Abstract
Purpose
Hormone replacement therapy (HRT) use increases breast cancer risk and mammographic density (MD). We examine whether MD mediates or modifies the association of HRT with the breast cancer.
Methods
For the 4,501 participants in the Danish diet, cancer and health cohort (1993–1997) who attended mammographic screening in Copenhagen (1993–2001), MD (mixed/dense or fatty) was assessed at the first screening after cohort entry. HRT use was assessed by questionnaire and breast cancer diagnoses until 2012 obtained from the Danish cancer registry. The associations of HRT with MD and with breast cancer were analyzed separately using Cox’s regression. Mediation analyses were used to estimate proportion [with 95% confidence intervals (CI)] of an association between HRT and breast cancer mediated by MD.
Results
2,444 (54.3%) women had mixed/dense breasts, 229 (5.4%) developed breast cancer, and 35.9% were current HRT users at enrollment. Compared to never users, current HRT use was statistically significantly associated with having mixed/dense breasts (relative risk and 95% CI 1.24; 1.14–1.35), and higher risk of breast cancer (hazard ratio 1.87; 1.40–2.48). Association between current HRT use and breast cancer risk was partially mediated by MD (percent mediated = 10%; 95% CI 4–22%). The current HRT use-related breast cancer risk was higher in women with mixed/dense (1.94; 1.37–3.87) than fatty (1.37; 0.80–2.35) breasts (p value for interaction = 0.15).
Conclusions
MD partially mediates some of the association between HRT and breast cancer risk. The association between HRT and breast cancer seems to be stronger in women with dense breasts.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Mammographic density (MD) is increasingly being used as a biomarker of breast cancer risk, as it is one of the strongest risk factors [1]. MD refers to the amount of radiologically dense breast consisting of epithelial or stromal tissue that appears light on a mammogram, whereas fat tissue appears dark on a mammogram [2]. Women with very dense breasts (> 75% density in the breast) have a four to six times greater risk of breast cancer than women with little density (< 5–10%) or fatty breasts [1, 2].
Combined estrogen plus progestin hormone replacement therapy (HRT) is an established risk factor for breast cancer [3,4,5] although it is still commonly used as an effective treatment for alleviating the climacteric symptoms of menopause such as hot flushes, sleeping disturbance, depressive mood, muscle, and joint pain. Therefore is it important to evaluate whether adverse effects of HRT on breast cancer risk pertain to all women, or may be modified by other factors, such as MD, so that some women with certain MD (high or low) can use HRT while do not react on it [6,7,8]. Combined estrogen plus progestin refers to different treatment regimens including cyclical HRT, also known sequential estrogen + progestin (SEP) and continuous estrogen + progestin (CEP) [9]. SEP therapy refers to use of estrogen daily with progestin added to it for 10–14 days every 4 weeks, while CEP therapy refers to continuous use of estrogen and progestin on a daily basis [9].
A number of studies have shown that current use of HRT increases MD [10,11,12,13,14] and that positive association between HRT and MD is of similar magnitude to that of HRT and breast cancer [4, 5]. Thus, it was suggested that HRT increases risk of breast cancer via its effect on MD, and that MD is thus the mediating factor [15,16,17]. However, this is not fully understood, with only three studies to date. Boyd et al. found that association between HRT and breast cancer was robust to adjustment for MD, concluding that the effects of HRT on MD, and on breast cancer risk, respectively, are separate and not related causally, but has not conducted formal mediation analyses [15]. Rice et al. found that the association between current HRT use and breast cancer in postmenopausal women was statistically significantly mediated by percent MD, by 22% [16]. Finally, Byrne et al. found that increase in breast cancer risk among postmenopausal women using estrogen plus progestin HRT regimen was completely mediated by increase in MD [17].
Furthermore, it has been suggested that the impact of HRT use on breast cancer risk varies by MD. Hou et al. found that the HRT use was associated with the highest breast cancer risk in women with very dense breasts, while no excess risk was found with HRT use in women with fatty breasts [7]. Similarly, a case–control study by Boyd et al. reported significantly stronger positive associations between HRT use and MD in breast cancer cases than in controls [6]. Kerlikowske et al. concluded that women with high breast density have the added increased risk of breast cancer when taking HRT [8]. Furthermore, they had data on HRT regimens and found excess breast cancer risk with both, estrogen and estrogen plus progestin [8].Yaghjyan et al. found that women with dense breast who are current user of HRT are at significant higher risk of breast cancer than previous and never user of HRT [18].
The purpose of this study is to determine whether the effect of HRT on breast cancer risk is mediated or modified by its effect on MD, separately for different HRT regimens: estrogen (E), SEP, and CEP.
Patients and methods
Danish diet, cancer and health cohort
Between 1993 and 1997, a total of 160,725 persons (72,729 women), 50–64 years of age, born in Denmark, living in Copenhagen or Aarhus (the two largest cities in Denmark), and with no record of cancer in the Danish Cancer Registry, were invited to participate in the Danish prospective diet, cancer and health (DCH) cohort. In total, 57,053 people, of whom 29,875 were women (37% of invited women and 7% of the entire Danish female population in this age group), accepted the invitation and participated in the study and answered a detailed questionnaire on diet, health, education, occupation, lifestyle, and reproductive characteristics. A detailed description of the DCH cohort has been published previously [19].
Study cohort
The study cohort consist of 4,501 postmenopausal women from the Danish diet, cancer and health cohort who participated in the Copenhagen mammography screening program between 1991 and 2001.
HRT exposure assessment
Participants of the DCH cohort reported at the baseline lifestyle questionnaire information on use of HRT at enrollment (never/previous/current), the age at which they began using HRT, the duration (years) of HRT use, and the brand of HRT product used. ‘Triers’ were defined as former HRT users with less than 6 months of use. Based on the self-reported brand of HRT product used, the HRT regimen was coded as either unopposed estrogen or as estrogen + progestin combination, which was further classified as either continuously administered estrogen + progestin (CEP) or sequentially administered estrogen + progestin (SEP).
Confounders and co-morbidity
The DCH lifestyle questionnaire provided information about physical activity in leisure time (yes/no), alcohol use (g/day), education (≤ 7, 8–10, > 10 years), parity, number of children, age at first birth, history of hysterectomy, and history of benign breast tumor. Body mass index (BMI) was measured by trained professionals at baseline. Women were divided into three birth year intervals (1929–1934, 1935–1939, and 1940–1946) to account for birth-cohort effects. Women were defined as postmenopausal at the cohort baseline if they reported having no menstruation within 12 months prior to the baseline questionnaire.
MD definition
The Copenhagen mammography screening program started in 1991 [20, 21] and targeted about 40,000 women aged 50–69 years at the start of each biennial invitation round. Women were free to refuse to participate in screening as well as to decline further invitations. We used data from the first screening of 134,640 women who participated in first five rounds of screening between 1991 and 2001 [20]. One radiologist was in charge of the screening, which occurred at a single Copenhagen hospital. At women’s first screening, a two-view mammography, craniocaudal and oblique, was taken by the radiographers or X-ray nurses. Analog mammography was used, and mammograms were evaluated independently by visual assessment by two trained radiologists, who did not meet the attending women, unless they were recalled for assessment. Attending women were asked to fill in a questionnaire about HRT use, earlier breast surgery, family history of breast cancer, and eventual suspicion of a breast lump; however, this information was not entered in the database of the Copenhagen mammography register, and was thus not available for this study. Women with a negative screening test and fatty breasts were scheduled to have only an oblique view at the next screen, whereas women with a negative screening test and mixed/dense breasts were scheduled for two views, in order to improve sensitivity of screening, as masking is more likely in women with mixed/dense breasts. Radiologists have recorded their recommendation for one- (1) or two-view (2) mammography at the subsequent screening for each woman, available as a variable from the Copenhagen mammography register, which is a proxy of fatty (1) or mixed/dense (2) MD. Fatty (1) MD corresponds to equivalent to breast imaging reporting and data system (BI-RADS, Atlas, 2003) [22] code 1 (< 25%) and part of code 2 (25–50%), while mixed/dense (2) MD corresponds to part of BI-RADS code 2 (25–50%), and BI-RADS codes 3 (51–75%), and 4. To evaluate MD readings, two radiologists had to come to an agreement on the MD readings. In cases in which readings did not reach consensus, the evaluation was sent to a third radiologist. We could not estimate inter-reader agreement in this study population, but very experienced readers have generally high inter-observer agreement in Copenhagen mammography screening program, as documented earlier [23].
This internationally unique dichotomous outcome for MD has been successfully validated in 120 mammograms which have been assigned both dichotomous and BI-RADS density classification scores, showing a substantial agreement with inter-rater variability (weighted kappa statistic) of 0.75 [21]. Furthermore, the Danish dichotomous MD score has been utilized in several earlier studies, showing the expected doubling of breast cancer risk in women with mixed/dense as compared to those with fatty breasts [23, 24], as well as showing strong inverse association with BMI in childhood [25], inverse association with active smoking in adult age [26], and no association with air pollution [27], all validating this measure of MD.
The Copenhagen mammography register contains information for all mammograms, including date of screening, MD (fatty or mixed/dense), and outcome of screening (negative or positive) taken during the screening program between 1991 and 2001, for women living in Copenhagen municipality aged between 50 and 69 years. For women who were part of the Danish diet, cancer, and health cohort and participated in mammographic screening in this period, we used MD assessed at the first screening after the cohort baseline (1993–1997). We did this in order to obtain prospective design, with HRT assessed at the cohort baseline, and MD assessed after baseline questionnaire on HRT. Average time between the cohort baseline and screening at which MD was obtained was 1.1 year (median 1 year, 25th percentile 0.5 years, 75th percentile 1.5 years, min 0.03 years, max 6.8 years).
Breast cancer definition
We linked the records of 4,501 women using the Danish personal identification number (CPR) to the Danish cancer registry [28] to extract breast cancer diagnoses, including invasive and in situ cancers (ICD-10 codes C50 and D05) between screening (1991–2001) and 31 December 2010, and to the civil registration system to extract information on emigration or death [29].
Statistical methods
We used generalized linear model (glm) for binary data with log link function [relative risk (RR) regression for binary data] to examine the association between HRT and MD. Since the log–glm model did not converge, we instead fitted the model using Cox proportional hazard procedure [30] with age as underlying time to examine association (estimate RR and 95% CIs) of MD with HRT use at enrollment (ever/never and current/previous/triers/never), HRT duration, time since HRT cessation, and HRT regimens (estrogen CEP, SEP) in separate models. Models were fit in two steps: a crude model (model 1), adjusted for age (underlying time scale) and in a model adjusted for age, birth cohort, education, BMI, alcohol use, physical activity, history of benign breast tumor, history of hysterectomy, parity, number of children, and age at first birth (model 2). The follow-up started on the date of cohort entry (1993–1997) and ended at the time of death, emigration, of mammographic screening, whichever came first. We used Cox proportional hazards regression with age as the underlying time, to investigate associations of breast cancer risk with HRT use at enrollment (ever/never and current/previous/triers/never), HRT duration, time since HRT cessation, and HRT regimens (estrogen CEP, SEP), separately, in three steps: a crude model, adjusted for age (age adjusted as age is underlying time scale) and BMI (model 1), a model additionally adjusted for birth cohort, education, alcohol use, physical activity, history of benign breast tumor, history of hysterectomy, parity, number of children, and age at first birth (model 2), and a model 2 additionally adjusted for MD (model 3). The follow-up started on the date of cohort entry (1993–1997) and ended at a date of breast cancer diagnosis, death, emigration, or 31 December 2011, whichever came first. We have examined the mediation of the association between HRT use at cohort baseline and breast cancer risk by MD, by using the method for counterfactual-based mediation analysis implemented through natural effect models as originally proposed by Lange et al. [31], and adapted to Cox setting as detailed in Lange et al. [32]. This method uses natural effects Cox model to estimate direct and indirect effects on HRs scale, as well as mediated proportion with 95% CIs. The potential effect modification of an association between HRT use and breast cancer by MD was evaluated by introducing interaction terms into the Cox model, and tested by the Wald test. Main logistic and Cox regression analyses were performed in Stata 11.2. Mediation analyses were performed in medflex package for R statistical programme [33].
The study was entirely based on register data and was approved by the Danish data inspection agency (2014-41-3168). Danish law regarding ethical approval of register-based research does not require informed consent from study participants, thus no contact was made with the participating women or their relatives and general practitioners.
Results
Table 1 presents the distribution of the baseline characteristics for 4,501 women from DCH cohort. The majority, 2,444 (54.3%) of women had mixed/dense breasts and 229 (5.1%) developed breast cancer during 15 years of follow-up, giving incidence rate of 3.4 cases per 1,000 person-years. Half of the women, 2,318 (51.5%) reported ever using HRT at enrollment, while 1,617 (35.9%) were current users at baseline. Of 2,318 ever users, 389 (8.6%) women reported using estrogen, 312 (6.9%) used SEP, and 1,617 (35.9%) used CEP.
Ever users of HRT at enrollment had significantly higher risk of having mixed/dense breasts (RR and 95% CI 1.16; 1.07–1.26) than never users (Table 2). The highest risk was observed for current HRT users at enrollment (1.24; 1.14–1.35), and there was no association in previous users or triers. The risk of having mixed/dense breasts was increased by 6% (1.06; 1.02–1.10) for each 5-year use of HRT, but was reduced by 6% after each 5-year cessation of HRT use (0.94; 0.88–1.00, per 5 years after cessation). The association with MD was limited to estrogen + progestin users, with highest RRs observed in SEP users (1.34; 1.20–1.50) followed by CEP users (1.21; 1.01–1.44), while no associating was observed with estrogen use (1.08; 0.94–1.23).
Having mixed/dense MD was significantly positively associated with the breast cancer risk (HR; 95% CI 1.86; 1.38–2.52) (Table 3). Ever users of HRT had significantly higher risk of breast cancer than non-users (1.56; 1.19–2.04), with the highest risk observed in current users at enrollment (1.87; 1.40–2.48) and none in previous users or triers. Mean time between mammographic screening and breast cancer diagnosis was 7.7 years. Women who used CEP had the highest risk for breast cancer (3.39; 2.20–5.22), followed by users of SEP (2.09; 1.48–2.97) as compared to non-users. Estrogen use was not associated with breast cancer risk (0.99; 0.59–1.65).
After adjustment for MD, the associations between HRT use and breast cancer attenuated slightly in ever (1.49; 1.13–1.95) and current users (1.76; 1.32–2.34), as well as for SEP users (1.94; 1.37–2.69) and CEP (3.21; 2.08–4.94) (Table 3).
Ever use of HRT showed statistically significant direct (1.49; 1.14–1.98) and indirect effect, or effect mediated by MD (1.05; 1.02–1.08), on breast cancer risk, with estimated mediation proportion of 11% (4–30%) (Table 4). Similarly, compared to never use, current use of HRT at the cohort baseline showed statistically significant direct (1.73; 1.31–2.33) and indirect (1.06; 1.03–1.11) effect on breast cancer risk, with a proportion mediated by MD of 10% (4–21%). There was not enough statistical power to estimate mediation for different HRT regimens.
The breast cancer risk related to HRT was highest in women with mixed/dense breasts, both in ever (HR; 95% CI 1.86; 1.21–2.85) and current (1.94; 1.37–3.87) users at enrollment, compared to women with fatty breasts (1.24; 0.77–1.98 and 1.37; 0.80–2.35, in ever and current users), although the differences were not statistically significant (p value for interaction 0.22 and 0.15, respectively) (Table 5). The association with breast cancer seemed to be strongest in SEP users with mixed/dense breasts (2.32; 1.56–3.46) with no association in SEP users with fatty breast (0.85; 0.33–2.20), whereas there was no difference in association with estrogen or CEP by MD (p value for interaction = 0.05).
Discussion
We found significantly positive associations between HRT use and MD, and breast cancer risk, respectively, limited to estrogen + progestin HRT regimens. We also found that the effect of HRT use on breast cancer risk was in part, by around 10%, mediated by MD. Finally, the overall adverse effect of HRT on breast cancer was greater in women with higher MD.
We found that ever users of postmenopausal HRT had 16% greater risk of having mixed/dense MD, with the highest risk 24% in current HRT users at enrollment, in line with other studies [10,11,12,13, 15, 24]. In this study, self-reported HRT use at cohort baseline in 1993–1997 was linked to MD assessed at screening on average 1 year after cohort baseline. We have furthermore found a 6% increase in MD per each 5-year use of HRT and a 6% reduction in MD after each 5-year cessation of HRT use in agreement with the majority of the studies on changes in MD after HRT cessation [34, 35], expect one who failed to show a relationship between time since last HRT use and MD [11]. Aiello et al., with data on long-term cessation over 10 years in 39,296 US women, found the significant decrease of MD after 1 year since cessation, and complete reversal of MD to levels before HRT use after 2 years [34]. Four studies have examined the effects of short-term HRT cessation on MD, all finding typically increased MD in women who continued using HRT, and unchanged or decreased MD in those who discontinued use after 2–3 weeks [35, 36], 2 months [37], or 2 years [38]. All these results, along with ours, provide strong evidence for the dynamic association between HRT use and MD, increasing with initiation and prolonged use, and decreasing after cessation of use.
Our study suggested there was a significant increase in MD with estrogen + progestin HRT regimens, possibly stronger for SEP (34%) than CEP (21%), while there was no statistically significant association with estrogen use, although positive association of 8% was detected. Number of the studies found that increase in MD is more pronounced in CEP than in SEP and estrogen users [10, 39,40,41,42]. Our result corroborate those by Greendale et al. who found, in a randomized trial of 307 US women, 7–13 fold increase in MD in women using estrogen + progestin regimens as compared to unopposed estrogen [39]. Similarly, Marugg et al. has found, in 81 Dutch women after 1–2 years, increased MD in 31% of estrogen + progestin users, and in 8.7% of unopposed estrogen users [10]. Lundstrom et al. has found in 175 Swedish women over 2 years greater increase in MD in CEP (52%) than in SEP (13%) and estrogen (18%) users [40]. Topal et al. has in 113 Turkish women, after 14 months, detected MD increase in 38.3% of the CEP users, 12.5% of cyclic estrogen–progestin users, and only 2.7% of estrogen only users [41]. Similarly, Sendag et al. in 216 women, during 20 month of follow-up, detected MD increase in 31.1% women using continuous combination therapy and only in 3.9% of the women using estrogen only [42]. However, Erel et al. detected highest (35%) MD increase CEP users and 22% increase in estrogen only and 19% in cyclic estrogen–progestin users [43], while Aiello et al. found that current estrogen–progestin users had a 98%, whereas current estrogen users had 71% greater odds of having dense breasts [34]. Different HRT regimens may cause different rates of MD change, but evidence in which regimens are most relevant for breast density is inconsistent.
We found a strong positive association between estrogen–progestin HRT regimen and breast cancer, in agreement with vast evidence [3,4,5].We detected 87% increase in postmenopausal breast cancer associated with current HRT use, which is somewhat lower than the RR of 2.22 (1.80–2.75) reported by Tjonneland et al., who in the same cohort, linked HRT use to breast cancer, but with a shorter follow-up, until 2000 [4]. Similarly, another Danish study by Stahlberg et al. based on Danish Nurse Cohort recruited in 1993, found remarkably similar effects of current HRT use (2.42; 1.81–3.26) on breast cancer until 2000 [5]. In current study with follow-up until 2012, the effect of HRT collected at cohort baseline (1993–1997) would be expected to be lower compared to estimates from Tjonneland et al. [4]. and Stahlberg et al., [5], due to increasing exposure misclassification with increasing time since exposure assessment, along with decline in number of HRT users in this period [44]. Finally, we found relevance of estrogen + progestin regimens, which was most pronounced for CEP and less for SEP, in agreement to previous evidence [3,4,5].
We found that increase in breast cancer risk of 56 and 87% related to ever and current HRT use, respectively, attenuated slightly, by 14 and 13%, respectively, after adjustment for MD, by similar magnitude for SEP and CEP (Table 3). By performing formal mediation analyses, we found that the proportion of association of ever and current HRT use with breast cancer mediated by MD was 11 and 10%, respectively (Table 4) and statistically significant. This implies that HRT use affects breast cancer risk partially via MD, and that this proportion was between 4 and 30% for ever-, and 4 and 21% for current use. This result is in agreement to that of Boyd et al., who in a nested-case–control study from a Canadian screening trial, found that an OR for association of current HRT use with breast cancer of 1.26 (1.00–1.59) attenuated by 25%–1.19 (0.94–1.51) after adjustment for MD [15]. However, Boyd et al. did not perform formal mediation analyses and concluded that MD was not a mediator of association between HRT and breast cancer, but rather that MD and HRT exerted independent effects on breast cancer. More recently, Rice et al. however, in agreement with ours, reported that MD mediated effect of current HRT use on breast cancer risk by 22%, which was statistically significant [16]. Finally, the most recent study showed that short-term (1-year) effect of estrogen plus progestin daily use, corresponding to CEP in our data, on breast cancer risk was completely mediated by change in MD [17]. Thus, our study corroborates previous evidence that MD acts as mediator of an association between HRT and breast cancer, although our proportion mediated by MD is lower than that reported in other studies. This is possibly explained by our definition of MD as binary variable, which is a drastic simplification of a finer measure, such as percent MD, used in previous studies. This simplification of MD to a binary variable introduced measurement error, which in turn biases the indirect effect and thus mediated proportion towards null. Hence, the real mediated proportion of an association between HRT and breast cancer mediated by biological MD is likely higher than that presented in this study.
Risk of breast cancer in HRT users differed according to MD and was generally higher in women with mixed/dense than with fatty MD (Table 5). Ever users of HRT with fatty breasts had 24% higher, while those with mixed/dense breasts had 86% higher breast cancer risk (p value for interaction = 0.22). The difference was even stronger in current HRT users, where women with fatty breasts had 37% and women with mixed/dense breasts had 94% increased risk of breast cancer (p = 0.15). This is in agreement with results by Hou et al., which directly assessed the effect modification of association between HRT and breast cancer by MD, though in American women with different racial composition from Danish women [7]. Hou et al. found that the HRT use was associated with the highest breast cancer risk in women with extremely dense breasts (OR range for ever HRT use: 1.22–1.49), with no excess risk in women with almost entirely fat breasts [7]. Similarly, a case–control study by Boyd et al. which studied the association between percent MD (PMD) and breast cancer by HRT use, reported 6% higher MD in HRT users (compared to never users) who were breast cancer cases, and 1.6% in controls using HRT as compared to never users (p = 0.001) [6]. Kerlikowske et al. concluded that women with high breast density (comparing BI-RADS density 4–2, comparable to our mixed/dense category) have the added increased risk of breast cancer when taking HRT (2.02; 1.35–1.68), as compared to those not taking HRT (1.51; 1.35–1.68) [6]. Furthermore, Kerlikowske et al. found excess breast cancer risk with both estrogen (1.99; 1.61–2.46) and estrogen + progestin (2.09; 1.79–2.43) use [8], while we detected no association with estrogen, positive and similar associations with CEP in both groups, and differential associations with SEP by MD, that seemed limited to women with dense breasts. Yaghjyan et al. found that women with dense breasts (comparing percent density > 50% vs. < 10%) who were current users of HRT, had significantly higher risk of breast cancer (OR: 5.34; 95% CI 3.36–8.49) than previous (2.69; 1.32–5.49) or never (2.57; 1.18–5.60) HRT user [45].
Several biological mechanisms behind association of HRT use and MD have been suggested. Previous studies showed the association between serum estradiol level and MD changes in women who used HRT, which support proliferative effect of estrogen on breast epithelial cell [46, 47]. Similarly, breast epithelial cell proliferations were observed in menstruating women due to high levels of estrogen and progestin [48]. In line with our findings, it has been shown that use of estrogen + progestin combination is associated with higher level of breast epithelial cell proliferation than in estrogen alone and non-HRT users [46]. Breast epithelial cell proliferation is also known as epithelial hyperplasia, defined as abnormal growth and accumulation of cells that line the ducts or the lobules in the breasts, which may lead to increased breast cancer risk [49]. Therefore, higher levels of epithelial hyperplasia associated with estrogen + progestin combination use likely explain increased MD and breast cancer risk with this HRT regimen, as compared to estrogen alone and no HRT use [50, 51]. Thus it is plausible that some of the increased risk of breast cancer related to HRT use is mediated via increase in MD by HRT use, likely estrogen + progestin use, as suggested by our results. In addition, a recent study suggests that high MD is associated with a more aggressive breast cancer tumors type, especially in women taking estrogen + progesterone HRT regimen [45].
This study benefited from an ability, unique to Denmark, to link breast density data from Copenhagen mammography register to a large prospective Danish DCH cohort, with detailed information on HRT and breast cancer risk factors, and facilitate the data to study whether MD mediates the effect of HRT on breast cancer risk, explored in few other studies to date [15,16,17]. DCH data on HRT use and breast cancer risk factors were collected independently of and before mammography screening, limiting the possibility of recall or information bias. HRT data have been validated and utilized before in an earlier study in this cohort linking HRT to breast cancer [4]. However, a limitation of this study is that we have assessed HRT use only at the enrollment in 1993–1997, and thus we cannot account for change in HRT use status during the follow-up, and corresponding exposure misclassification is likely to bias effect estimates towards zero. We utilized a Danish dichotomized MD score as mixed/dense or fatty breasts, as no other measure of MD was available, in contrast to a variety of measures of MD used in related studies, including BI-RADS or percent MD. However, this dichotomous outcome has been utilized in earlier studies of MD and breast cancer mortality [23], early childhood BMI and MD [25], active tobacco smoking and MD [26], alcohol use and MD [52], and air pollution and MD [27], and showed an expected doubling of the breast cancer risk in women with mixed/dense compared to women with fatty breasts, in agreement with Boyd et al. [1] Furthermore, we have successfully validated dichotomous MD measure and found good agreement with BI-RADS [23]. A weakness of the study is the small sample size for HRT regimens, as well as lack of data on history of breast cancer, which is an important determinant of MD as well as breast cancer risk. Finally, the major weakness of the study is the lack of data on MD change during follow-up, which would facilitate the optimal design to study whether MD mediates the association between HRT use and breast cancer risk, but this was however not possible neither in the other studies on the topic [15, 16]. Thus, we cannot exclude the possibility that the larger effect of HRT on breast cancer in the mixed/dense group may be due to the fact that these are the women who experienced a higher MD in response to HRT, and other studies need to address this. Considering the lack of data on MD change, and utilization of crude measure of MD, both of which would likely bias our results towards zero, our findings of 10–11% of the association of HRT and breast cancer being explained by MD are likely underestimated. This confirms that, despite limitations in our design, we contribute with novel evidence that MD is a likely on a biological pathway from HRT use to increased breast cancer risk, but also that other mechanisms are at play.
Conclusion
We found significantly positive associations between HRT use and MD, as well as between HRT and breast cancer risk, which seemed limited to estrogen + progestin HRT regimens. We found that the association between HRT use and breast cancer risk was in part, by around 10%, mediated by MD. This suggests that MD is a mediator of certain biological pathways on HRT-related breast cancer development, and also that other mechanisms are at play. Finally, the association between HRT and breast cancer risk seemed more pronounced in women with dense breasts.
Abbreviations
- HRT:
-
Hormone replacement therapy
- MD:
-
Mammographic density
- DCH:
-
Danish diet, cancer and health cohort
- OR:
-
Odds ratio
- HR:
-
Hazard ratio
- CI:
-
Confidence intervals
- BMI:
-
Body mass index
- CEP:
-
Continuous estrogen + progestin
- SEP:
-
Sequential estrogen + progestin
References
Boyd NF, Martin LJ, Yaffe MJ, Minkin S (2011) MD and breast cancer risk: current understanding and future prospects. Breast Cancer Res 13:223. https://doi.org/10.1186/bcr2942
McCormack V, dos Santos Silva I (2006) Breast density and parenchymal patterns as markers of breast cancer risk: a meta-analysis. Cancer Epidemiol Biomarkers Prev 15:1159–1169
Chlebowski RT, Hendrix SL, Langer RD, Stefanick ML, Gass M, Lane D, Rodabough RJ, Gilligan MA, Cyr MG, Thomson CA, Khandekar J, Petrovitch H, McTiernan A; WHI Investigators (2003) Influence of estrogen plus progestin on breast cancer and mammography in healthy postmenopausal women: the Women’s Health Initiative Randomized Trial. JAMA 289:3243–3253
Tjonneland A, Christensen J, Thomsen BL, Olsen A, Overvad K, Ewertz M, Mellemkjaer L (2004) Hormone replacement therapy in relation to breast carcinoma incidence rate ratios: a prospective Danish cohort study. Cancer 100:2328–2337
Stahlberg C, Pedersen AT, Lynge E, Andersen ZJ, Keiding N, Hundrup YA, Obel EB, Ottesen B (2004) Increased risk of breast cancer following different regimens of hormone replacement therapy frequently used in Europe. Int J Cancer 109:721–727
Boyd NF, Melnichouk O, Martin LJ, Hislop G, Chiarelli AM, Yaffe MJ, Minkin S (2011) Mammographic density, response to hormones, and breast cancer risk. J Clin Oncol 29:2985–2992. https://doi.org/10.1200/JCO.2010.33.7964
Hou N, Hong S, Wang W, Olopade OI, Dignam JJ, Huo D (2013) Hormone replacement therapy and breast cancer: heterogeneous risks by race, weight, and breast density. J Natl Cancer Inst 105:1365–1372. https://doi.org/10.1093/jnci/djt207
Kerlikowske K, Cook AJ, Buist DS, Cummings SR, Vachon C, Vacek P, Miglioretti DL (2010) Breast cancer risk by breast density, menopause, and postmenopausal hormone therapy use. J Clin Oncol 28:3830–3837. https://doi.org/10.1200/JCO.2009.26.4770
NHS choices (2016). Hormone replacement therapy (HRT). https://www.nhs.uk/conditions/hormone-replacement-therapy-hrt/types/. Accessed 09 Jan 2018
Marugg RC, van der Mooren MJ, Hendriks JHCL., Rolland R, Ruijs SHJ (1997) Mammographic changes in postmenopausal women on hormonal replacement therapy. Eur Radiol 7:749–755
Persson I, Thurfjell E, Holmberg L (1997) Effect of estrogen and estrogen–progestin replacement regimens on mammographic parenchymal density. J Clin Oncol 15:3201–3207
Sala E, Warren R, McCann J, Duffy S, Luben R, Day N (2000) High-risk mammographic parenchymal patterns, hormone replacement therapy and other risk factors: a case control study. Int J Epidemiol 29:629–636
Marchesoni D, Driul L, Ianni A, Fabiani G, Della Martina M, Zuiani C, Bazzocchi M (2006) Postmenopausal hormone therapy and mammographic breast density. Maturitas 53:59–64
Martin LJ, Minkin S, Boyd NF (2009) Hormone therapy, mammographic density, and breast cancer risk. Maturitas 64:20–26. https://doi.org/10.1016/j.maturitas.2009.07.009
Boyd NF, Martin LJ, Li Q, Sun L, Chiarelli AM, Hislop G, Yaffe MJ, Minkin S (2006) Mammographic density as a surrogate marker for the effects of hormone therapy on risk of breast cancer. Cancer Epidemiol Biomarkers Prev 15:961–966
Rice MS, Bertrand KA, VanderWeele TJ, Rosner BA, Liao X, Adami HO (2016) Mammographic density and breast cancer risk: a mediation analysis. Breast Cancer Res 18:1–94. https://doi.org/10.1186/s13058-016-0750-0
Byrne C, Ursin G, Martin CF, Peck JD, Cole EB, Zeng D, Kim E, Yaffe MD, Boyd NF, Heiss G, McTiernan A, Chlebowski RT, Lane DS, Manson JE, Wactawski-Wende J, Pisano ED (2017) Mammographic density change with estrogen and progestin therapy and breast cancer risk. J Natl Cancer Inst 1:109. https://doi.org/10.1093/jnci/djx001
Yaghjyan L, Colditz GA, Rosner B, Tamimi RM (2015) Mammographic breast density and breast cancer risk: interactions of percent density, absolute dense, and non-dense areas with breast cancer risk factors. Breast Cancer Res Treat 150:181–189. https://doi.org/10.1007/s10549-015-3286-6
Tjonneland A, Olsen A, Boll K, Stripp C, Christensen J, Engholm G, Overvad K (2007) Study design, exposure variables, and socioeconomic determinants of participation in diet, cancer and health: a population-based prospective cohort study of 57,053 men and women in Denmark. Scand J Public Health 35:432–441
Vejborg I, Olsen AH, Jensen MB, Rank F, Tange UB, Lynge E (2002) Early outcome of mammography screening in Copenhagen 1991–99. J Med Screen 9:115–119
Hodge R, Hellmann SS, Euler-Chelpin Mv, Vejborg I, Andersen ZJ (2014) Comparison of Danish dichotomous and BI-RADS classifications of mammographic density. Acta Radiol Short Rep 3:2047981614536558
American College of Radiology (2003). Breast imaging reporting and data system® (BI-RADS®) 4. Reston: American College of Radiology
Winkel RR, von Euler-Chelpin M, Nielsen M, Diao P, Nielsen MB, Uldall WY, Vejborg I (2015) Inter-observer agreement according to three methods of evaluating mammographic density and parenchymal pattern in a case control study: impact on relative risk of breast cancer. BMC Cancer 15:274
Olsen AH, Bihrmann K, Jensen MB, Vejborg I, Lynge E (2009) Breast density and outcome of mammography screening: a cohort study. Br J Cancer 100:1205–1208
Andersen ZJ, Baker JL, Bihrmann K, Vejborg I, Sørensen TIA, Lynge E (2014) Birth weight, childhood BMI and height in relation to mammographic density and breast cancer: register based cohort study. Breast Cancer Res 16:R4
Jacobsen KK, Lynge E, Vejborg I, Tjønneland A, von Euler-Chelpin M, Andersen ZJ (2016) Cigarette smoking and mammographic density in the Danish diet, cancer and health cohort. Cancer Causes Control 27:271–280
Huynh S, von Euler-Chelpin M, Raaschou-Nielsen O, Hertel O, Tjønneland A, Lynge E, Vejborg I, Andersen ZJ (2015) Long-term exposure to air pollution and mammographic density in the Danish diet, cancer and health cohort. Environ Health 14:31. https://doi.org/10.1186/s12940-015-0017-8
Gjerstorff ML (2011) The Danish cancer registry. Scand J Public Health 39:42–45
Pedersen CB (2011) The Danish civil registration system. Scand J Public Health 39:22–25
Barroscorresponding AD, Hirakata VN (2003) Alternatives for logistic regression in cross-sectional studies: an empirical comparison of models that directly estimate the prevalence ratio. BMC Med Res Methodol 3:21. https://doi.org/10.1186/1471-2288-3-21
Lange T, Vansteelandt S, Bekaert M (2012) A simple unified approach for estimating natural direct and indirect effects. Am J Epidemiol 176(3):190–195
Lange T, Hansen KW, Sørensen R, Galatius S (2017). Applied mediation analyses: a review and tutorial. Epidemiol Health https://doi.org/10.4178/epih.e2017035
Steen J, Tom Moerkerke LB, Vansteelandt S (2017) An R package for flexible mediation analysis using natural effect models. J Stat Softw 76(11):1–46
Aiello EJ, Buist DS, White E (2006) Do breast cancer risk factors modify the association between hormone therapy and mammographic breast density? (United States). Cancer Causes Control 17:1227–1235
Colacurci N, Fornaro F, De Franciscis P, Mele D, Palermo M, del Vecchio W (2001) Effects of a short-term suspension of hormone replacement therapy on mammographic density. Fertil Steril 76:451–455
Harvey JA, Pinkerton JV, Herman CR (1997) Short-term cessation of hormone replacement therapy and improvement of mammographic specificity. J Natl Cancer Inst 89:1623–1625
Rutter CM, Mandelson MT, Laya MB, Seger DJ, Taplin S (2001) Changes in breast density associated with initiation, discontinuation, and continuing use of hormone replacement therapy. JAMA 285:171–176
Buist DS, Anderson ML, Reed SD, Aiello Bowles EJ, Fitzgibbons ED, Gandara JC, Seger D, Newton KM (2009) Short-term hormone therapy suspension and mammography recall: a randomized trial. Ann Intern Med 150:752–765
Greendale GA, Reboussin BA, Sie A, Singh HR, Olson LK, Gatewood O, Bassett LW, Wasilauskas C, Bush T, Barrett-Connor E (1999) Effects of estrogen and estrogen–progestin on mammographic parenchymal density. Ann Intern Med 130:262–269
Lundström E, Wilczek B, von Palffy Z, Söderqvist G, von Schoultz B (1999) Mammographic breast density during hormone replacement therapy: differences according to treatment. Am J Obstet Gynecol 181:348–352
Topal NB, Ayhan S, Topal U, Bilgin T (2006) Effects of hormone replacement therapy regimens on mammographic breast density: the role of progestins. J Obstet Gynaecol Res 32:305–308
Sendag F, Coşan Terek M, Ozşener S, Oztekin K, Bilgin O, Bilgen I, Memiş A (2001) Mammographic density changes during different postmenopausal hormone replacement therapies. Fertil Steril 76:445–450
Erel CT, Esen G, Seyisoglu H, Elter K, Uras C, Ertungealp E, Aksu MF (2001) Mammographic density increase in women receiving different hormone replacement regimens. Maturitas 40:151–157
Von Euler-Chelpin M (2011) Breast cancer incidence and use of hormone therapy in Denmark 1978–2007. Cancer Causes Control 22:181–187
Yaghjyan L, Tamimi RM, Bertrand KA, Scott CG, Jensen MR, Pankratz VS, Brandt K, Visscher D, Norman A, Couch F, Shepherd J, Fan B, Chen YY, Ma L, Beck AH, Cummings SR, Kerlikowske K, Vachon CM (2017) Interaction of mammographic breast density with menopausal status and postmenopausal hormone use in relation to the risk of aggressive breast cancer subtypes. Breast Cancer Res Treat 165:421–431. https://doi.org/10.1007/s10549-017-4341-2
Santen RJ, Yue W, Naftolin F, Mor G, Berstein L (1999) The potential of aromatase inhibitors in breast cancer prevention. Endocr Relat Cancer 6:235–243
Hofseth LJ, Raafat AM, Osuch JR, Pathak DR, Slomski CA, Haslam SZ (1999) Hormone replacement therapy with estrogen or estrogen plus medroxyprogesterone acetate is associated with increased epithelial proliferation in the normal postmenopausal breast. J Clin Endocrinol Metab 84:4559–4565
Soderqvist G, Isaksson E, von Schoultz B, Carlstrom K, Tani E, Skoog L (1997) Proliferation of breast epithelial cells in healthy women during the menstrual cycle. Am J Obstet Gynecol 176:123–128
American Cancer Society. Ductal or lobular hyperplasia (2015) Hyperplasia of the Breast (Ductal or Lobular)
Magnusson C, Baron JA, Correia N, Bergstrom R, Adami HO, Persson I (1999) Breast cancer risk following long-term oestrogen- and oestrogen-progestin-replacement therapy. Int J Cancer 81:339–344
Olsson HL, Ingvar C, Bladström A (2003) Hormone replacement therapy containing progestins and given continuously increases breast carcinoma risk in Sweden. Cancer 97:1387–1392
Jacobsen KK, Lynge E, Tjønneland A, Vejborg I, von Euler-Chelpin M, Andersen ZJ (2017) Alcohol consumption and mammographic density in the Danish diet, cancer and health cohort. Cancer Causes Control 2812:1429–1439. https://doi.org/10.1007/s10552-017-0970-3
Funding
Funding was provided by Syddansk Universitet (DK), Department of Public Health.
Author information
Authors and Affiliations
Contributions
All authors made substantial contributions to conception and design, analysis, and interpretation of data, and critical review of the manuscript. SA secured funding, interpretation of the results, and wrote the manuscript. ZJA carried out the design of the study, performed the statistical analyses, and the revision of the manuscript. TL performed statistical analyses of mediation, and helped rewrite the manuscript substantially during the revision process. AA helped get the funding for the study, advised on epidemiological methods, and was involved in drafting the manuscript. SH helped with literature review and revising the manuscript. IV, MEC, EL, and AT have been involved in revising the manuscript critically for important intellectual content.
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no competing interests.
Ethics approval and consent to participate
The study was entirely based on register data and was approved by the Danish Data Inspection Agency (2014-41-3168). Informed consent was obtained from all participants included in the study.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Azam, S., Lange, T., Huynh, S. et al. Hormone replacement therapy, mammographic density, and breast cancer risk: a cohort study. Cancer Causes Control 29, 495–505 (2018). https://doi.org/10.1007/s10552-018-1033-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10552-018-1033-0