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Cancer Causes & Control

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Open Access 01.07.2010 | Original paper

Cancer risk in DES daughters

verfasst von: Janneke Verloop, Flora E. van Leeuwen, Theo J. M. Helmerhorst, Hester H. van Boven, Matti A. Rookus

Erschienen in: Cancer Causes & Control | Ausgabe 7/2010

Abstract

Objective

We examined long-term risk of cancer in women exposed to diethylstilbestrol (DES) in utero.

Methods

A total of 12,091 DES-exposed women in the Netherlands were followed prospectively from December 1992 till June 2008. Cancer incidence was assessed through linkage with the Dutch pathology database (PALGA) and the Netherlands Cancer Registry and compared with the Dutch female population.

Results

A total of 348 medically verified cancers occurred; median age at end of follow-up was 44.0 years. No overall increased risk of cancer was found (standardized incidence ratio [SIR] = 1.01; 95% confidence interval [CI] = 0.91, 1.13). The risk of clear cell adenocarcinoma of the vagina and cervix (CCA) was statistically significantly increased (SIR = 24.23; 95% CI = 8.89, 52.74); the elevated risk persisted above 40 years of age. The risk of melanoma diagnosed before age 40 was increased (SIR = 1.59; 95% CI = 1.08, 2.26). No excess risks were found for other sites, including breast cancer.

Conclusions

Except for an elevated risk of CCA, persisting at older ages, and an increased risk of melanoma at young ages, we found no increased risk of cancer. Longer follow-up is warranted to examine cancer risk at ages when cancer occurs more frequently.

Supplementary material 1 (DOCX 15 kb)

Electronic supplementary material

The online version of this article (doi:10.1007/s10552-010-9526-5) contains supplementary material, which is available to authorized users.

Introduction

Diethylstilbestrol (DES) is a synthetic estrogen that was prescribed to several millions of pregnant women worldwide from the late 1940s to the early 1970s, in order to prevent miscarriages and other pregnancy complications [1, 2]. Among women exposed prenatally to the drug, several adverse health effects have been observed before age 30, such as clear cell adenocarcinoma of the vagina and cervix (CCA) and reproductive tract abnormalities [3, 4]. These findings raised concern about potential other long-term health effects. In prenatally DES-exposed mice, similar genital tract alterations were found, including vaginal adenocarcinomas and adenosis [5]. In addition, DES-exposed mice developed uterine tumors [5].

Molecular mechanisms are still unclear, but results from animal studies suggest that DES exposure in utero might lead to a persistent overexpression of protooncogenes that are associated with increased proliferation (c-jun, c-fos, c-myc) or decreased apoptosis (bcl-2, bcl-x), resulting in unregulated cell growth and carcinogenesis (see review [6]). In addition, growth factor genes (like EGF, TGF-α) have been shown to be overexpressed after in utero exposure to DES [7]. Also other estrogen responsive genes, like the lactoferrin gene, are induced by DES exposure (see review [6]).

In humans, long-term cancer risk in DES daughters has only been studied in the National Cancer Institute (NCI) DES Follow-up Study [8]. With a median age of 49 at the end of follow-up, this study revealed no excess risks for cancer except for CCA and breast cancer after age 40. Risks for squamous cell cervical cancer and melanoma could not be evaluated, because agreement between self-reported cancers and medical verification was poor and medical verification data were incomplete.

We report on the first European study of cancer risk in a large cohort of 12,091 DES-daughters, with long-term and complete follow-up. Cancer incidence was ascertained through linkages with the population-based Netherlands Cancer Registry (NCR) and the Dutch nationwide pathology database (PALGA) [9]. Since all cancers were medically verified, this study is the first one to report on the risks of squamous cell cervical cancer and melanoma.

Materials and methods

Study population

The DES-net project is a nationwide prospective follow-up study of 12,091 Dutch DES daughters, identified through the registry of the Netherlands DES Center. This registry was established in 1992, in order to deal with future health claims. All DES daughters were advised to register, both individuals with and without health problems at time of registration. Documented DES exposure was not necessary at the time of registration. Median age of the DES daughters at time of registration was 29.

From March 2000 till December 2004, 13,113 women received a 16-page mailed questionnaire on risk factors for hormone-related cancers and medical history (Fig. 1). The questionnaire included an informed consent form to grant permission for abstracting data from their medical records and population-based disease registries. Also, women were asked to provide a copy of their documented DES exposure. In case no copy was available, the mother was asked to give permission to have her medical record traced by the researchers. Non-responders were sent a reminder after 2 months and a second reminder after 6 months. The final response rate to the questionnaire was 60%.

The study was approved by the Medical Ethical Committee of the Netherlands Cancer Institute and the Surveillance Committees of PALGA and the NCR.

Assessment of cancer incidence and death

Cancer incidence was assessed through linkage with PALGA and NCR, which both have nationwide coverage since 1989 and 1991, respectively. The Surveillance Committees granted us permission to link both responders and non-responders under strict privacy procedures, while we excluded 202 women who had refused. Linkage information was complete for 12,251 women (Fig. 1). After linkage, information was provided on date of diagnosis, type of tumor, and morphology. All tumors were coded according to the International Classification for Diseases, 10th revision. Vital status was obtained by linkage with the Dutch Office of Death Registry (CBG), updated till October 2007. A total of 128 women died during follow-up, of whom 54 died of cancer.

Classification of DES exposure for women with questionnaire data

Documented DES exposure was available for 881 subjects (Table 2). For the majority of our subjects, no documented DES exposure was available. For sensitivity analyses, we used as surrogates of DES exposure medically verified DES-related reproductive tract abnormalities (such as adenosis, squamous cell metaplasia occurring in the vagina or in an extensive area of the portio (more than 75%), cox comb, vaginal ridges, T-shaped uterus). Adenosis and squamous cell metaplasia were ascertained by colposcopy.

Furthermore, we assigned women to ‘suspected DES-exposed’ in case women reported in the questionnaire threatened or prior bleeding or prior pregnancy loss as indications for DES usage by their mother, since it has been observed that these indications are strongly associated with documented DES exposure [10]. Finally, we distinguished a category of women who had been frequently screened (3 or more cervical Pap smears before age 30 or 2 or more vaginal smears before age 50), with exclusion of diagnostic smears. Pap smears before age 30 occur very infrequently in the general population as the Dutch national screening surveillance program starts at age 30. In DES daughters, however, Pap smears before age 30 do occur since they are advised to have a yearly gynecological exam during the first 5 years of DES surveillance, including vaginal and cervical smears. Therefore, having had 3 or more Pap smears before age 30 was considered a valid indicator of suspected DES exposure in the Netherlands.

Validation of DES exposure for women with questionnaire data

For 115 subjects, we compared self-reported DES exposure with the information in prenatal records in four hospitals with preserved historical medical archives.

Statistical analyses

Women with cancer diagnosed before the start of follow-up (n = 160) were excluded from analyses, among whom were 53 patients with CCA. A total of 12,091 women were included in the analyses. Follow-up started at the date of registration at the DES Center and ended on June 30, 2008, the date of first cancer diagnosis, or death, whichever came first. We excluded 2 second primary tumors that were probably related to cancer treatment (1 squamous cell cervical cancer after treatment for cervical adenocarcinoma; 1 squamous cell vaginal cancer after treatment for vaginal adenocarcinoma).

Standardized Incidence Ratio’s (SIRs) were calculated to compare the observed cases in our study with the expected number in the general population, based on age-, sex-, and calendar period-specific incidence rates from the NCR. The 95% confidence intervals (95% CI) were calculated assuming a Poisson distribution [11].

We also calculated risks for women stratified according to the availability of questionnaire data, age, type of DES confirmation, medical indication for DES use, parity, maternal age of DES mother, education, and duration of index pregnancy.

As reference for the stage distribution of melanoma, we used the age-specific stage distribution in the general female population in the period 2003–2007.

To test for heterogeneity in the SIRs between strata, the chi-square distribution was applied [11].

We used SPSS statistical software (SPSS Inc., Chicago, IL).

Results

The majority of the DES daughters were born between 1961 and 1970, with no differences between women with and without a questionnaire (Table 1). Ninety-three percent of the women registered in 1992. The median age at the end of follow-up was 44.3 years in the questionnaire group and 43.3 years in the group without questionnaire.

Table 1

Baseline characteristics of Dutch DES daughters (n = 12,091) according to type of response

	Questionnaire (n = 7,589)		Without questionnaire (n = 4,502)
	No. of women	%	No. of women	%
Year of birth
≤1955	968	13	557	12
1956–1960	1,731	23	840	19
1961–1965	1,852	24	1,095	24
1966–1970	2,139	28	1,280	28
>1970	899	12	730	16
Age at end of follow-up
<40	2,103	28	1,425	32
40–49	3,853	51	2,231	50
50+	1,633	22	846	19
Year of registration
1992	7,052	93	4,139	92
1993–1995	304	4	244	5
1996–2000	200	3	65	1
2001–2005	33	0	54	1

Twelve percent of the DES daughters with questionnaire data had documented DES exposure, 22% had medically verified DES-associated reproductive tract abnormalities, and 26% had a history of frequent vaginal or cervical screening (Table 2). Habitual abortion was the most frequently self-reported medical indication for DES usage by the mother (50%), followed by threatened abortion (25%) or the combination of both (17%). DES daughters were more often highly educated (college or university) compared to women in the Dutch female population (38 and 25%, respectively, reference data not in the table). Twenty-eight percent of the women had overweight or were obese (compared to 34% in the general female population). Thirty-three percent of the DES daughters above 40 years of age (as a proxy for the end of a woman’s fertile lifespan) were nulliparous, compared to 17% of the Dutch population in the same age category (reference data not shown).

Table 2

Baseline characteristics of DES daughters with questionnaire data

	Questionnaire (n = 7,589)
	No. of women	%
DES confirmation
Medical file mother	881	12
DES-related reproductive tract abnormalities	1,648	22
History of frequent^a vaginal screening (before age 50) or frequent^a cervical screening (before age 30)	1,983	26
No information available	3,077	40
Medical indication DES use mother
Both threatened and habitual abortion	1,310	17
Threatened abortion only	1,902	25
Habitual abortion only	3,827	50
Diabetes	9	0
Premature delivery, uterus problems	34	0
Other problems index pregnancy	36	0
History of pregnancy problems (other than abortion)	153	2
No obvious medical indication (prevention)	94	1
Unknown	224	3
Highest educational level
Primary school	952	13
Secondary school	3,617	48
College or university	2,846	38
Unknown or missing	174	2
Body mass index, kg/m²
<20	939	12
20–24	4,336	57
25–29	1,571	21
30+	557	7
Unknown or missing	186	2
Parity^b
Yes	1,360	66
No	680	33
Unknown or missing	34	2
Maternal age (DES mother)
<25	1,141	15
25–29	2,604	34
30–34	2,193	29
35+	1,481	20
Unknown or missing	170	2

^aFrequency of screening: two or more vaginal smears before age 50 or three or more cervical smears before age 30

^bAmong n = 2,074 women older than 40 at time filling in the questionnaire

Overall cancer risk was not increased in DES daughters compared to the general population (SIR = 1.01; 95% CI = 0.91, 1.13) (Table 3). The SIR for CCA of the vagina and cervix was statistically significantly increased (SIR = 24.23; 95% CI = 8.89, 52.74). No association for breast cancer was observed (SIR = 1.05; 95% CI = 0.90, 1.23). The risk of squamous cell cancer located in the vagina or cervix was non-significantly decreased compared to the general population (SIR = 0.64; 95% CI = 0.31, 1.17). A significantly decreased risk was observed for lung cancer (SIR = 0.54; 95% CI = 0.27, 0.96). No statistically significant findings were observed for other types of cancer. Similar cancer risks were seen in the subgroup of women with questionnaire data, except for a statistically significantly increased risk of cancer of the placenta (chorioncarcinoma) (SIR = 11.41; 95% CI = 1.38, 41.21) based on two cases. Risk was similar when we restricted the analyses to women with questionnaire data.

Table 3

Risk of cancer among DES daughters, for all women and women with questionnaire data only^a

Type of cancer	All participants n = 12,091 180,941 women-years				With questionnaire data only n = 7,589 113,845 women-years
Type of cancer	Obs	Exp	SIR	95% CI	Obs	Exp	SIR	95% CI
Total cancer^b,c	348	343.3	1.01	0.91–1.13	217	219.8	0.99	0.86–1.13
Breast	165	156.5	1.05	0.90–1.23	112	100.7	1.11	0.92–1.34
Cervix (all morphologies)	15	20.4	0.74	0.41–1.21	10	13.0	0.77	0.37–1.42
Vagina (all morphologies)	6	0.4	16.42	6.02–35.74	5	0.2	21.51	6.98–50.21
Vagina and cervix	21	20.8	1.01	0.63–1.55	15	13.2	1.13	0.64–1.87
Clear cell adenocarcinoma	6	0.3	24.23	8.89–52.74	5	0.2	32.02	10.38–74.71
Squamous cell carcinoma	10	15.7	0.64	0.31–1.17	7	10.0	0.70	0.28–1.44
Adenocarcinoma	4	3.8	1.06	0.29–2.71	3	2.4	1.25	0.26–3.65
Adenosquamous carcinoma	1	0.7	1.39	0.04–7.76	0	0.5
Vulva	2	1.6	1.27	0.15–4.59	1	1.0	0.99	0.03–5.51
Corpus uteri	9	7.1	1.27	0.58–2.41	4	4.5	0.88	0.24–2.26
Ovary^c	10	10.8	0.92	0.44–1.7	6	6.9	0.87	0.32–1.88
Placenta	2	0.3	7.10	0.86–25.64	2	0.2	11.41	1.38–41.21
Lung^c	11	20.4	0.54	0.27–0.96	5	13.2	0.38	0.12–0.89
Melanoma^c	48	35.3	1.36	1.00–1.8	26	22.4	1.16	0.76–1.7
Colon, rectum, anus	15	17.6	0.85	0.48–1.41	9	11.2	0.80	0.37–1.53
Thyroid	6	6.5	0.92	0.34–2.01	4	4.11	0.97	0.26–2.49
Hodgkin lymphoma	3	3.6	0.84	0.17–2.47	1	2.2	0.45	0.01–2.53
Non-Hodgkin lymphoma, immunoproliferative disease	8	8.3	0.96	0.42–1.9	6	5.3	1.13	0.42–2.47
Brain	8	6.3	1.28	0.55–2.52	5	4.0	1.26	0.41–2.94
Leukemia	3	5.7	0.52	0.11–1.53	3	3.6	0.83	0.17–2.42

^aSIR, Standardized incidence ratio, defined as observed number of cancers compared to the expected number of cancers in the general population with the same age; 95% CI = 95% confidence interval based on a Poisson distribution, obs = observed number of cases; exp = expected number of cases

^b27 cancers included in total cancer rate but not included in table: Lip (1), Tongue (1), Mouth (2), Salivary glands (1), Stomach (3), Anus (1), Pancreas (2), Larynx (1), Trachea (1), Sarcoma (2), Skin, squamous cell (9), Mesothelioma (1), Kidney (1), Bladder (2), Eye (1), Central Nervous System (1), Plasma cell tumor (1), Unknown or ill defined (6)

^cEight secondary tumors were included: Lung (2), Sarcoma (1), Melanoma (1), Skin, squamous cell (1), Ovary (1), Central nervous system (1), Non-Hodgkin lymphoma (1)

Within the group with questionnaire data, we were able to stratify according to confirmation of DES exposure (Table 4). The risks of CCA and vagina cancer were strongly elevated in all strata, though the SIR estimates for CCA was highest in the group confirmed by medical file (SIR = 109.9; 95% CI = 12.3, 396.79). The observed events of melanoma occurred in two strata and both showed similarly elevated SIRs. The risk for breast cancer was highest in the group with the lowest level of DES confirmation (SIR = 1.94; 95% CI = 0.93, 3.57).

Table 4

Risk of cancer among DES daughters with questionnaire data by type of DES confirmation^a

	Medical file mother n = 881 13,152 women-years				DES-related reproductive tract abnormalities^b n = 1,648 24,637 women-years				DES Indication (habitual abortion or threatened abortion) n = 4,682 70,426 women-years				History of screening or no data available n = 378 5,630 women-years
	Obs	Exp	SIR	95% CI	Obs	Exp	SIR	95% CI	Obs	Exp	SIR	95% CI	Obs	Exp	SIR	95% CI	p-value
All types	16	20.7	0.77	0.44–1.26	50	46.1	1.09	0.81–1.43	133	141.7	0.94	0.79–1.11	18	11.3	1.59	0.94–2.51	0.22
Breast	7	9.2	0.76	0.31–1.57	23	21.3	1.08	0.69–1.62	72	65.1	1.11	0.87–1.39	10	5.2	1.94	0.93–3.57	0.11
Melanoma	0	2.5			7	4.9	1.44	0.58–2.98	19	14.0	1.36	0.82–2.13	0	1.1			0.13
Vagina/cervix CCA	2	0.02	109.9	12.3–396.79	2	0.03	58.96	7.13–212.87	1	0.1	10.39	0.26–57.87	0	0.01			<0.01
Vagina/cervix squamous cell	0	1.11			3	2.23	1.34	0.28–3.93	4	6.19	0.65	0.18–1.65	0	0.48			0.45
Ovary	1	0.6	1.62	0.04–9	1	1.41	0.71	0.02–3.94	4	4.5	0.88	0.24–2.26	0	0.4			0.85
Corpus uteri	0	0.3			1	0.8	1.21	0.03–6.75	2	3.1	0.64	0.08–2.31	1	0.3	3.77	0.1–20.97	0.43

^aSIR = Standardized incidence ratio defined as observed number of cancers compared to the expected number of cancers in the general population with the same age; 95% CI = 95% confidence interval based on a Poisson distribution; obs = observed number of cases; exp = expected number of cases; p-values were based on the χ² test for heterogeneity and two sided

^bDES-related abnormalities: 50% adenosis, 8% isolated squamous metaplasia, 42% anatomical malformations

When we compared self-reported DES exposure with the information in prenatal records DES exposure was confirmed in 53 records of the 70 subjects (76%), in 15 records neither DES nor other medication was recorded (21%), and in 2 records another drug was mentioned (3%) (Table 5).

Table 5

Validation of self-reported DES exposure in four hospitals with preserved historical medical archives

	Mother self-reported DES exposure, n = 115
No. medical file available	45	31%
Medical file mother available	70	61%
DES exposure confirmed in medical file
Yes	53	76%
No	15	21%
Other medicine reported	2	3%

Table 6 shows the association between DES exposure and risk of cancer stratified according to age at diagnosis. The risk of melanoma, diagnosed before age 40, was statistically significantly increased (SIR = 1.59; 95% CI = 1.08, 2.26), but no increased risk after age 40 was detected (Table 6). The elevated risk at young ages did not seem to be attributable to detection bias, because the stage distribution was comparable with the general population (χ² 1.94, p = 0.75 and χ² 5.59, p = 0.23, for ages <40 and 40+, respectively) (Table 1, supplement). CCA risk remained elevated at ages above 40 (SIR = 32.89; 95% CI = 3.98, 118.76). The decrease in lung cancer risk was most pronounced above 40 years of age, but based on eight cases only. For the other types of cancer, no differences between age strata were observed.

Table 6

Risk of cancer among DES daughters by age at diagnosis^a

Type of cancer	Attained age <40 years of age 119,394 women-years				Attained age ≥40 years of age 61,547 women-years
Type of cancer	Obs	Exp	SIR	95% CI	Obs	Exp	SIR	95% CI
All types	124	118.8	1.04	0.87–1.24	224	224.5	1.00	0.87–1.14
Breast	42	44.0	0.95	0.69–1.29	123	112.6	1.09	0.91–1.31
Melanoma	31	19.5	1.59	1.08–2.26	17	15.8	1.08	0.63–1.72
Vagina (all morph)	3	0.2	18.02	3.72–52.65	3	0.2	15.08	3.11–44.07
Cervix (all morph)	9	12.95	0.69	0.32–1.32	6	7.4	0.81	0.30–1.76
Vagina and cervix
CCA	4	0.2	21.41	5.81–54.82	2	0.1	32.89	3.98–118.76
Squamous cell	6	9.9	0.60	0.22–1.31	4	5.8	0.70	0.19–1.78
Placenta	2	0.3	7.75	0.94–27.99	0	0.02
Lung	3	3.2	0.94	0.19–2.75	8	17.2	0.46	0.20–0.92
Ovary	4	3.6	1.13	0.31–2.89	6	7.3	0.82	0.30–1.79
Corpus uteri	3	0.9	3.22	0.66–9.41	6	6.2	0.97	0.36–2.12

Four CCA patients were diagnosed in the age category 30–39 years and two CCA patients between the ages of 40–49 years (Table 2, supplement). The incidence rates for CCA in women aged 30–39 and 40–49 were 0.05 and 0.04 per 1,000 women-years, respectively. Among the five CCA patients with medical information, one case had a confirmed history of adenosis. One patient had a younger sister with CCA (no participant, diagnosed at age 23 and deceased at age 25). All CCA patients diagnosed prospectively were still alive at the end of our follow-up.

Discussion

In this first European cohort study of cancer risk in DES daughters, no overall increased cancer risk was observed compared to the general population. The risk of CCA remained increased after age 40. Neither overall breast cancer risk was increased, nor risk above age 40. We found an elevated risk of melanoma before age 40. The risk of lung cancer was decreased.

A unique feature of this study is the large study size and the almost complete long-term follow-up for cancer. Also, all cancers were medically verified. However, a drawback of our study is that the majority of participants had no documented DES exposure. Nevertheless, we think that the assumption is justified that the majority of our subjects was indeed exposed to DES, for the following reasons. First, in our validation study self-reported DES exposure was confirmed in 53 prenatal records (76%), whereas in 15 records neither DES nor any other medication was recorded (21%). It is still possible that in the latter cases DES was prescribed by the general practitioner rather than the gynecologist. In the Netherlands, pregnancies have always been under the surveillance of general practitioners or midwives. DES was also prescribed by general practitioners but their records are notoriously hard to trace. Therefore, we estimate that the misclassification with regard to DES exposure is probably higher than 3% but certainly lower than 24%. Second, stratification according to levels of confirmation of DES exposure did not result in different conclusions (Table 4), whereas more uncertainty about DES exposure might have led to more bias to the null. Finally, the proportion of women doubting their DES exposure was higher among women who did not respond to the questionnaire. Although, in general, the SIRs were slightly higher in the questionnaire group, these differences were not statistically significant (Table 3).

Furthermore, women may have registered at the Netherlands DES Center because of gynecological complaints, although women without health problems at time of registration were especially encouraged to register. Since we prospectively followed all women from time of registration, all cancer diagnoses prior to registration were not included in our analysis. However, our results might still be biased if health problems were related to future cancer risk (both bias to or away from zero). In a sensitivity analysis, we excluded the first follow-up years in the analyses, to adjust for signs and symptoms of disease at time of registration, with similar results.

It is possible that women enrolled into our cohort differ from the background population of DES daughters. For instance, with respect to breast cancer nulliparity might cause such selection bias. As expected, the proportion of nulliparous women in our cohort was higher than in the general population (33 vs. 17%, respectively) due to a higher prevalence of subfertility among DES daughters compared to the general population [4]. However, if women registered because of subfertility problems (median age at registration was 29.1 years), the proportion of nulliparous women might be too high, and as a result the risk of breast cancer in our cohort might be underestimated during premenopausal years (assuming that the risk of breast cancer is transiently increased after childbirth, [12]), and overestimated during postmenopausal years. To examine whether the SIR of 1.11 (95% CI: 0.92–1.34) for breast cancer overall was due to nulliparity, we conducted partially stratified analyses comparing strata of parous and nulliparous women with the total reference group. The SIR for breast cancer was 1.19 (95% CI: 0.93–1.49) for parous and 0.96 (95% CI: 0.66–1.35) for nulliparous women (data not shown), suggesting that a higher frequency of nulliparity did not explain our results.

Another limitation of our study design is the lack of an internal comparison group, which prevented us from adjusting for several risk factors for cancer. The stratified analyses among women with questionnaires showed no statistically significant differences in cancer risk between strata of parity, maternal age of DES mother, education, and duration of index pregnancy (data not shown). However, residual confounding might still occur, since the reference group could not be stratified by any confounder except age and birth cohort. In spite of this, our analyses suggest that these effects are small.

In contrast to our study, DES exposure in the NCI DES follow-up study was completely verified. However, incident cancer cases were obtained by mailed questionnaires and medical record retrieval for confirmation of self-reported cancer was incomplete.

With the limitations of our study kept in mind, we found a highly increased risk of CCA, although somewhat lower than found in the NCI DES follow-up study (SIR = 24.23; 95% CI = 6.02, 35.74 and SIR = 39.0; 95% CI = 15, 104, respectively) [8]. Our SIR estimate does not apply to ages below 30, which might partly explain the lower estimate. The CCA incidence rate of 0.05 per 1,000 exposed women aged 30–39 (based on four cases) was similar to the incidence rate of 0.03 per 1,000 in the NCI study (based on one case in the same age range) [8]. Our study shows that the CCA risk remained increased after age 40 (SIR = 32.89; 95% CI = 3.98, 118.76, incidence rate of 0.04 per 1,000, based on two cases). Recently, DES-associated CCA patients up to age 55 have been added to the Registry for Research on Hormonal Transplacental Carcinogenesis, and a possible increase in incidence at age ≥40 years has been suggested (http://obgyn.bsd.uchicago.edu/registry.html). The cumulative incidence rate for exposed women ages 30–44 years in our study was 0.8 per 1,000 women. Combined with the cumulative incidence rate in the Dutch CCA registry of 1.5 per 1,000 women before age 30 (personal communication Jos van Dijck, Comprehensive Cancer Centre East), we calculated an absolute risk of 2.3 CCA cases per 1,000 DES daughters by age 44 (compared to 1.6 per 1,000 DES daughters by age 39 in the NCI DES follow-up study).

Trichopoulos et al. hypothesized that prenatal factors associated with high endogenous estrogen levels in utero might increase the risk of breast cancer [13]. In the NCI study, the overall risk for breast cancer was not increased, comparing DES exposed to unexposed women. However, at ages ≥40 and ≥50 years risks were significantly increased (incidence rate ratio (IRR) = 1.91; 95% CI = 1.09, 3.33 and IRR = 3.00; 95% CI = 1.01, 8.98, respectively) [14]. The increased risks for breast cancer attenuated when general population data (SEER) were used as reference, possibly explained by the lower body mass index of the study population (both exposed and unexposed). We used the general population as reference and found no increased breast cancer risk neither overall, nor above age 40 (SIR = 1.05; 95% CI = 0.90, 1.23 and SIR = 1.09; 95% CI = 0.91, 1.31, respectively). Our DES daughters might differ from the general population with respect to breast cancer risk factors for which we could not adjust. However, stratification for educational level, parity, and maternal age at birth did not alter our results. Another possible explanation for the inconsistent findings between our study and the NCI study is chance, because the number of cases was relatively small in the older age categories. Also, the misclassification of DES exposure in our study might have attenuated the risk.

Melanoma risk was statistically significantly increased among women ages <40 years. In addition, the risk was higher in the total cohort than in the group with questionnaire data. Possibly, some survival bias may be present in the questionnaire group as not all melanoma cases might have survived long enough to be able to participate to the questionnaire. In the NCI study, melanoma risk could not be evaluated because medical verification of this cancer, and cervical cancer, was incomplete. Sun exposure and skin type are considered to be main risk factors, while the role of reproductive and hormonal factors is controversial [15]. It has been suggested that low parity is associated with an increased risk [16], but we could not confirm that in our study (data not shown). Additionally, although this is only circumstantial evidence, the immune system might be involved. Suppression of immune response in transplantation patients who receive long-term immunosuppression therapy has been associated with a higher risk of melanoma [17]. Some studies suggested that DES daughters might be at higher risk of developing autoimmune diseases [18] or have an enhanced immune response to different mitogens [19, 20]. However, the relevance of autoimmune diseases to melanoma risk is unclear and an enhanced immune response would probably not be associated with an increased risk of melanoma. Also it is unlikely that surveillance bias plays a major role, as the stage distribution of melanoma did not differ between our subjects and the general population. Since this is the first time that melanoma risk was found to be increased in DES daughters, this result needs to be confirmed by other studies.

The risk of squamous cell cervical cancer was non-significantly decreased. This is likely due to the high screening rate among DES daughters, leading to enhanced detection of precancerous lesions of the cervix. In an earlier publication, we reported on an increased prevalence ratio (PR) of squamous cell cervical cancer among DES daughters (PR = 5.4; 95% CI = 2.8, 9.5) [21]. However, selection bias could not be ruled out. In the NCI study, medical verification for cervical cancer was incomplete and no valid risk estimates were available [22]. When evaluating cervical cancer risk, one should also take the number of pre-invasive cervical lesions into account [23].

In our study, one incident and two prevalent cases of invasive squamous cell vaginal cancer occurred, while 0.2 case was expected. All cases were reviewed by our pathologist (HvB). Assuming that these three cases were the only ones occurring among DES-exposed women in the Netherlands (alive at the time of registration), we calculated a life-time prevalence of 3 cases per 40,000 exposed women (7.5 per 100,000). This prevalence rate was 4 times as high as the prevalence rate (20-year period) in the general population in the same age category (1.8 prevalent cases per 100,000 women, region Comprehensive Cancer Centre Amsterdam). However, the estimated number of DES-exposed women in the Netherlands is rather uncertain and the number of cases is small.

The risk of lung cancer was statistically significantly reduced in our study. We did not collect information on smoking habits in our questionnaire. Therefore, we analyzed smoking behavior of 464 DES daughters that participated in a study on IVF treatment effects [24]. DES daughters smoked less cigarettes compared to the Dutch female population (source Statistics Netherlands), 13.2 and 15.9 cigarettes per day, respectively, which might explain our finding.

In conclusion, the results of our study are generally reassuring except for CCA, with a risk increase persisting at older ages. The slightly elevated risk of melanoma before age 40 is remarkable, but needs to be confirmed by other studies. We did not confirm the increased risk of breast cancer at older ages, as suggested in the NCI DES Follow-up study. Since most DES daughters in our cohort are still relatively young (44.0 years), longer follow-up is warranted to examine cancer risks at ages when cancer occurs more frequently.

Acknowledgments

The authors would like to acknowledge the Netherlands Cancer Registry (in particular Dr. O. Visser and Dr. J. A. A. M. van Dijck) and PALGA (Drs. M. Casparie) for providing the follow-up data. The authors wish to thank Drs. W. Klokman for the use of his person year analyses program and Ir. T. M. Mooij for assistance with analyses. Furthermore, we would like to acknowledge for their help with data collection: M. Legdeur, O. van der Hel, M. Homs, A. van der Meij, E. Reisenstadt, P. Woerdeman, E. Staals, M. Das, W. Drenthen, I. van Bergen, M. Rueter, J. van der Swaluw, N. Goessens, H. Karim-Kos, A. Bruinsma, M. Zwaal, H. Kruizenga, J. Klein, J. Scherrenburg, R. Paulis, K. Karsenberg, S. de Jager, I. Bisschops, M. Simons, S. Dijkhuis, B. Huisman, K. Jeanson, H. Gerritsen, K. Bakhuis, E. Bosnajakovic, L. van Dussen, G. de Leeuw- Mantel. The authors would like to warmly thank the team of the DES Center team: Drs. M. Koster, M. Kattenburg, Drs. D. van der Brugge, J. Vellekoop, I. Faber and many other volunteers. The authors wish to thank for their cooperation with collecting data from the medical archives: Dr. J. E. G. M. Stoot, Drs. J. E. M. Degen, Dr. P. X. J. M. Bouckaert, Atrium Medical Center; Dr. P. J. Dörr,Medical Center Haaglanden, location: Westeinde; Dr. J. G. Aalders, Dr. A. G. J. van der Zee, University Medical Center Groningen; Drs. L. J. van Dam, Gelre hospitals,location: Juliana; Drs. J. van den Ham, Drs. J. H. Eggens, Rivierenland Hospital, Tiel and Dr. J. Koudstaal, University Medical Center, Utrecht.

Financial support

This work was supported by The Dutch Cancer Society (grant number 2001-2426); The Netherlands Organization for Health Research and Development ZonMw; Sacha Swarttouw-Hijmans Foundation; Janivo Foundation; Mr. Paul de Gruyter Foundation; and Peterson Foundation.

Open Access

This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.

Open AccessThis is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.

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Heinonen OP (1973) Diethylstilbestrol in pregnancy. Frequency of exposure and usage patterns. Cancer 31(3):573–577CrossRefPubMed

Noller KL, Fish CR (1974) Diethylstilbestrol usage: its interesting past, important present, and questionable future. Med Clin North Am 58(4):793–810PubMed

Herbst AL, Ulfelder H, Poskanzer DC (1971) Adenocarcinoma of the vagina. Association of maternal stilbestrol therapy with tumor appearance in young women. N Engl J Med 284:878–881PubMedCrossRef

Giusti RM, Iwamoto K, Hatch EE (1995) Diethylstilbestrol revisited: a review of the long-term health effects. [review] [113 refs]. Ann Intern Med 122:778–788PubMed

Newbold R (1995) Cellular and molecular effects of developmental exposure to diethylstilbestrol: implications for other environmental estrogens. Environ Health Perspect 103(Suppl 7):83–87CrossRefPubMed

Newbold RR, Padilla-Banks E, Jefferson WN (2006) Adverse effects of the model environmental estrogen diethylstilbestrol are transmitted to subsequent generations. Endocrinology 147(6 Suppl):S11–S17CrossRefPubMed

Sato T, Fukazawa Y, Ohta Y, Iguchi T (2004) Involvement of growth factors in induction of persistent proliferation of vaginal epithelium of mice exposed neonatally to diethylstilbestrol. Reprod Toxicol 19(1):43–51CrossRefPubMed

Troisi R, Hatch EE, Titus-Ernstoff L et al (2007) Cancer risk in women prenatally exposed to diethylstilbestrol. Int J Cancer 121(2):356–360CrossRefPubMed

Casparie M, Tiebosch AT, Burger G et al (2007) Pathology databanking and biobanking in The Netherlands, a central role for PALGA, the nationwide histopathology and cytopathology data network and archive. Cell Oncol 29(1):19–24PubMed

10.

Sharp GB, Cole P, Anderson D, Herbst AL (1990) Clear cell adenocarcinoma of the lower genital tract. Correlation of mother’s recall of diethylstilbestrol history with obstetrical records. Cancer 66:2215–2220CrossRefPubMed

11.

Breslow NE, Day NE (1987) Rates and rate standardization. In: Breslow NE, Day NE (eds) Statistical methods in cancer research. Volume II—The design and analysis of cohort studies. Oxford University Press, Oxford, pp 48–79

12.

Lambe M, Hsieh C, Trichopoulos D, Ekbom A, Pavia M, Adami HO (1994) Transient increase in the risk of breast cancer after giving birth. N Engl J Med 331(1):5–9CrossRefPubMed

13.

Trichopoulos D (1990) Hypothesis: does breast cancer originate in utero? Lancet 335:939–940CrossRefPubMed

14.

Palmer JR, Wise LA, Hatch EE et al (2006) Prenatal diethylstilbestrol exposure and risk of breast cancer. Cancer Epidemiol Biomarkers Prev 15(8):1509–1514CrossRefPubMed

15.

Lens M, Bataille V (2008) Melanoma in relation to reproductive and hormonal factors in women: current review on controversial issues. Cancer Causes Control 19(5):437–442CrossRefPubMed

16.

Karagas MR, Zens MS, Stukel TA et al (2006) Pregnancy history and incidence of melanoma in women: a pooled analysis. Cancer Causes Control 17(1):11–19CrossRefPubMed

17.

Euvrard S, Kanitakis J, Claudy A (2003) Skin cancers after organ transplantation. N Engl J Med 348(17):1681–1691CrossRefPubMed

18.

Noller KL, Blair PB, O’Brien PC et al (1988) Increased occurrence of autoimmune disease among women exposed in utero to diethylstilbestrol. Fertil Steril 49:1080–1082PubMed

19.

Burke L, Segall-Blank M, Lorenzo C, Dynesius-Trentham R, Trentham D, Mortola JF (2001) Altered immune response in adult women exposed to diethylstilbestrol in utero. Am J Obstet Gynecol 185(1):78–81CrossRefPubMed

20.

Ways SC, Mortola JF, Zvaifler NJ, Weiss RJ, Yen SS (1987) Alterations in immune responsiveness in women exposed to diethylstilbestrol in utero. Fertil Steril 48(2):193–197PubMed

21.

Verloop J, Rookus MA, van Leeuwen FE (2000) Prevalence of gynecologic cancer in women exposed to diethylstilbestrol in utero. N Engl J Med 342(24):1838–1839CrossRefPubMed

22.

Hatch EE, Palmer JR, Titus-Ernstoff L et al (1998) Cancer risk in women exposed to diethylstilbestrol in utero. JAMA 280(7):630–634CrossRefPubMed

23.

Hatch EE, Herbst AL, Hoover RN et al (2001) Incidence of squamous neoplasia of the cervix and vagina in women exposed prenatally to diethylstilbestrol (United States). Cancer Causes Control 12(9):837–845CrossRefPubMed

24.

Klip H, Burger CW, de Kraker J, van Leeuwen FE (2001) Risk of cancer in the offspring of women who underwent ovarian stimulation for IVF. Hum Reprod 16(11):2451–2458PubMed

Titel: Cancer risk in DES daughters
verfasst von: Janneke Verloop
Flora E. van Leeuwen
Theo J. M. Helmerhorst
Hester H. van Boven
Matti A. Rookus
Publikationsdatum: 01.07.2010
Verlag: Springer Netherlands
Erschienen in: Cancer Causes & Control / Ausgabe 7/2010
Print ISSN: 0957-5243
Elektronische ISSN: 1573-7225
DOI: https://doi.org/10.1007/s10552-010-9526-5

Springer Medizin

Cancer risk in DES daughters