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. 2008 Jul 29;99(4):611–615. doi: 10.1038/sj.bjc.6604524

The occurrence of invasive cancers following a diagnosis of breast carcinoma in situ

D Robinson 1,*, L Holmberg 2, H Møller 1
PMCID: PMC2527835  PMID: 18665169

Abstract

Approximately 1 in every 600 women attending breast-screening programmes in the United Kingdom is diagnosed with breast carcinoma in situ (BCIS). However, there is little information on the occurrence of subsequent cancers (other than second breast cancers) in these women. We investigated the occurrence of invasive cancers in 12 836 women diagnosed with BCIS in southeast England between 1971 and 2003, using data from the Thames Cancer Registry. A greater than expected number of subsequent cancers was found for two sites: breast (standardised incidence ratio (SIR) 1.96; 95% confidence interval (CI) 1.79–2.14) and corpus uteri (SIR 1.42; 95% CI 1.11–1.78). For subsequent ipsilateral breast cancer in those treated with breast conservation, the excess was independent of the time since diagnosis of BCIS, whereas for subsequent contralateral breast cancer, there was a steady decline in excess over time. For subsequent uterine cancer, the excess became statistically significant only at >5 years after BCIS diagnosis, consistent with a treatment effect. This was further supported by Cox regression anaysis: the risk of subsequent uterine cancer was significantly increased in women receiving hormonal therapy compared with those not receiving it, with a hazard ratio of 2.97 (95% CI 1.84–4.80).

Keywords: breast carcinoma in situ, second cancers, hormonal therapy, uterine cancer

Currently, approximately 1 in every 600 women attending breast-screening programmes in the United Kingdom is diagnosed with breast carcinoma in situ (BCIS). This amounted to almost 3000 cases in 2004–2005 (NHS Cancer Screening Programmes, 2006). The most common form of treatment is lumpectomy, with or without radiotherapy, although women with a more diffuse pattern of BCIS may undergo mastectomy. A number of previous studies have focused on the risk of second breast cancer following a diagnosis of BCIS (Habel et al, 1997; Wärnberg et al, 2000; Claus et al, 2003; Levi et al, 2005; Rawal et al, 2005), with estimates of relative risk generally of the order of two- to fivefold. Few studies have looked at the occurrence of subsequent invasive cancers at other sites (Ward et al, 1992; Franceschi et al, 1998; Soerjomataram et al, 2006), and these were based on relatively small numbers of cases.

In the current population-based study, we have investigated the occurrence of subsequent invasive cancers in a very large series of unselected women with BCIS in southeast England. We have also examined the relationship between treatment for BCIS and the development of subsequent cancers.

Materials and methods

All recorded cases of BCIS (ICD10 code D05) diagnosed in women between 1971 and 2003 were extracted from the Thames Cancer Registry (TCR) database. The TCR is a population-based registry covering London and a large part of southeast England. Patients with any other cancers diagnosed prior to, or at the same time as, BCIS were excluded in order to avoid confounding the sequelae of BCIS with those of other cancers, particularly breast cancer. The occurrence of subsequent cancers was analysed by calculating the standardised incidence ratio (SIR) for each cancer site. This is the ratio of the observed number of cancers at that site divided by the number expected in the general population, calculated by multiplying time at risk by age/calendar period-matched incidence rates for women in southeast England. For each case, person-years were calculated from date of diagnosis to the end of 2004, date of death, date of last known follow-up or date of diagnosis of subsequent cancer, whichever was earlier. Ipsilateral and contralateral subsequent breast cancers were considered separately. When analysing ipsilateral subsequent breast cancer, follow-up was truncated at the date of mastectomy if this had been performed.

Information on radiotherapy and hormonal therapy received within 6 months of diagnosis was also available on the database. Although precise details of the type of hormonal therapy were unavailable, the use of tamoxifen is likely to predominate. The effects of treatment on the occurrence of subsequent cancers were explored by applying Cox regression models with age at diagnosis of BCIS (stratified into 5-year age groups), radiotherapy and hormonal therapy as covariates. Results for a given mode of treatment were expressed as the hazard ratio (HR) in those with a record of receiving that treatment vs those with no such record, adjusted for age and the receipt or otherwise of the other treatment mode.

Results

A total of 14 329 cases of BCIS were extracted from the database. Of these, 23 were excluded as having a recorded date of diagnosis that was the same as the date of death, and a further 1046 cases were excluded as having a prior or synchronous cancer. An additional 424 patients who were recorded as receiving chemotherapy were also excluded, as it is likely that these patients were wrongly classified as chemotherapy was not a normal component of treatment for BCIS during the period of the study. This left a total of 12 836 cases for analysis. Table 1 shows the characteristics of the patients included in the study. The majority (86%) of the in situ cancers were intraductal BCIS, 5% were lobular BCIS and the remainder were of other or mixed morphological subtypes. The mean age at diagnosis was 57 years. Overall, 3880 patients (30.2%) had a record of radiotherapy treatment and 3064 (23.9%) had a record of hormonal therapy. Of the patients who underwent breast-conserving surgery, 42% had a record of treatment with radiotherapy.

Table 1. Patient characteristics.

  No. of patients % of patients
Age at diagnosis (years)
 <45 1764 13.7
 45–49 1611 12.6
 50–54 2568 20.0
 55–59 2133 16.6
 60–64 1920 15.0
 ⩾65 2840 22.1
     
Period of diagnosis
 1971–1974 971 7.6
 1975–1984 2360 18.4
 1985–1994 3892 30.3
 1995–2003 5613 43.7
     
Morphological type    
 Ductal 11 052 86.1
 Lobular 681 5.3
 Other/mixed 1103 8.6
     
Surgery
 Total mastectomy 4713 36.7
 Partial mastectomy 764 6.0
 Lumpectomy 4991 38.9
 Other surgery 632 4.9
 None 1736 13.5
     
Radiotherapy
 Yes 3880 30.2
 No 8956 69.8
     
Hormonal therapy
 Yes 3064 23.9
 No 9772 76.1
Total cases 12 836  
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Table 2 shows the observed and expected numbers of subsequent invasive cancers at a number of major sites. A greater than expected number of subsequent occurrences of cancer was found for two sites: breast (C50) and corpus uteri (C54). Standardised incidence ratios were 1.96 for breast cancer (95% confidence interval (CI) 1.79–2.14) and 1.42 for uterine cancer (95% CI 1.11–1.78). There was a reduced incidence of cancers of the pancreas (SIR 0.59; 95% CI 0.37–0.90) and lung (SIR 0.75; 95% CI 0.61–0.92), and of cancers at ‘other’ sites (SIR 0.52; 95% CI 0.41–0.66).

Table 2. Occurrence of invasive cancers at specific sites subsequent to breast carcinoma in situ.

Site Observed Expected SIR 95% CI
Head and neck 19 25.03 0.76 0.46–1.19
Oesophagus 22 22.85 0.97 0.60–1.46
Stomach 26 32.82 0.79 0.52–1.16
Colorectal 130 147.93 0.88 0.73–1.04
Pancreas 22 37.20 0.59 0.37–0.90
Lung 101 133.92 0.75 0.61–0.92
Malignant melanoma 14 21.80 0.64 0.35–1.08
Breast 512 261.44 1.96 1.79–2.14
Cervix uteri 12 20.39 0.59 0.30–1.03
Corpus uteri 74 52.14 1.42 1.11–1.78
Ovary 49 59.81 0.82 0.61–1.08
Kidney 16 16.02 1.00 0.57–1.62
Bladder 22 30.13 0.73 0.46–1.11
Non-Hodgkin's lymphoma 24 35.56 0.67 0.43–1.00
Multiple myeloma 11 16.00 0.69 0.34–1.23
Leukaemia 20 24.93 0.80 0.49–1.24
Othersa 72 138.28 0.52 0.41–0.66
All sitesa 1146 1076.25 1.06 1.00–1.13
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CI=confidence interval; SIR=standardised incidence ratio.

a

Excluding non-melanoma skin cancers.

Table 3 shows the SIRs for these two sites by time since diagnosis of BCIS, and also separately for subsequent ipsilateral and contralateral breast cancers. The overall SIRs for subsequent ipsilateral and contralateral breast cancers were 2.37 (95% CI 2.07–2.70) and 1.72 (95% CI 1.53–1.93), respectively. For subsequent ipsilateral breast cancer, the excess was fairly constant, with SIRs of 2.24, 2.55 and 2.27 at times 0–1, 1–5 and >5 years after BCIS diagnosis, respectively. For subsequent contralateral breast cancer, there was a steady decline in the excess over time, with SIRs of 3.00, 2.07 and 1.38, respectively, in these three time periods. For subsequent cancer of the uterus, the excess became statistically significant only at >5 years after BCIS diagnosis (SIR 1.58; 95% CI 1.18–2.07).

Table 3. Occurrence of invasive cancers of the breast and uterus subsequent to breast carcinoma in situ (by time since diagnosis).

  Years since diagnosis
 
Site 0–1 1–5 >5 Total
Uterus
 Pyrs 12 736 42 110 73 850 128 696
 Obs 6 16 52 74
 Exp 4.11 15.07 32.96 52.14
 SIR 1.46 1.06 1.58 1.42
 CI 0.54–3.18 0.61–1.72 1.18–2.07 1.11–1.78)
         
Breast
All
  Pyrs 10 467 33 671 53 206 97 344
  Obs 66 189 257 512
  Exp 24.57 83.59 153.28 261.44
  SIR 2.69 2.26 1.68 1.96
  CI 2.08–3.42 1.95–2.61 1.48–1.89 1.79–2.14
         
Ipsilateral
 Pyrs 8388 26 106 35 250 69 744
 Obs 23 86 117 226
 Exp 10.25 33.73 51.47 95.45
 SIR 2.24 2.55 2.27 2.37
 CI 1.42–3.37 2.04–3.15 1.88–2.72 2.07–2.70
         
Contralateral
 Pyrs 12 547 41 235 71 162 124 944
 Obs 43 103 140 286
 Exp 14.32 49.86 101.81 165.99
 SIR 3.00 2.07 1.38 1.72
 CI 2.17–4.04 1.69–2.51 1.16–1.62 1.53–1.93
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CI=confidence interval; Exp=expected number; Obs=observed number; Pyrs=person-years; SIR=standardised incidence ratio.

In general, results were similar when looking separately at patients diagnosed with ductal carcinoma in situ (DCIS) or lobular carcinoma in situ (LCIS) (results not shown). However, in the first year post-diagnosis, there was a significant excess of subsequent ipsilateral breast cancers in women diagnosed with LCIS (SIR 8.06; 95% CI 2.62–18.82), but not for DCIS (SIR 1.51; 95% CI 0.80–2.58).

The results of the Cox regression analysis are shown in Table 4. The risk of subsequent uterine cancer was significantly increased in women with a record of hormonal therapy (compared with those without), with an HR of 2.97 (95% CI 1.84–4.80). The risk of subsequent breast cancer was decreased in women with a record of radiotherapy (HR 0.73; 95% CI 0.60–0.89); this reduction in risk was due solely to a decreased risk of subsequent ipsilateral breast cancer (HR 0.40; 95% CI 0.29–0.55). There was no significant reduction in the risk of subsequent contralateral breast cancer in women with a record of radiotherapy. Including period of diagnosis and morphological type as additional factors in the model had no significant effect on the estimated HRs.

Table 4. HRs and 95% CIs for subsequent cancer in relation to type of treatment.

  Type of treatment
Site Radiotherapy Hormone therapy
Uterus
 Pyrsa 41 554 26 866
nb 22 34
 HRc 0.83 2.97
 CI 0.50–1.37 1.84–4.80
     
Breast
All
  Pyrsa 34 105 22 834
  nb 145 120
  HRc 0.73 1.01
  CI 0.60–0.89 0.82–1.25
     
Ipsilateral
  Pyrsa 27 803 19 387
  nb 49 65
  HRc 0.40 1.20
  CI 0.29–0.55 0.89–1.61
     
Contralateral
 Pyrsa 40 408 26 281
nb 96 55
 HRc 1.07 0.85
 CI 0.84–1.37 0.63–1.15
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CI=confidence interval; HR=hazard ratio; Pyrs=person-years.

a

Total person-years in group receiving treatment of specified type.

b

Number of occurrences of subsequent cancer in group receiving treatment.

c

HR for treatment recorded vs not recorded, adjusted for 5-year age group and other treatment mode.

A separate analysis restricted to women in the age range of 50–64 years eligible for breast screening showed essentially the same results (data not shown). In addition, stratifying the analysis into pre- and post-screening periods (1971–1989 vs 1990–2003) produced similar results with respect to subsequent invasive breast cancer. There was no significant excess of uterine cancer in the earlier period, but this was due to the small number of patients receiving hormonal therapy prior to mid 1980s/early 1990s.

Discussion

We have found an excess of subsequent cancers of the breast and corpus uteri following a diagnosis of BCIS. For subsequent uterine cancer, the excess became statistically significant only at >5 years after BCIS diagnosis, consistent with a treatment effect. This was confirmed by Cox regression analysis: the risk of subsequent uterine cancer was significantly increased in women with a record of hormonal therapy, with an HR of 2.97 (95% CI 1.84–4.80).

Increased occurrence of breast cancer following BCIS has been shown in a number of previous studies from around the world: from Sweden (Wärnberg et al, 2000; Rawal et al, 2005); Switzerland (Franceschi et al, 1998; Levi et al, 2005); The Netherlands (Soerjomataram et al, 2006); and the United State of America (Ward et al, 1992; Habel et al, 1997; Claus et al, 2003). Soerjomataram et al (2006) also found an increased occurrence of skin cancer (SIR 1.7; 95% CI 1.1–2.6) following BCIS, whereas Ward et al (1992) found that (apart from breast cancer) colorectal, cervical and endometrial cancers were the most prevalent in BCIS patients. On the other hand, Franceschi et al (1998) found no excess risk at any cancer site other than the breast.

Soerjomataram et al (2006) studied subsequent ipsilateral and contralateral breast cancers separately, and found the increased risks to be similar (SIR for ipsilateral 1.9; contralateral 2.0) – although each of these figures was based on a per-person rather than per-breast calculation and should therefore be doubled in order to be directly comparable with our SIR estimates.

The very high SIR (3.00; 95% CI 2.17–4.04) observed for subsequent contralateral breast cancer in the first year after BCIS diagnosis may be a manifestation of co-existing disease, or may result from the extra surveillance around the time of treatment for the first breast cancer, intense medical follow-up or self-observation of the patient – resulting in either detection or lead-time bias. The fact that detection bias is in operation is further indicated by the high risk of ipsilateral cancer (SIR 8.06) in patients with LCIS during the first year of follow-up, as LCIS has traditionally been thought to be a marker for high risk of multifocal and contralateral disease (Frykberg et al, 1987; Page et al, 1991; Chuba et al, 2005).

The SIR values we found for subsequent breast and uterine cancers are similar to those following invasive breast cancer from an earlier study on the same population (Evans et al, 2001). This similarity was also seen in the studies by Soerjomataram et al (2006) and Claus et al (2003).

It is known from randomised controlled trials that radiotherapy after breast-conserving surgery for BCIS reduces recurrences in the ipsilateral breast (Fisher et al, 1993; Fisher et al, 1998; Julien et al, 2000; Houghton et al, 2003; Bijker et al, 2006; Emdin et al, 2006; Ringberg et al, 2007). We also found this protective effect of radiotherapy on the subsequent development of invasive cancer in the ipsilateral breast (HR 0.40; 95% CI 0.29–0.55). This HR is similar to those reported from the clinical trials. Thus, the well-studied effects of radiotherapy appear to hold true in an observational setting. However, our findings are in contrast with those of Soerjomataram et al (2006), who found (also in an observational setting) that both ipsilateral and contralateral invasive breast cancer risks were slightly higher in BCIS patients who received radiotherapy.

In our study, we found a significant effect of hormonal therapy on the subsequent risk of uterine cancer in women diagnosed with BCIS, with those who received this form of treatment being three times more likely to develop cancer of the uterus than those who did not. This was not offset by any significant reduction in the risk of developing subsequent invasive breast cancer (HR 1.01; 95% CI 0.82–1.25).

A number of previous studies have demonstrated a link between hormonal treatment for invasive breast cancer and the development of uterine or endometrial cancer (Khandekar et al, 1978; Hardell, 1988; Fornander et al, 1989; Atlante et al, 1990; Gusberg, 1990; Mathew et al, 1990; Andersson et al, 1991; Fisher et al, 1994; Rubino et al, 2003). However, it is generally accepted that for women with invasive breast cancer, the benefits of hormonal treatment, such as tamoxifen, outweigh the associated risks (Gail et al, 1999).

In the NSABP B-24 study, Fisher et al (1999) compared lumpectomy plus radiation therapy with lumpectomy, radiation therapy and tamoxifen treatment. They found that the risk of ipsilateral breast cancer was lower in the tamoxifen group. In contrast, Houghton et al (2003) in the UK randomised trial found that ipsilateral invasive disease was not reduced by tamoxifen, and concluded that ‘there is little evidence for the use of tamoxifen in these women’.

We found significantly lower than expected numbers of lung and pancreatic cancers following a diagnosis of BCIS as well as in the group of ‘other’ cancers. This has not been reported in other studies. The incidence of breast cancer and the uptake of mammographic screening are known to be related to the socioeconomic status, and it is likely that the women in our study are more affluent and generally more health conscious, with lower than average rates of smoking.

The major strengths of our study are its population-based design, the large number of patients and the length of follow-up. However, it also has a number of limitations. The findings on the incidence of second primary cancers are based on cancer registry data, which contain limited and incomplete treatment information largely confined to initial management and lacking in detail of specific drugs, radiation doses and radiation fields. Also, there may be underreporting of second cancers in those who leave the registry catchment area. In the majority of such cases, the registry would neither be informed of the patient's emigration nor receive notification of subsequent cancers. This would lead to an underestimation of the risk of subsequent cancer, and hence the quoted SIR values relating to excess risk will tend to be erroneous on the conservative side. In addition, as the data were extracted in 2005, cancer incidence till the end of 2004 would still be incomplete by a few percent. Again, this would tend to lead to an underestimation of SIRs, although this problem would be restricted to the short-term estimates.

There is also a possibility of under-ascertainment of treatment in the TCR database, as information on treatment more than 6 months after diagnosis is not recorded. This is more likely to be of importance in relation to the recording of radiotherapy, as waiting times for radiotherapy are known to have increased in recent years (Robinson et al, 2005; Jack et al, 2007). However, any misclassification would result in a dilution of the difference between the treated and untreated groups, and hence any reported estimates of treatment effects would be conservative. A previous study on the same database (Roychoudhuri et al, 2004), looking at malignancies following radiotherapy for invasive breast cancer, showed an increase in myeloid leukaemia consistent with other studies, suggesting that the treatment data are reliable.

The quality and completeness of the recording of BCIS have been variable over the period studied. There was an increase in the numbers in mid 1990s, corresponding to an increased rate of detection following the introduction of the national breast-screening programme. Since then, rates have continued to rise, with the overall age-standardised rate for 2003 being approximately 13 per 100 000 women. Our identification of BCIS cases was based on patient pathology reports. As a result of changes over time in the histological classification and diagnosis of BCIS, it is possible that some of our patients may have had invasive breast cancer that was missed on diagnosis, but we would expect the number of such cases to be small.

There have also been significant changes in treatment for BCIS over the period of the study. Cox regression analysis indicates that after allowing for these changes in treatment over time, the period of diagnosis was not independently related to subsequent risk of cancer, that is, there is no significant effect of period over and above the associated treatment effects.

Although we have allowed for the effects of curative mastectomies by analysing ipsilateral and contralateral subsequent breast cancers separately, our data set may still contain women who underwent prophylactic removal of the contralateral breast, which we were unable to allow for. However, the number of such women is likely to be small and would have minimal effect on the calculation of risk estimates.

In many women, BCIS is detected at screening. Our data show that such women are at a moderately increased risk of a subsequent contralateral invasive breast cancer, a greater risk of ipsilateral invasive breast cancer in those with a preserved breast (especially if radiotherapy is not given) and a risk of uterine cancer associated with hormonal treatment. However, all three can be managed – the first by surveillance to detect and treat early, the second by radiotherapy and the third by the limitation of the administration of tamoxifen to those patients for whom it is really indicated.

References

  1. Andersson M, Storm HH, Mouridsen HT (1991) Incidence of new primary cancers after adjuvant tamoxifen therapy and radiotherapy for early breast cancer. J Natl Cancer Inst 83: 1013–1017 [DOI] [PubMed] [Google Scholar]
  2. Atlante G, Pozzi M, Vincenzoni C, Vocaturo G (1990) Four case reports presenting new acquisitions on the association between breast and endometrial carcinoma. Gynecol Oncol 37: 378–380 [DOI] [PubMed] [Google Scholar]
  3. Bijker N, Meijnen P, Peterse JL, Bogaerts J, van Hoorebeeck I, Julien J-P, Gennaro M, Rouanet P, Avril A, Fentiman IS, Bartelink H, Rutgers EJ (2006) Breast-conserving treatment with or without radiotherapy in ductal carcinoma in situ: ten-year results of European Organisation for Research and Treatment of Cancer Randomized phase III trial 10853 – a study by the EORTC Breast Cancer Cooperative Group and EORTC Radiotherapy Group. J Clin Oncol 24: 3381–3387 [DOI] [PubMed] [Google Scholar]
  4. Chuba PJ, Hamre MR, Yap J, Severson RK, Lucas D, Shamsa F, Aref A (2005) Bilateral risk for subsequent breast cancer after lobular carcinoma in situ: analysis of surveillance, epidemiology, and end results data. J Clin Oncol 23: 5534–5541 [DOI] [PubMed] [Google Scholar]
  5. Claus EB, Stowe M, Carter D, Holford T (2003) The risk of a contralateral breast cancer among women diagnosed with ductal and lobular breast carcinoma in situ: data from the Connecticut Tumor Registry. Breast 12: 451–456 [DOI] [PubMed] [Google Scholar]
  6. Emdin SO, Granstrand B, Ringberg A, Sandelin K, Arnesson L-G, Nordgren H, Anderson H, Garmo H, Holmberg L, Wallgren A (2006) SweDCIS: radiotherapy after sector resection for ductal carcinoma in situ of the breast. Results of a randomised trial in a population offered mammography screening. Acta Oncol 45: 536–543 [DOI] [PubMed] [Google Scholar]
  7. Evans HS, Lewis CM, Robinson D, Bell CMJ, Møller H, Hodgson SV (2001) Incidence of multiple primary cancers in a cohort of women diagnosed with breast cancer in southeast England. Br J Cancer 84: 435–440 [DOI] [PMC free article] [PubMed] [Google Scholar]
  8. Fisher B, Costantino J, Redmond C, Fisher E, Margolese R, Dimitrov N, Wolmark N, Wickerham DL, Deutsch M, Ore L, Mamounas E, Poller W, Kavanah M (1993) Lumpectomy compared with lumpectomy and radiation therapy for the treatment of intraductal breast cancer. N Engl J Med 328: 1581–1586 [DOI] [PubMed] [Google Scholar]
  9. Fisher B, Costantino JP, Redmond CK, Fisher ER, Wickerham DL, Cronin WM (1994) Endometrial cancer in tamoxifen-treated breast cancer patients: findings from the National Surgical Adjuvant Breast and Bowel Project (NSABP) B-14. J Natl Cancer Inst 86: 527–537 [DOI] [PubMed] [Google Scholar]
  10. Fisher B, Dignam J, Wolmark N, Mamounas E, Costantino J, Poller W, Fisher ER, Wickerham DL, Deutsch M, Margolese R, Dimitrov N, Kavanah M (1998) Lumpectomy and radiation therapy for the treatment of intraductal breast cancer: findings from National Surgical Adjuvant Breast and Bowel Project B-17. J Clin Oncol 16: 441–452 [DOI] [PubMed] [Google Scholar]
  11. Fisher B, Dignam J, Wolmark N, Wickerham DL, Fisher ER, Mamounas E, Smith R, Begovic M, Dimitrov NV, Margolese RG, Kardinal CG, Kavanah MT, Fehrenbacher L, Oishi RH (1999) Tamoxifen in treatment of intraductal breast cancer: National Surgical Adjuvant Breast and Bowel Project B-24 randomised controlled trial. Lancet 353: 1993–2000 [DOI] [PubMed] [Google Scholar]
  12. Fornander T, Rutqvist LE, Cedermark B, Glas U, Mattson A, Silfverswärd C, Skoog L, Somell A, Theve T, Wilking N (1989) Adjuvant tamoxifen in early breast cancer: occurrence of new primary cancers. Lancet 1: 117–120 [DOI] [PubMed] [Google Scholar]
  13. Franceschi S, Levi F, La Vecchia C, Randimbison L, Te V-C (1998) Second cancers following in situ carcinoma of the breast. Int J Cancer 77: 392–395 [DOI] [PubMed] [Google Scholar]
  14. Frykberg ER, Santiago F, Betsill Jr WL, O'Brien PH (1987) Lobular carcinoma in situ of the breast. Surg Gynecol Obstet 164: 285–301 [PubMed] [Google Scholar]
  15. Gail MH, Costantino JP, Bryant J, Croyle R, Freedman L, Helzlsouer K, Vogel V (1999) Weighing the risks and benefits of tamoxifen treatment for preventing breast cancer. J Natl Cancer Inst 91: 1829–1846 [DOI] [PubMed] [Google Scholar]
  16. Gusberg SB (1990) Tamoxifen for breast cancer: associated endometrial cancer. Cancer 65: 1463–1464 [DOI] [PubMed] [Google Scholar]
  17. Habel LA, Moe RE, Daling JR, Holte S, Rossing MA, Weiss NS (1997) Risk of contralateral breast cancer among women with carcinoma in situ of the breast. Ann Surg 225: 69–75 [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. Hardell L (1988) Tamoxifen as a risk factor for carcinoma of corpus uteri. Lancet 3: 563. [DOI] [PubMed] [Google Scholar]
  19. Houghton J, George WD, Cuzick J, Duggan C, Fentiman IS, Spittle M (2003) Radiotherapy and tamoxifen in women with completely excised ductal carcinoma in situ of the breast in the UK, Australia, and New Zealand: randomised controlled trial. Lancet 362: 95–102 [DOI] [PubMed] [Google Scholar]
  20. Jack RH, Davies EA, Robinson D, Sainsbury R, Møller H (2007) Radiotherapy waiting times for women with breast cancer: a population-based study. BMC Cancer 7: 71 (http://www.biomedcentral.com/1471-2407/7/71) [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Julien JP, Bijker N, Fentiman IS, Peterse JL, Delledonne V, Rouanet P, Avril A, Sylvester R, Mignolet F, Bartelink H, van Dongen JA (2000) Radiotherapy in breast-conserving treatment for ductal carcinoma in situ: first results of the EORTC randomised phase III trial 10853. Lancet 355: 528–533 [DOI] [PubMed] [Google Scholar]
  22. Khandekar JD, Victor TA, Mukhopadhyaya P (1978) Endometrial carcinoma following estrogen therapy for breast cancer. Report of three cases. Arch Intern Med 138: 539–541 [PubMed] [Google Scholar]
  23. Levi F, Randimbison L, Te V-C, La Vecchia C (2005) Invasive breast cancer following ductal and lobular carcinoma in situ of the breast. Int J Cancer 116: 820–823 [DOI] [PubMed] [Google Scholar]
  24. Mathew A, Chabon AB, Kabakow B, Drucker M, Hirschman RJ (1990) Endometrial carcinoma in five patients with breast cancer on tamoxifen therapy. NY State J Med 90: 207–208 [PubMed] [Google Scholar]
  25. NHS Breast Screening Programme (2006) Annual Review 2006. Sheffield: NHS Cancer Screening Programmes [Google Scholar]
  26. Page DL, Kidd Jr TE, Dupont WD, Simpson JF, Rogers LW (1991) Lobular neoplasia of the breast: higher risk for subsequent invasive cancer predicted by more extensive disease. Hum Pathol 22: 1232–1239 [DOI] [PubMed] [Google Scholar]
  27. Rawal R, Lorenzo Bermejo J, Hemminki K (2005) Risk of subsequent invasive breast carcinoma after in situ breast carcinoma in a population covered by national mammographic screening. Br J Cancer 92: 162–166 [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Ringberg A, Nordgren H, Thorstensson S, Idvall I, Garmo H, Granstrand B, Arnesson LG, Sandelin K, Wallgren A, Anderson H, Emdin S, Holmberg L (2007) Histopathological risk factors for ipsilateral breast events after breast conserving treatment for ductal carcinoma in situ of the breast – results from the Swedish randomised trial. Eur J Cancer 43: 291–298 [DOI] [PubMed] [Google Scholar]
  29. Robinson D, Massey T, Davies E, Jack RH, Sehgal A, Møller H (2005) Waiting times for radiotherapy: variation over time and between cancer networks in southeast England. Br J Cancer 92: 1201–1208 [DOI] [PMC free article] [PubMed] [Google Scholar]
  30. Roychoudhuri R, Evans H, Robinson D, Møller H (2004) Radiation-induced malignancies following radiotherapy for breast cancer. Br J Cancer 91: 868–872 [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Rubino C, de Vathaire F, Shamsaldin A, Labbe M, Lê MG (2003) Radiation dose, chemotherapy, hormonal treatment and risk of second cancer after breast cancer treatment. Br J Cancer 89: 840–846 [DOI] [PMC free article] [PubMed] [Google Scholar]
  32. Soerjomataram I, Louwman WJ, van der Sangen MJC, Roumen RMH, Coebergh JWW (2006) Increased risk of second malignancies after in situ breast carcinoma in a population-based registry. Br J Cancer 95: 393–397 [DOI] [PMC free article] [PubMed] [Google Scholar]
  33. Ward BA, McKhann CF, Ravikumar TS (1992) Ten-year follow-up of breast carcinoma in situ in Connecticut. Arch Surg 127: 1392–1395 [DOI] [PubMed] [Google Scholar]
  34. Wärnberg F, Yuen J, Holmberg L (2000) Risk of subsequent invasive breast cancer after breast carcinoma in situ. Lancet 355: 724–725 [DOI] [PubMed] [Google Scholar]

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