Skip to main content
PMC home page
British Journal of Cancer logoLink to British Journal of Cancer
. 2007 Apr 24;96(11):1747–1749. doi: 10.1038/sj.bjc.6603761

Cancer, cardiovascular disease and diabetes mortality among women with a history of endometrial cancer

S H Wild 1,*, J R Bryden 1, R J Lee 1, J L Bishop 2, A R Finlayson 2, C D Byrne 3, D H Brewster 1,2
PMCID: PMC2359928  PMID: 17453005

Abstract

Among 7182 women with endometrial cancer in Scotland, standardised mortality ratios (and 95% confidence intervals (CI)) were 6.38 (5.74–7.15) for all cancers and 1.10 (1.00–1.22) for circulatory diseases as underlying cause of death and 2.81 (2.19–3.70) for diabetes as underlying/contributory cause of death.

Keywords: endometrial cancer, mortality, breast cancer, ovarian cancer, cardiovascular disease, diabetes

Endometrial cancer (malignant neoplasm of the corpus uteri) is one of the five most common cancers among women and develops in approximately 400 women in Scotland (ISD Scotland, 2004), 40 000 women in the United States (National Cancer Institute, 2006) and 77 000 women across Europe each year (International Agency for Research on Cancer, 2005). Age-standardised incidence of endometrial cancer in Scotland has increased over the last decade and mortality rates appear stable (ISD Scotland, 2004). Compared with many other cancers, the survival after a diagnosis of endometrial cancer is high, with survival relative to the age-matched general population of women of approximately 70%, five years after diagnosis (Harris et al, 1998; Quinn et al, 2001). It is therefore important to consider the role of other causes of morbidity and mortality among women with endometrial cancer.

Endometrial cancer is associated with factors that increase (including obesity, diabetes and hypertension) (Shoff and Newcomb, 1998; Parazzini et al, 1999; Anderson et al, 2001; Xu et al, 2005, 2006; Trentham-Dietz et al, 2006) and decrease (including higher socio-economic status and not smoking) (Kelsey et al, 1982) risk of cardiovascular disease. In addition, there is an association with polycystic ovary syndrome (Hardiman et al, 2003), the effect on cardiovascular disease of which is unclear. It is plausible that women who survive endometrial cancer may be at high risk of cardiovascular disease and could benefit from effective approaches to primary and secondary prevention.

In Scotland, linkage between several centrally held datasets including cancer registries and death records is performed using probability matching (Kendrick and Clarke, 1993), which uses all available identifying information, including name, date of birth, postal code and patient reference number, to link records belonging to the same person.

We examined the causes of death among women with endometrial cancer and compared mortality from all causes, all cancers and selected major cancers, all diseases of the circulatory system (specifically ischaemic heart disease and stroke) and diabetes between women with endometrial cancer and women in the general population of Scotland.

MATERIALS AND METHODS

The Information Services Division of National Health Service National Services Scotland identified a retrospective cohort of women in Scotland who received a registration of malignant neoplasm of the corpus uteri (ninth and tenth revisions of the International Classification of Diseases (ICD-9 and ICD-10) codes 182 and C54) between 1981 and 2000 and provided anonymised data linked to mortality records for cohort members.

Cause of death in Scotland was coded using ICD-9 codes for deaths between 1981 and 1999 and ICD-10 codes for deaths occurring after 1999. An area-based measures of deprivation category was used as a marker for socio-economic status, which is a potentially important confounding factor. The Carstairs Index is derived from four census indicators: low social class, lack of car ownership, overcrowding and male unemployment for postal sectors derived from 1981 and 1991 census data (Carstairs and Morris, 1991).

Estimates of the numbers of women in Scotland by age group (in 5-year groups from 30 to 34 and 85+), calendar period (1981–1985, 1986–1990, 1991–1996, 1997–2002) and deprivation category were derived from the Registrar General for Scotland mid-year population estimates and 1981 and 1991 census population estimates. The number of deaths for the general population of women in Scotland by 5-year age group, calendar period and deprivation category were available for all causes combined and for selected underlying causes of death: all cancers (ICD-9: 140–208, ICD-10: C0-C97), breast cancer (ICD-9: 174, ICD-10: C50), ovarian cancer (ICD-9: 183, ICD-10: C56), colon cancer (ICD-9: 153, ICD-10: C18), all diseases of the circulatory system (ICD-9: 390–459, ICD-10: I00-I99), ischaemic heart disease (ICD-9: 410–414, ICD-10: I20-I25), cerebrovascular disease (ICD-9: 430–438, ICD-10: I60-I69, G45). Diabetes (ICD-9: 250, ICD-10: E10-E14) was considered as either an underlying or contributory cause of death.

For each cohort member, date of endometrial cancer diagnosis was grouped into calendar periods of 1981–1985, 1986–1990, 1991–1995 and 1996–2000. Length of follow-up was calculated in days either between diagnosis and death or between diagnosis and the end of 2002 for survivors. Calendar periods at death were grouped in the following categories: 1981–1985, 1986–1990, 1991–1996 and 1997–2002. The analysis was based on women of 30 years and older at diagnosis who had complete data available on age, deprivation category and date of diagnosis.

Standardised mortality ratios (SMRs) for all combined and selected causes of death were derived for the endometrial cancer cohort using indirect standardisation. Age group, calendar period and deprivation category-specific mortality rates for the whole population of women in Scotland over 29 years of age (approximately 1.7 million women) were used as the standard. CIs were estimated using the Fieller method, which takes account of potential errors in expected death rates (Silcocks, 1994).

RESULTS

The cohort included 16 women below 30 years of age and four women with missing data for deprivation category and these 20 women were excluded, leaving 7182 women in the analysis. The mean and median age at diagnosis of endometrial cancer was 65 years. Median time between diagnosis of endometrial cancer and death or the end of the follow-up period at 31 December 2002 for the cohort was 5.0 years (inter-quartile range: 1.8–10.5 years).

Approximately half of the cohort (3615 women) died during the follow-up period and five year absolute survival was 62%. The single largest cause of death was endometrial cancer with 1529 (42%) death certificates giving endometrial cancer (ICD-9 and ICD-10 codes 182 and C54) as the underlying cause of death. There were another 210 (5.8%) death certificates that gave ICD-9 and ICD-10 codes 179 and C55 (uterus, part unspecified) for the underlying cause of death. A further 384 death certificates (11%) included endometrial cancer (ICD-9 and ICD-10 codes 182 and C54) as a contributory cause of death.

Breast cancer, ovarian cancer, ischaemic heart disease and cerebrovascular disease were identified as the underlying cause of death for 114 (3.2%), 87(2.4%), 394 (11%), 238 (6.6%) deaths, respectively. Diabetes was reported as either underlying or contributory cause of death on 220 death certificates (6.1%). Diabetes was given as the underlying cause of death on only 32 death certificates. The most common underlying causes of death when diabetes was given as a contributory cause were ischaemic heart disease (52 deaths), endometrial cancer (29 deaths) and cerebrovascular disease (24 deaths). Table 1 shows SMRs for all causes, all cancers, endometrial, breast and ovarian cancer, all circulatory diseases, ischaemic heart disease, cerebrovascular disease and diabetes among the cohort of women with endometrial cancer.

Table 1. Numbers of deaths, mortality ratios (SMR) and 95% CI for selected causes of death between 1981 and 2002 among women with endometrial cancer diagnosed between 1981 and 2000 in Scotland, standardised for age, deprivation category and calendar period.

Cause of death (ICD codes) Deaths SMR 95% CI
All causes 3615 2.34 2.21–2.49
All cancers (ICD-9: 140–208, ICD-10: C0–C97) 2357 6.38 5.74–7.15
Endometrial cancer (ICD-9: 182, ICD-10: C54) 1529 277 150–1682
Breast cancer (ICD-9: 174, ICD-10: C50) 114 2.05 1.51–2.90
Ovarian cancer (ICD-9: 183, ICD-10: C56) 87 4.26 2.77–7.74
All circulatory disease (ICD-9: 390–459, ICD-10: I00–I99) 795 1.10 1.00–1.22
Ischaemic heart disease (ICD-9: 410–414, ICD-10: I20–I25) 394 1.10 0.96–1.27
Cerebrovascular disease (ICD-9: 430–438, ICD-10: I60–I69, G45) 238 1.02 0.85–1.22
Diabetes (underlying or contributory cause) (ICD-9: 250, ICD-10: E10–E14) 220 2.81 2.19–3.70
Open in a new tab

Abbreviations: CI, confidence intervals; SMR, standardized mortality ratios.

DISCUSSION

In this first cohort study of mortality in Britain among women with endometrial cancer we found that over 42% of death certificates included endometrial cancer as the underlying cause of death. We found that in the cohort, ovarian cancer mortality was over four times higher and all-cause, breast cancer and diabetes-related mortality was approximately twice as high as that of the general female population, after allowing for potential differences in distribution of age, calendar period and deprivation category between groups. In contrast, mortality from ischaemic heart disease and cerebrovascular disease were similar in the cohort and the general female population.

A similar proportion of deaths ascribed to endometrial cancer was also reported by a smaller study in Iowa in which 39 out of 93 death certificates for women with a history of endometrial cancer gave endometrial cancer as the underlying cause of death (Folsom et al, 2004). The high breast cancer mortality in the endometrial cancer cohort reflects shared risk factors (including low parity, late menopause, high socio-economic status and obesity) but perhaps also the increased endometrial cancer risk associated with tamoxifen treatment for breast cancer (Bergman et al, 2000). Tamoxifen treatment appears to be associated with a reduced risk of cardiovascular disease (Swerdlow and Jones, 2005). We were unable to determine in our study the temporal relationship between endometrial and breast cancers. Higher ovarian cancer mortality in the cohort may again be related to shared risk factors as for breast cancer, but could also be potentially related to oestrogen production by some ovarian cancers.

Recording of diabetes on death certificates is known to be incomplete (Thomason et al, 2005). Under-reporting of diabetes on death certificates appears to be even more marked for people who died of cancer than among those with other recorded causes of death (McEwen et al, 2006). This would suggest a bias that may underestimate excess diabetes-related mortality among women with endometrial cancer.

The relative risk of coronary heart disease among women with diabetes is approximately 2.5-fold that of women without diabetes (Lee et al, 2000). The presumed higher prevalence of diabetes among women with endometrial cancer could therefore be expected to be associated with an increase in cardiovascular disease mortality. A long-term follow-up study of women with polycystic ovary syndrome also reported no excess of cardiovascular disease mortality, despite an excess of prevalence of and mortality from diabetes (Wild et al, 2000). The absence of excess cardiovascular disease mortality in the cohort could potentially be explained by a combination of endometrial and breast cancer acting as competing causes of death, residual confounding, non-random misclassification bias or possibly a protective effect of exposure to unopposed oestrogen against cardiovascular disease. A prospective cohort study is required to establish the role of these factors.

The use of routine data means that the potential confounding effects of only age, calendar period and deprivation category could be addressed in this study. We were unable to consider the effects of other potential confounding factors including parity, body mass index, fat distribution, smoking habit, presence and treatment for hypertension or dyslipidaemia and use of hormone replacement therapy, aspirin, anti-hypertensives, lipid-lowering drugs or tamoxifen.

There is the potential for errors in record linkage, but this is unlikely to have a marked effect as the linkage process is estimated to be 98% accurate (Harley and Jones, 1999). The codes and the rules for coding the underlying cause of death changed with the introduction of ICD-10 codes for mortality data in 2000 and we have assumed that any effect of this would be similar for women with and without endometrial cancer.

In conclusion, we have shown that endometrial cancer is associated with an approximately fourfold increase in ovarian cancer mortality and a twofold increase in mortality from breast cancer and diabetes, and that cardiovascular disease mortality among women with a history of endometrial cancer is similar to that observed in the general population. The findings suggest that women with endometrial cancer should receive similar advice on lifestyle and pharmacological treatment for primary and secondary prevention of cardiovascular disease to women in the general population. The high diabetes prevalence and mortality among women with endometrial cancer suggests that weight control and regular physical activity are particularly important for this group of women. Further research is required to establish the temporal relationships between endometrial cancer, ovarian cancer, breast cancer and diabetes and to establish appropriate approaches to screening for and management of each condition among women with one or more of the other conditions.

Acknowledgments

This work was supported by a small grant from the Chief Scientist Office of the Scottish Executive Health Department. We thank Dr Pam Warner for her helpful comments on the draft manuscript.

References

  1. Anderson KE, Anderson E, Mink PJ, Hong CP, Kushi LH, Sellers TA, Lazovich D, Folsom AR (2001) Diabetes and endometrial cancer in the Iowa women's health study. Cancer Epidemiol Biomarkers Prev 10: 611–616 [PubMed] [Google Scholar]
  2. Bergman L, Beelen ML, Gallee MP, Hollema H, Benraadt J, van Leeuwen FE (2000) Risk and prognosis of endometrial cancer after tamoxifen for breast cancer. Comprehensive Cancer Centres' ALERT Group. Assessment of Liver and Endometrial cancer Risk following Tamoxifen. Lancet 356: 881–887 [DOI] [PubMed] [Google Scholar]
  3. Carstairs V, Morris R (1991) Deprivation and Health in Scotland. Aberdeen: Aberdeen University Press [Google Scholar]
  4. Folsom AR, Anderson KE, Sweeney C, Jacobs Jr DR (2004) Diabetes as a risk factor for death following endometrial cancer. Gynecol Oncol 94: 740–745 [DOI] [PubMed] [Google Scholar]
  5. Hardiman P, Pillay OC, Atiomo W (2003) Polycystic ovary syndrome and endometrial carcinoma. Lancet 361: 1810–1812 [DOI] [PubMed] [Google Scholar]
  6. Harley K, Jones C (1999) Quality of Scottish Morbidity Records (SMR) Data. Health Bulletin 54: 410–417 [PubMed] [Google Scholar]
  7. Harris V, Sandridge AL, Black RJ, Brewster DH, Gould A (1998) Cancer Registration Statistics Scotland 1986–1995. Edinburgh: ISD Scotland Publications [Google Scholar]
  8. International Agency for Research on Cancer. GLOBOCAN 2002 Database. http://www-dep.iarc.fr/ 2005. Accessed 24/11/06
  9. ISD Scotland 2004. Cancer in Scotland 2002 updated 2006 http://www.isdscotland.org/isd/files/Cancer_in_Scotland_summary_m.pdf Accessed 24/11/06
  10. Kelsey JL, LiVolsi VA, Holford TR, Fischer DB, Mostow ED, Schwartz PE, O'Connor T, White C (1982) A case-control study of cancer of the endometrium. Am J Epidemiol 116: 333–342 [DOI] [PubMed] [Google Scholar]
  11. Kendrick S, Clarke J (1993) The Scottish record linkage system. Health Bulletin 51: 72–79 [PubMed] [Google Scholar]
  12. Lee WL, Cheung AM, Cape D, Zinman B (2000) Impact of diabetes on coronary artery disease in women and men: a meta-analysis of prospective studies. Diabetes Care 23: 962–968 [DOI] [PubMed] [Google Scholar]
  13. McEwen LN, Kim C, Haan M, Ghosh D, Lantz PM, Mangione CM, Safford MM, Marrero D, Thompson TJ, Herman WH (2006) Diabetes reporting as a cause of death: results from the Translating Research Into Action for Diabetes (TRIAD) study. Diabetes Care 29: 247–253 [DOI] [PubMed] [Google Scholar]
  14. National Cancer Institute 2006. Estimated new cancer cases deaths 2005. Surveillance, Epidemiology and End Results. http://seer.cancer.gov/csr/1975_2002/results_single/sect_01_table.01.pdf Accessed 24/11/06
  15. Parazzini F, La Vecchia C, Negri E, Riboldi GL, Surace M, Benzi G, Maina A, Chiaffarino F (1999) Diabetes and endometrial cancer: an Italian case-control study. Int J Cancer 81: 539–542 [DOI] [PubMed] [Google Scholar]
  16. Quinn M, Babb P, Brock A, Kirby L, Jones J (2001) Cancer Trends in England and Wales 1950–1999. SMPS No 66 London: The Stationery Office [Google Scholar]
  17. Shoff SM, Newcomb PA (1998) Diabetes, body size, and risk of endometrial cancer. American Journal of Epidemiology 148: 234–240 [DOI] [PubMed] [Google Scholar]
  18. Silcocks P (1994) Estimating confidence limits on a standardised mortality ratio when the expected number is not error free. J Epidemiol Community Health 48: 313–317 [DOI] [PMC free article] [PubMed] [Google Scholar]
  19. Swerdlow AJ, Jones ME (2005) Tamoxifen treatment for breast cancer and risk of endometrial cancer: a case-control study. J Natl Cancer Inst 97: 375–384 [DOI] [PubMed] [Google Scholar]
  20. Thomason MJ, Biddulph JP, Cull CA, Holman RR (2005) Reporting of diabetes on death certificates using data from the UK Prospective Diabetes Study. Diabet Med 22: 1031–1036 [DOI] [PubMed] [Google Scholar]
  21. Trentham-Dietz A, Nichols HB, Hampton JM, Newcomb PA (2006) Weight change and risk of endometrial cancer. Int J Epidemiol 35: 151–158 [DOI] [PubMed] [Google Scholar]
  22. Wild S, Pierpoint T, McKeigue P, Jacobs H (2000) Cardiovascular disease in women with polycystic ovary syndrome at long-term follow-up: a retrospective cohort study. Clin Endocrinol (Oxf) 52: 595–600 [DOI] [PubMed] [Google Scholar]
  23. Xu WH, Matthews CE, Xiang YB, Zheng W, Ruan ZX, Cheng JR, Gao YT, Shu XO (2005) Effect of adiposity and fat distribution on endometrial cancer risk in Shanghai women. Am J Epidemiol 161: 939–947 [DOI] [PubMed] [Google Scholar]
  24. Xu WH, Xiang YB, Zheng W, Zhang X, Ruan ZX, Cheng JR, Gao YT, Shu XO (2006) Weight history and risk of endometrial cancer among Chinese women. Int J Epidemiol 35: 159–166 [DOI] [PubMed] [Google Scholar]

Articles from British Journal of Cancer are provided here courtesy of Cancer Research UK

RESOURCES