the breast cancer SIR was 0.81 (95% confidence interval, 0.72–0.92;
We found no overall elevation in breast cancer risk after occupational exposure to PCBs. However, the exposure-related risk elevations seen among nonwhite workers, although of limited interpretability given the small number of cases, warrant further investigation, because the usual reproductive risk factors accounted for little of the increased risk.
The increase in breast cancer rates in recent decades has prompted researchers to explore the role of environmental factors in breast cancer etiology. One such factor is exposure to polychlorinated biphenyls (PCBs), which were manufactured in the United States for a variety of commercial uses from the 1930s until the late 1970s, when they were banned. These environmentally persistent compounds have exhibited endocrine system activity in the laboratory (
A systematic review found that total PCB exposure is not an important predictor for breast cancer in the general population (
Electrical capacitor production workers have been followed in several studies. Highly exposed workers (~ 2,500 individuals, including 1,318 females) in two plants that produced electrical capacitors in New York State and Massachusetts were studied by
No previous study of these capacitor worker cohorts found large or significant elevations for female breast cancer mortality, and studies that examined exposure–response trends by duration (
The study population consisted of women included in prior retrospective cohort mortality studies of workers at three capacitor manufacturing plants in the United States. Plants 1 and 2, located in New York State and Massachusetts, respectively, employed a total of 13,321 women. Plant 3, located in Indiana, had 857 female employees. From the combined base cohort of 14,178 potentially PCB-exposed women, we restricted the present study to the 5,752 women who worked for at least 1 year at any of the three capacitor plants (41% of the total). The minimum employment restriction was motivated by the difficulty in locating women with short-term employment for questionnaire follow-up. Follow-up for breast cancer incidence began after 1 year of employment. This project received approval from the National Institute for Occupational Safety and Health (NIOSH) Human Subjects Review Board (HSRB). Per the HSRB-approved protocol, a returned questionnaire was considered implied informed consent. For study participants interviewed by telephone, we obtained oral informed consent before the interview.
We mailed a self-administered questionnaire to all women or their next of kin for whom we could determine valid addresses. After two mailings and a reminder postcard, we telephoned nonrespondents to obtain the information. We identified addresses and telephone numbers using sources such as the Internal Revenue Service (IRS), the U.S. Postal Service, motor vehicle registration records, credit bureaus, and telephone number lookup services. The questionnaire collected information on
Reliable information on race was generally not available from plant records. For many deceased workers, we obtained race information from death certificates and other vital status sources. The questionnaire actively sought race information, asking women to select from the following categories: white, black, American Indian or Alaskan Native, Asian or Pacific Islander, and other. Respondents selecting “other” for race were prompted to further specify their race. The questionnaire asked separately whether the worker was of Hispanic origin.
For the present study, we used race data from the plants and from death certificates only for calculating preliminary standardized incidence ratios (SIRs) and standardized rate ratios (SRRs). In these analyses, we assumed workers of unknown race to be white. We limited further analyses evaluating the effects of race to the subcohort with questionnaire data and used only the self- or proxy-reported data to classify workers by race. This approach differs from that used in previous studies of these cohorts (
Vital status follow-up began in 1940 for the New York and Massachusetts facilities, and in 1957 for the Indiana plant, which opened in that year. Previous mortality studies of the cohorts (
For the present study, the end date for breast cancer incidence and mortality ascertainment was 31 December 1998. We identified additional breast cancer cases using questionnaires and cancer registries. Cancer registries were available in all three of the states in which the plants were located, but for varying periods of time (Massachusetts, 1982–1998; New York, 1976–1998; Indiana, 1987–1998). After we obtained the most current addresses, we evaluated the distribution by state of address and decided to also match our file against the Florida registry (covering 1981–1998) and the California registry (covering 1988–1998). Matching is done by staff at the registries, and data are not available to the public.
Questionnaire data were available for 201 of the 281 identified breast cancer cases (72%). If the report of breast cancer by a woman (or her next of kin) was specifically contradicted by another source of information (e.g., the medical record), we did not include the report as a case (
We obtained dates of breast cancer diagnosis from self-report, proxy report, the medical record, cancer registry record, or the death certificate. When diagnosis dates from multiple sources conflicted, we used the earliest date considered most valid (e.g., we considered medical record and cancer registry dates more valid than self-reported dates). For breast cancer decedents with only death certificate information (
Work history data from the three plants were collected by NIOSH in the mid-1970s. The plants began using PCBs at different times, but the overall exposure period for the cohort ranged from 1939 until 1977. We used plant-specific semiquantitative JEMs to allow ranking of exposure intensity for all workers across all three plants and across time. Sources used to develop the JEMs included work history records, a small number of air samples from the mid-1970s, information about historical process changes, job descriptions, and plant layouts. Separate JEMs for inhalation and dermal exposures in each plant used the same scale for exposure scores across plants and routes of exposure. We used an average of inhalation and dermal exposure scores to create the final plant-specific JEMs. These scores are unitless, because the dermal component could not be quantified; in the analysis, cumulative exposures are summed 1,000 unit-years. The exposure assessment process has been described in detail (
We used the NIOSH Personal Computer Life Table Analysis System (PC-LTAS) to determine whether the incidence of breast cancer in the study cohort was higher than that expected from general population rates (
Analyses using SEER referent rates produced SIRs and SRRs by categories of cumulative exposure and exposure duration, stratified by age (in 5-year categories), calendar time (in 5-year categories), and, for some analyses, race (white and nonwhite). Follow-up time began in 1970 when the SEER rates became available, or 1 year after employment, whichever was later. Beginning follow-up in 1970 eliminated 24 (8.5%) of the 281 breast cancer cases and 34.3% of the person-time from LTAS analyses only. Follow-up continued until the date of diagnosis, date of death, study end date (31 December 1998), or last known date before loss to follow-up, whichever was earliest. We also conducted lagged analyses to allow for the necessary latency period for solid tumors, with 0-, 10-, and 15-year lags examined. This lag discounts all exposure in the last years before the cutoff date, and sometimes results in a worker having no exposure or being “lagged out.” For exposure–response analyses, LTAS calculated a linear trend in a person-year–weighted regression of directly standardized rates, with statistical significance of each trend determined using a two-tailed
We conducted internal exposure–response analyses using Cox regression. We used the SAS PHREG procedure (
We limited regression analyses for the full cohort (5,752 workers) to exploring exposure metrics and birth cohort effects. We considered several exposure metrics: cumulative exposure (log-transformed and untransformed), duration of exposure (log-transformed and untransformed), peak exposure, and average exposure (cumulative exposure divided by duration of exposure). We analyzed all metrics as continuous and categorical, with lags of 0, 10, and 15 years evaluated. We performed similar analyses for the subset of workers with some questionnaire data (the “questionnaire subcohort”) to see whether risks were similar in the two groups.
Because of the importance of certain covariates in assessing the relations between PCB exposure and breast cancer risk, we restricted further analyses to workers with complete questionnaire data on covariates of
We knew from prior studies (
We performed covariate analyses on the restricted cohort, using backward elimination to rule out the least influential of the potential confounders. We also examined key interaction terms, evaluating statistical significance with the chi-square likelihood ratio test.
Among the full cohort of 5,752 women, the mean ± SD duration of employment was 7.7 ± 4.5 years. A total of 1,413 (25%) had died by the study end date. We obtained completed questionnaires for 3,952 (69%) of the cohort, 80% from living respondents and 20% from next of kin of deceased cohort members. The primary reason for nonresponse was our inability to determine a correct address (21%). A total of 500 former workers and proxy respondents (8.7%) refused to complete the questionnaire, and 112 (2%) failed to respond after repeated attempts.
We found 281 incident breast cancer cases in the full cohort. Although mortality follow-up of the cohort was exhaustive, nonfatal incident cases occurring before initiation of the cancer registries or occurring in states other than Massachusetts, New York, Indiana, Florida, and California could be ascertained only via questionnaire. Approximately 20% of the cohort did not return a questionnaire and were not known to be deceased at end of follow-up; incident cases occurring outside the registry search may have been missed in this group, particularly in the early years of follow-up.
Of the full cohort, we identified 147 women by plant records and death certificates as being of races other than white. When we used the questionnaire responses instead, the number of workers (both cases and noncases) identified as being of races other than white rose to 282. This group includes workers identifying as members of specific races other than white (black, American Indian/Alaskan Native, Asian, or Pacific Islander), women who identified only as “other,” and women identifying as multiracial. Because the number of workers identifying as other than white was small, we kept this group together for all further analyses and refer to it herein as “nonwhite,” although some women in fact selected a multiracial identity where one of the races was white.
Of the 281 cases in the full cohort, we identified only eight as nonwhite from plant or death certificate data. However, among workers with complete questionnaire data on the covariates of
More data were available for the questionnaire subcohort, including demographic and lifestyle characteristics. Again, cases (
The plants differed in a number of ways. Most striking were the contrasts in exposure distributions. Mean ± SD estimated exposure for the workforce of plant 2 (0.80 ± 1.06, 1,000 unit-years) was more than twice that in plant 1 (0.34 ± 0.71) and was an order of magnitude greater than that in plant 3 (0.078 ± 0.10). The medians reflected a similar pattern (plant 2 = 0.39, plant 1 = 0.11, and plant 3 = 0.04). Although all three facilities had nonwhite populations < 4% according to records-based data, we classified > 15% of workers at plant 2 as nonwhite using questionnaire data. The percentages of nonwhite workers for plants 1 and 3 increased only slightly when we used questionnaire data.
In the aggregate, white and nonwhite workers in the restricted subcohort differed on a number of demographic and lifestyle factors (
SIR and SRR results reflect follow-up time and cases occurring in 1970 or later, because of availability of SEER comparison data. For the full cohort, the unlagged SIR was 0.81 [95% confidence interval (CI), 0.72–0.92;
SRR results differed depending on dose cut points and lag (data not shown), particularly for white women, with no consistent patterns observed. In nonwhite women, trends were always positive and sometimes statistically significant, depending on cut points and lag. However, elevations were limited to the highest dose categories, with deficits observed in some intermediate categories.
Because the SRR results suggested a difference in risk by race, we evaluated the effects of race in the regression analyses and then conducted further evaluations of potential confounders and effect modifiers in the restricted cohort separately for nonwhite and white women.
Among white women, cumulative exposure and duration of exposure had little effect on breast cancer risk. Birth cohort was significant, with an increased risk for the group born during the period 1920–1934 and a larger increase compared with baseline for those born after 1934. Beyond birth cohort, the covariates retained in the model were parity, family history of breast cancer, and self- versus proxy questionnaire completion. Plant did not strongly affect the relation between the exposure metrics and breast cancer risk, and we eliminated this variable from the model. Use of hormone replacement therapy, although technically a confounder, had a lesser effect on risk, and we also eliminated this variable from the final model in the interest of parsimony. Menopausal status was not a confounder in this group.
In contrast, among nonwhite women, the effects of increasing exposure were positive and statistically significant. Both cumulative exposure (continuous) and duration of exposure were highly associated with breast cancer risk. Categorical exposure was associated with elevated risk at the two highest levels, but not in the intermediate category. The variables usually considered breast cancer risk factors (family history, parity, use of hormone replacement therapy, menopausal status) had little effect on risk in this group (data not shown). The most important covariates for this cohort were ever-smoking, source of questionnaire data, and birth cohort (limited to those women born after 1934). In univariate analyses, nonwhite cases smoked more than noncases (46 vs. 29 pack-years), in part because they smoked for more years (42.6 vs. 32.9). We did not observe these patterns among white workers. To assess whether smoking might be a proxy for alcohol use, we examined models with smoking but not alcohol, with alcohol but not smoking, and with both alcohol and smoking and found that only smoking had significant explanatory value.
To further explore the effects of smoking in nonwhite workers, we considered current smoking status (at time of death for deceased workers or time of questionnaire completion for living workers) and pack-years. Adding pack-years or current smoking status to a model that included ever smoking had little effect. The interaction between current smoking status and cumulative exposure nearly attained statistical significance (
Because the mean and median PCB exposure estimates were significantly higher among nonwhite workers, we considered the possibility that the greater risk observed in nonwhite women was attributable to a high-exposure effect. We reevaluated the exposure risk in white women using the same cut points employed for nonwhite women and found the same lack of trend we observed with the original quartile-based cut points. The lack of exposure–response in white women does not appear to be related to the lower exposure levels in this group.
In this study of breast cancer incidence among female workers employed in capacitor production facilities, differences in risk by race, although subject to a number of caveats, were evident. In white women, the SIR was below expectation, and in the modeling analyses, the very small positive exposure response observed was largely explained by the well-known risk factors parity, age at first live birth, and family history of breast cancer. Differences between the SIR and exposure–response results likely resulted from differences in covariate control, in addition to differences between the subcohorts used in the SIR and regression analyses; despite these differences, we observed no statistically significant elevation of risk in any subcohort of white women. These results suggest that among white women, if there is a relation of PCB exposure with breast cancer risk, it is likely quite modest, even at the relatively high levels characteristic of occupationally exposed populations.
In contrast, among nonwhite women, whereas the SIR was close to expectation, the strong, positive exposure response seen in regression analyses was only modestly attenuated by smoking, birth cohort, and source of questionnaire data (self or proxy), the only covariates with significant explanatory power. Race was not a variable of strong
In both white and nonwhite women, risk of breast cancer after PCB exposure was lower for women born before 1920 than for those born after 1934. The pattern of increasing breast cancer incidence risk for later birth cohorts is generally consistent with results reported from the SEER registry (
The study has several potential limitations. Response bias is a possibility when questionnaires are used. If nonrespondents had lower breast cancer rates than respondents, an artificial excess of breast cancer would be observed in the exposed population versus the nonexposed referent population. To minimize the likelihood of such bias, the study materials referred not to breast cancer but to “health effects.”
Of greater concern is that ascertainment of incident breast cancer cases was likely better for the later years of the study, when cancer registry data were available to supplement death records and questionnaire data. Although we identified only 10 breast cancer deaths using death certificates alone, it is likely that nonfatal incident cases were missed in the early years. This would lead to underestimates of the SIR and could affect exposure–response analyses, because early exposures were substantially higher than those in later years. In addition, this could affect observed secular trends. On the other hand, we could not verify some of the cases identified via questionnaire either by medical records or by a cancer registry, so we cannot rule out limited overascertainment.
Completion of questionnaires by proxy respondents likely introduced misclassification on some covariates. Proxy respondents often left blanks in response to some questions, so the restricted cohort underrepresents deceased workers. In addition, proxy respondents may also have been less accurate in responses to questions they did answer. When we performed a sensitivity analysis evaluating proxy and self-respondents in the restricted cohort separately, we found that results for each group were quite similar to those for all respondents combined, although risk estimates were slightly higher among self-respondents.
Errors in reporting of smoking are potentially problematic, given the results in nonwhite women. Studies have shown that smoking status is reported more accurately by proxies than was number of cigarettes smoked (
Misclassification of PCB exposure is another potential limitation. We assessed exposure levels by job title, department, and work process, with limited air sampling data available from the 1970s only. The combination of dermal and inhalation exposures into a single semiquantitative estimate does not account for differences in doses by route of exposure. In addition, the use of total PCBs as the exposure metric may obscure the effects of individual congeners or subgroups.
Race, although an important predictor for breast cancer risk after PCB exposure in this study, is not well defined for this cohort. In addition to general concerns about using race in place of more specific information about genetics to explain disease risk (
Further specification of ethnic origins of all members of the cohort would be of interest because other studies raise the possibility that differences in nonoccupational exposure levels and/or genetic susceptibility could contribute to observed differences in risk by race. A study of women residing near a PCB-contaminated harbor in New Bedford, Massachusetts, close to where plant 2 is located, found higher PCB levels in infants of women from Portugal, the Azores, and Cape Verde compared with those born in the United States, Canada, or other countries (
Smoking is not generally considered a risk factor for breast cancer. The smoking results in the present study may represent a chance finding, or smoking may be a proxy for some other risk factor (although we ruled out alcohol, one obvious possibility) or a vehicle for greater but unmeasured PCB exposure through hand-to-mouth ingestion.
The lack of any significant overall increase in risk of breast cancer after PCB exposure in this occupational cohort is reassuring and consistent with the results of previous studies of the contributing cohorts (
The findings and conclusions in this report are those of the authors and do not necessarily represent the views of the National Institute for Occupational Safety and Health.
We thank M. Schubauer-Berigan, P. Laber, C. Gersic, F. Armstrong, C. Lehman, Z. Zivkovich, T. Schnorr, and M. Torok for their assistance with this study. The assistance of the following cancer registries was also invaluable: the Massachusetts Department of Public Health, Massachusetts Cancer Registry; the New York State Department of Health, New York State Cancer Registry; Indiana State Department of Health, Indiana State Cancer Registry; California Cancer Registry; and the Florida Cancer Data System.
This study was supported, in part, by the Department of Defense Women’s Health Research Program (MIPR 94MM4580).
Characteristics of breast cancer cases and noncases.
| Variable | Cases | Noncases |
|---|---|---|
| Entire cohort | ||
| No. of workers | 281 | 5,471 |
| Year of birth (mean ± SD) | 1926 ± 11 | 1930 ± 13 |
| Years exposed (mean ± SD) | 9.3 ± 8.2 | 7.7 ± 7.6 |
| Cumulative exposure (1,000 unit-years) | ||
| Mean ± SD | 0.67 ± 0.95 | 0.57 ± 0.93 |
| Median | 0.27 | 0.22 |
| Questionnaire subcohort | ||
| No. of workers | 201 | 3,751 |
| Year of birth (mean ± SD) | 1928 ± 11 | 1932 ± 12 |
| Self-respondent on questionnaire (%) | 63.7 | 82.0 |
| Nonwhite ethnicity (%) | 7.5 | 9.3 |
| Ever-smoker (%) | 51.0 | 52.3 |
| BMI at 20 years of age [kg/m2 (mean ± SD)] | 20.8 ± 3.0 | 21.2 ± 3.2 |
| Age at menarche [years (mean ± SD)] | 12.8 ± 1.7 | 12.9 ± 1.7 |
| Premenopausal at diagnosis (%) | 15.4 | NA |
| Parous (%) | 86.1 | 86.7 |
| No. of live births (mean ± SD) | 2.5 ± 1.7 | 2.5 ± 1.8 |
| Age at first live birth [years (mean ± SD)] | 23.8 ± 4.2 | 23.0 ± 4.5 |
| Used hormone replacement therapy (%) | 27.5 | 33.3 |
| Age began hormone replacement use [years (mean ± SD)] | 46.5 ± 8.8 | 47.2 ± 9.2 |
| Breast cancer in first-degree female relative (%) | 21.2 | 13.9 |
| Years exposed (mean ± SD) | 8.9 ± 8.2 | 7.4 ± 7.4 |
| Cumulative exposure (1,000 unit-years) | ||
| Mean ± SD | 0.59 ± 0.84 | 0.52 ± 0.89 |
| Median | 0.27 | 0.20 |
NA, not applicable.
Questionnaire subcohort comprises members of the full cohort for whom some questionnaire data were available. Not all participants (or their proxies) provided responses for each question; some variables have missing values.
Selected characteristics of restricted cohort
| Variable | White ( | Nonwhite ( |
|---|---|---|
| Cases and noncases | ||
| Year of birth (mean ± SD) | 1934 ± 11.6 | 1933 ± 10.6 |
| Self-respondent on questionnaire (%) | 90.0 | 89.0 |
| Ever-smoker (%) | 51.8 | 55.0 |
| Pack-years (ever-smokers only) (mean ± SD) | 35.2 ± 28.0 | 29.3 ± 24.0 |
| BMI at 20 years of age [kg/m2 (mean ± SD)] | 21.2 ± 3.2 | 21.5 ± 3.6 |
| Age at menarche [years (mean ± SD)] | 12.9 ± 1.7 | 13.2 ± 1.9 |
| Premenopausal at diagnosis (%) | 19.2 | 14.3 |
| Parous (%) | 87.5 | 88.0 |
| No. of live births (mean ± SD) | 2.5 ± 1.7 | 2.9 ± 2.1 |
| Age at first live birth [years (mean ± SD)] | 23.0 ± 4.4 | 22.5 ± 4.7 |
| Used hormone replacement therapy (%) | 33.2 | 31.6 |
| Age began hormone replacement use [years (mean ± SD)] | 47.3 ± 8.9 | 48.2 ± 10.4 |
| Breast cancer in first-degree female relative (%) | 13.5 | 18.8 |
| Years exposed (mean ± SD) | 7.0 ± 7.1 | 6.6 ± 6.6 |
| Cumulative exposure (1,000 unit-years) | ||
| Mean ± SD | 0.45 ± 0.81 | 0.64 ± 0.88 |
| Median | 0.16 | 0.33 |
| Breast cancer cases only | ||
| No. of cases | 131 | 14 |
| Cumulative exposure (1,000 unit-years) | ||
| 25th percentile | 0.07 | 0.17 |
| 50th percentile | 0.22 | 1.15 |
| 75th percentile | 0.63 | 2.13 |
Restricted cohort comprises women with questionnaire data for ever smoking, parity, age at first live birth, breast cancer in a first-degree female relative, hormone use, and age began hormone use. Some other variables have missing values.
Main effects exposure–response results for breast cancer incidence with a 10-year lag by subcohort: hazard ratio (95% CI).
| Variable | Full cohort ( | Questionnaire subcohort | Restricted subcohort |
|---|---|---|---|
| Model 1 | |||
| Cumulative exposure (per 1,000 unit-years) | 1.01 (0.96–1.05) | 1.00 (0.94–1.06) | 1.04 (0.97–1.11) |
| Born < 1920 (reference group) | 1.00 | 1.00 | 1.00 |
| Born 1920–1934 | 1.63 (1.19–2.23) | 1.71 (1.14–2.57) | 1.64 (0.96–2.83) |
| Born ≥ 1935 | 2.47 (1.65–3.70) | 2.86 (1.74–4.71) | 3.40 (1.79–6.46) |
| Model 2 | |||
| Years exposed | 1.01 (0.99–1.03) | 1.01 (0.99–1.03) | 1.02 (1.00–1.05) |
| Born < 1920 (reference group) | 1.00 | 1.00 | 1.00 |
| Born 1920–1934 | 1.62 (1.18–2.22) | 1.72 (1.14–2.58) | 1.66 (0.96–2.86) |
| Born ≥ 1935 | 2.50 (1.67–3.75) | 2.93 (1.78–4.84) | 3.52 (1.85–6.72) |
Questionnaire subcohort comprises members of the full cohort for whom some questionnaire data were available.
Restricted cohort comprises women with questionnaire data for ever smoking, parity, age at first live birth, breast cancer in first-degree female relative, hormone use, and age began hormone use.
Full models for breast cancer incidence with a 10-year lag, restricted subcohort
| Variable | Hazard ratio (95% CI) |
|---|---|
| White women (131 cases) | |
| Model 1: Continuous cumulative exposure (per 1,000 unit | 1.00 (1.00–1.00) |
| Born < 1920 (reference group) | 1.00 |
| Born 1920–1934 | 3.07 (1.63–5.78) |
| Born ≥ 1935 | 7.81 (3.65–16.7) |
| Self-respondent | 0.31 (0.19–0.50) |
| Parous | 0.30 (0.10–0.84) |
| Age at first live birth | 1.07 (1.03–1.11) |
| Positive family history | 1.60 (1.05–2.44) |
| Model 2: Years exposed | 1.02 (0.99–1.05) |
| Model 3: Categorical cumulative exposure (per 1,000 unit | |
| 0 to < 0.16 ( | 1.00 |
| 0.16 to < 0.46 ( | 1.36 (0.83–2.23) |
| 0.46 to < 1.6 ( | 1.15 (0.70–1.89) |
| ≥ 1.6 ( | 1.27 (0.75–2.17) |
| Nonwhite women (14 cases) | |
| Model 4: Continuous cumulative exposure (per 1,000 unit | 1.33 (1.14–1.56) |
| Born < 1920 (reference group) | 1.00 |
| Born 1920–1934 | 0.94 (0.22–4.07) |
| Born ≥ 1935 | 3.75 (0.51–27.8) |
| Self-respondent | 0.07 (0.02–0.26) |
| Ever-smoker | 3.84 (1.01–14.6) |
| Model 5: Years exposed | 1.13 (1.03–1.23) |
| Model 6: Categorical cumulative exposure (per 1,000 unit | |
| < 0.47 ( | 1.00 |
| 0.47 to < 3.9 ( | 0.60 (0.12–3.01) |
| 3.9 to < 5.8 ( | 7.65 (1.11–52.8) |
| ≥ 5.8 ( | 22.3 (2.38–209) |
Restricted cohort comprises women with questionnaire data for ever smoking, parity, age at first live birth, breast cancer in first-degree female relative, hormone use, and age began hormone use.
Models control for birth cohort (1920–1934, ≥ 1935, vs. < 1920); self-respondent, parity, age at first live birth, and positive family history).
Models control for birth cohort (1920–1934, ≥ 1935, vs. <1920); self-respondent and ever-smoker).