Under-treatment of elderly patients with ovarian cancer: A population based study.pdf (BMC Cancer)

Fourcadier et al. BMC Cancer (2015) 15:937 DOI 10.1186/s12885-015-1947-9 RESEARCH ARTICLE Open Access Under-treatment of elderly patients with ovarian cancer: a population based study Elisabeth Fourcadier1, Brigitte Trétarre1, Claudine Gras-Aygon1, Fiona Ecarnot2, Jean-Pierre Daurès1 and Faïza Bessaoud1* Abstract Background: Ovarian cancer is the fourth most common cancer among women in France, and mainly affects the elderly. The primary objective of this study was to compare treatment of ovarian cancer according to age. Methods: All patients with invasive cancer (n = 1151) diagnosed between 1997 and 2011 in the Herault Department of southern France were included. Demographic data (age, area of residence), cancer characteristics (stage, histology, grade) and treatment modality (type, period and location of treatment) were analysed. Univariate and multivariate logistic regression was used to compare treatment by age. Results: Ovarian cancer was less treated in elderly compared to younger patients, regardless of the type of treatment. This difference was more pronounced for chemotherapy, and was maximal for surgery followed by chemotherapy (odds ratio (OR) for surgery for patients aged >70 vs those aged <70 years = 0.47 [0.24–0.91], OR for chemotherapy, age >70 vs <70 = 0.30 [0.16–0.55] and OR for surgery plus chemotherapy, age >70 vs <70 = 0.14 [0.08–0.28]). This effect of age was independent of other variables, including stage and grade. The probability of receiving standard treatment, in accordance with recommendations, was reduced by 50 % in elderly patients compared to their younger counterparts. Overall and net survival of elderly patients with standard treatment was similar to those of younger patients treated outside standard treatment. Conclusions: Elderly women with ovarian cancer were therapeutically disadvantaged compared to younger women. Further studies including co morbidities are necessary to refine these results and to improve therapeutic management of elderly patients with ovarian cancer. Keywords: Ovarian cancer, Elderly, Treatment pattern, Guidelines-recommended therapy, Survival Background Cancer is the second leading cause of death in women after cardiovascular disease. In France, the number of new cancer cases increased significantly between 1980 and 2012 [1]. This increase is largely due to the increase in population and aging, which automatically increases the number of cases, particularly those occurring in the elderly. In Western countries, ovarian cancer remains the leading gynecological cause of death [2]. Ovarian cancer represents the 6th cause of cancer and the 4th cause of death in women in France. Nearly 4600 new * Correspondence: faiza.bessaoud@orange.fr 1 Cancer Registry of Hérault Departement of France - ICM, 208, rue des apothicaires, 34298 Montpellier, Cedex 5, France Full list of author information is available at the end of the article cases are diagnosed, and nearly 3100 women die of this disease annually in France [1]. Ovarian cancer is a disease that is most common in the elderly, and its incidence increases with age to reach a peak during the 7th decade of life [3]. The populations in western countries tend to be aging; hence, the number of elderly women needing to be treated for ovarian cancer can be expected to increase [4]. Prior studies have shown that elderly women, compared to their younger counterparts, are more likely to have a delayed diagnosis or an advanced stage at diagnosis [5–7]. Furthermore, in elderly patients, the tumor characteristics (such as histology and stage) are often not investigated [8]. Furthermore, treatment of this disease is complex, consisting in consensus-based treatment defined according to stage and tumor grade. © 2015 Fourcadier et al. 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. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated. Fourcadier et al. BMC Cancer (2015) 15:937 Surgery and/or chemotherapy constitute the cornerstone of ovarian cancer treatment [9]. Such taxing treatment requires good physiological capacity, and many older people may have diminished physiological reserves, especially due to the presence of comorbidities. Consequently, many authors have addressed the issue of treatment of ovarian cancer in older women, highlighting significant disparities in senior health care. Several studies [4, 10–12] have shown that elderly patients with ovarian cancer have a poorer prognosis compared to their younger counterparts, due in part to undertreatment. Furthermore, when the elderly are treated, standard treatment guidelines are less frequently applied than for younger patients, and the elderly receive less aggressive therapy, even in the absence of comorbidity [13–15]. Based on these findings, our study hypothesis was that elderly women with ovarian cancer are under-treated. The main objective of this work was to investigate whether treatment practices differed between elderly women with ovarian cancer and their younger counterparts. Methods Study population This observational study included all ovarian cancer cases (ICD-O-3 code C56.9) (n = 1151) occurring among women diagnosed between January 1997 and December 2011, residing in the Hérault department of southern France. We excluded all patients with borderline tumors. Data recorded The tumor registry has existed in the Hérault department since 1983 and covers a population of more than one million inhabitants (1 062 036 according to the 2011 census). The registry records all cases of cancer occurring in this department in a continuous and exhaustive manner. All cases of ovarian cancer included in the present study were validated through systematic verification across original medical records. Demographic data, tumor characteristics (date of incidence, stage and grade at diagnosis) and treatment data (actual treatment given and location of treatment), as well as survival were determined in a reliable manner. This study was approved by two Ethics Committees for studies using human subjects (the Consultative Committee on Data Processing for Medical Research and the National authority for the protection of privacy and personal data) which provided approval to access routinely collected population-based cancer data in Hérault and which advocates that all medical information is confidential and anonymous and the need for individual informed consent was waived on the basis that the registry collects data already available in the patients’ medical files. Page 2 of 10 Variables Outcome variable The primary outcome variable analyzed in this study was the type of treatment. Firstly, this variable was used in binary form, i.e. patient had surgery (yes/no) and patient had chemotherapy (yes/no). Subsequently, it was analyzed in the form of treatment sequences or patterns. Four patterns were used (surgery alone, surgery followed by chemotherapy, chemotherapy alone or neo adjuvant, and no treatment). These patterns were derived from treatment guidelines and recommendations corresponding to the existing consensus for the treatment of ovarian cancer. The treatment strategy depended on the tumour stage and grade. Surgery was generally the first line treatment, with a view to full tumour resection. Surgery alone may be sufficient to treat early grade cancers (stages IA/IB and grade 1). For intermediate stage cancers (stages IC, II, III and grades 1–3), surgery is followed by chemotherapy with a view to eliminating any residual cancer cells and reducing the risk of relapse. When the tumour is diagnosed at an advanced stage (stage IV), chemotherapy may be performed before surgery to reduce the size of the tumour before resection, or may be used as a stand-alone approach. Finally, in our last model, we created a binary variable to record whether standard treatment was applied (yes/no), according to whether guidelines-recommended treatment was applied or not. Explanatory variables The main explanatory variable in this study was the age at diagnosis, divided into two classes, namely ≤70 years and >70 years old. Other variables considered were demographic data and cancer characteristics (stage, grade, histology). We recorded the area of residence (urban or rural). Tumour stage was recorded and classified into four groups according to the TNM classification system and International Federation of Gynecology and Obstetrics (FiGO) staging system (UICC 6th edition). In our study, tumor histology was classified according the World Health Organization (WHO) classification and grouped into epithelial type; other; or “unknown histology”, when there was no microscopic confirmation or no histological testing. The tumor grade was coded in three categories: welldifferentiated (grade 1), moderately differentiated (grade 2), and poorly differentiated (grade 3) or unknown. The healthcare establishment where the first treatment took place was categorized into: private for-profit clinics, public university teaching center (Public Univ.), public nonacademic (Public non Univ.) and Unknown or Outside the Hérault department (Unknown). The study period was divided into three classes: before (≤2002), during (2003–2007) and after (≥2008) the Fourcadier et al. BMC Cancer (2015) 15:937 national cancer plan. The national cancer plan mobilizes a national foundation for the organization healthcare and prevention, and provides support for research in the field of cancer. This plan includes the creation of an oncogeriatrics task force responsible for the promotion and coordination of projects in the field of epidemiology, prevention and adaptation of treatments and clinical trials in the elderly population [16]. The variables recorded for survival analysis included the date of diagnosis, the date of last contact and vital status (alive/deceased). Vital status was obtained from National Institute of Statistics and Economic Studies (INSEE) and the National Directory for the Identification of Individuals (RNIPP). The descriptive and comparative part of this study covers the period 1997–2011 and the survival analysis covers the period 1997–2010, with follow-up ending on 30/06/2013. Our descriptive and comparative analysis focuses on 1151 cases and the survival analysis on 1056 cases (692 deaths and 364 censored). Page 3 of 10 performed using the “relsurv” package specific to relative survival analysis. Results Among 1151 women diagnosed with invasive ovarian cancer, 38.9 % were elderly (≥70 years old). The average age was 64.7 years, median age was 66 years. Table 1 shows the characteristics of ovarian cancer according to age at diagnosis. Compared to younger women, elderly patients more frequently had their cancer diagnosed at a more advanced stage (p <0.0001); 12 % of elderly women presented stage I, compared to 24.5 % for younger women. Histological testing was often not performed or unknown in elderly women (p < 0.001) and the cancer grade was also more often unknown (p < 0.001). Younger women tended to be treated in Public university Table 1 Characteristics of ovarian cancer patients according to age Age Statistical analysis The chi square or Fisher’s exact test were used, as appropriate, to compare cancer characteristics according to age. Univariate and multivariate analysis using logistic regression were used to identify the association between treatment (Surgery and Chemotherapy: yes/No) and age, adjusted for other factors such as stage, grade, histological research, treatment location, and area of residence. Multivariate logistic regression was used to analyze the treatment pattern (surgery alone, surgery followed by chemotherapy, chemotherapy alone or neo-adjuvant chemotherapy, vs. no treatment) according to age. The Kappa test was used to assess agreement between the treatment administered and the treatment recommended by current guidelines. Overall survival was estimated according the Kaplan-Meier method. Net survival (survival if the cause of death under consideration was the only cause of death) is now recommended as a substitute for relative survival methods in current use, to evaluate population-based cancer survival [17, 18]. We estimated net survival using the non-parametric Pohar Perme estimator [19], which is based on the mortality rate of the general population and provides unbiased estimates of net survival. Overall survival curves were compared using the log rank test. All tests were twosided and a p-value <0.05 was considered statistically significant. A Cox regression model was used to estimate hazard ratios for overall mortality, with adjustment for age and other confounding factors including grade and stage. We verified the conditions of application of the model by testing the proportionality of risks. All statistical analyses were performed with the R software package. Net survival analysis was ≤70 years (N = 703) >70 years (N = 448) N N % P value for Chi2 % Stage <0.0001 I 172 24.5 % 54 12.1 % II 47 6.7 % 24 5.4 % III 328 46.7 % 227 50.7 % IV 122 17.4 % 115 25.7 % Unkown 34 4.8 % 28 6.3 % Grade 0.0003 (0.0676*) 1 62 8.8 % 19 4.3 % 2 120 17.1 % 61 13.6 % 3 150 21.3 % 79 17.6 % Unkown 371 52.8 % 289 64.5 % Epithelial 655 93.2 % 379 84.6 % Other 39 5.6 % 8 1.8 % No histology 9 1.3 % 61 13.6 % Private 386 54.9 % 265 59.1 % Public Univ. 240 34.1 % 120 26.8 % Public non-Univ. 51 7.3 % 33 7.4 % Unkown 26 3.7 % 30 6.7 % Histology <0.0001 Treatment location 0.0137 (0.0676*) Period of diagnosis 0.5509 ≤2002 279 39.7 % 164 36.6 % 2003–2007 220 31.3 % 144 32.1 % ≥2008 204 29,0 % 140 31.3 % Area of residence 0.5343 Urban 598 85.6 % 387 86.4 % Rural 105 14.9 % 61 13.6 % *p-value when modality ‘Unknown’ was excluded from analysis Fourcadier et al. BMC Cancer (2015) 15:937 Page 4 of 10 hospitals, whereas elderly patients tended to be treated in private clinics, although the difference was not statistically significant (p = 0.06). The period of diagnosis and the area of residence did not differ according to age. Tables 2 and 3 show the associations between treatment (surgery or chemotherapy) and age, and other potential confounding factors. Compared to their younger counterparts, elderly women less often underwent surgical treatment (60.9 % versus 89.6 %, p < 0.001) and chemotherapy (57.4 % versus 76.4 %, p < 0.001). After adjustment for cancer characteristics (stage, grade, histology and other adjuvant treatments), we observed that elderly women were 3.6 less likely to have surgical treatment (OR = 0.28 [0.19–0.41]) and three times less likely to undergo chemotherapy (OR = 0.34 [0.24–0.48]). Based on the assumption that the association between treatment and age could differ according the stage at diagnosis, we performed a stratified analysis, which showed that the association between age and surgery was significantly different according to cancer stage. For early stages I-II, surgical treatment did not differ according age (OR >70 vs ≤70 = 0.17 [0.01– Table 2 Univariate and multivariate analysis of the association between demographic and cancer characteristics and treatment by surgery Age Surgery (N = 903) No surgery (N = 243) N % N % ≤70 630 89.6 % 73 10.4 % >70 273 60.9 % 175 39.1 % I-II 295 99.3 % 2 0.7 % III 448 80.7 % 107 IV 128 54.0 % 109 Unkown 32 51.6 % 30 48.4 % yes 677 84.3 % 126 15.7 % no 226 64.9 % 122 31.5 % p Univariate analysis Multivariate analysis OR (95%CI) ORa (95%CI) 1 1 0.18 (0.13–0.25) 0.28 (0.19–0.41) 125.59 (30.5–516.35) 153.42 (35.67–659.9) 19.3 % 3.56 (2.56–4.97) 4.46 (2.97–6.72) 46.0 % 1 1 0.91 (0.52–1.6) 3.69 (1.33–10.25) 2.94 (2.17–3.85) 2.51 (1.58–3.97) 1 1 <0.0001 Stage Adjuvant treatment Histology <0.0001 <0.0001 <0.0001 Epithelial 856 82.8 % 178 17.2 % 1 1 Other 46 97.9 % 1 2.1 % 9.56 (1.31–69.81) 8.4 (1.05–67.44) No histology 1 1.4 % 69 98.6 % 0.003 (0.001–0.02) 0.01 (0.14–0.79) Grade <0.0001 1 73 90.1 % 8 9.9 % 1 1 2 763 97.7 % 18 2.3 % (0.4595*) 0.99 (0.41–2.39) 1.94 (0.72–5.28) 3 198 86.5 % 31 13.5 % 0.70 (0.31–1.59) 1.63 (0.63–4.19) Unkown 469 71.1 % 191 28.9 % 0.27 (0.13–0.57) 0.82 (0.35–1.96) Private 543 83,4 % 108 16.6 % 0.0001 1.37 (0.99–1.89) 2.00 (1.30–3.08) (0.0015*) Treatment location Public Univ. 283 78,6 % 77 21.4 % 1 1 Public non-Univ. 57 67,9 % 27 32.1 % 0.57 (0.34–0.97) 0.65 (0.31–1.34) Unkown 20 35,7 % 36 64.3 % 0.15 (0.08–0.28) 0.33 (0.14–0.79) ≤2002 348 78.6 % 95 21.4 % 2003–2007 292 80.2 % 72 19.8 % ≥2008 263 76.5 % 81 23.5 % Rural 132 79.5 % 34 20.5 % Urban 771 78.3 % 214 21.7 % Period of diagnosis 0.4751 Area of residence 0.7184 OR (95%CI) Odd Ratio and 95 % Confidence Interval, ORa Odd Ratios were adjusted for factors associated with treatment with a p-value <0.10 by univariate analysis *p-value when modality ‘Unknown’ was excluded from analysis Fourcadier et al. BMC Cancer (2015) 15:937 Page 5 of 10 Table 3 Univariate and multivariate analysis of the association between demographic and cancer characteristics and treatment by chemotherapy Age Chemotherapy (N = 794) No chemotherapy (N = 357) N % N % ≤70 537 76.4 % 166 23.6 % >70 257 57.4 % 191 42.6 % I-II 147 49.5 % 150 50.5 % III 459 82.7 % 96 17.3 % p <0.0001 Univariate Multivariate OR (95 % CI) ORa (95 % CI) 1 1 0.42 (0.32–0.54) 0.34 (0.24–0.48) 0.36 (0.25–0.52) 0.13 (0.08–0.21) 1.77 (1.23–2.54) 1.28 (0.83–1.97) Stage IV Adjuvant treatment <0.0001 173 73.0 % 64 27.0 % 1 1 15 24.2 % 47 75.8 % 0.12 (0.06–0.23) 0.14 (0.06–0.32) yes 677 74.2 % 235 25.8 % 3.03 (2.22–4) 2.60 (1.67–4.05) no 117 49.0 % 122 51.0 % 1 1 Epithelial 765 74.0 % 269 26.0 % 1 1 Other 17 36.2 % 30 63.8 % 0.20 (0.11–0.37) 0.37 (0.18–0.76) No histology 12 17.1 % 58 82.9 % 0.07 (0.04–0.14) 0.23 (0.11–0.48) 1 48 59.3 % 33 40.7 % 1 1 2 144 79.6 % 37 20.4 % 2.68 (1.51–4.74) 2.01 (1.04–3.89) 3 197 86.0 % 32 14.0 % 4.23 (2.37–7.56) 2.85 (1.48–5.50) Unkown 405 61.4 % 255 38.6 % 1.09 (0.68–1.75) 1.31 (0.75–2.27) Private 467 71.7 % 184 28.3 % 0.91 (0.68–1.22) 1.15 (0.81–1.63) Public Univ. 265 73.6 % 95 26.4 % 1 1 Public non-Univ. 40 47.6 % 44 52.4 % 0.33 (0.20–0.53) 0.41 (0.23–0.75) Unkown 22 39.3 % 34 60.7 % 0.23 (0.13–0.42) 0.37 (0.17–0.78) ≤2002 298 67.3 % 145 32.7 % 1 1 2003–2007 265 73.0 % 98 27.0 % 1.30 (0.96–1.77) 1.78 (1.23–2.57) ≥2008 231 67.2 % 113 32.8 % 0.99 (0.74–1.34) 1.26 (0.87–1.83) Rural 115 69.3 % 51 30.7 % Urban 679 68.9 % 306 31.1 % Histology <0.0001 <0.0001 Grade <0.0001 Treatment location <0.0001 Period of diagnosis 0.1637 Area of residence 0.9297 OR (95%CI) Odd Ratio and 95 % Confidence Interval, ORa Odd Ratios were adjusted for factors associated with treatment with a p-value <0.10 by univariate analysis * p-value when modality ‘Unknown’ was excluded from analysis 4.45], p = 0.2858). However, for stage III, there was a significant association between surgery and age, with elderly patients having a significantly lower likelihood of surgery (OR >70 vs ≤70 = 0.17 [0.09–0.30]), and there was a similar, albeit non-significant trend for stage IV (OR >70 vs ≤70 = 0.56 [0.31–1.03]). The association between chemotherapy and age was also stratified according stage at diagnosis, but there were no significant differences. The regression models including an interactive term between age and stage confirmed the findings of our stratified analysis. With the exception of the area of residence, all variables were significantly related to the three different treatment pathways (surgery alone, surgery + chemotherapy, chemotherapy alone or neo-adjuvant) (Table 4). Multivariate regression adjusted for cancer characteristics (stage, grade, histology), treatment location and period of diagnosis showed that there was a significant difference between elderly patients and their younger counterparts in terms of all treatment sequences. Regardless of the treatment pattern, elderly patients received less treatment. We observed a gradient effect Fourcadier et al. BMC Cancer (2015) 15:937 Page 6 of 10 Table 4 Demographic and cancer characteristics by treatment patterns Age Stage Grade Histology No treatment Surgery alone Surgery + Chemotherapy Chemotherapy alone or neo adjuvant Mod. N % N % N % N % <= 70 years 28 3.9 % 138 19.7 402 57.3 134 19 >70 years 96 21.5 % 93 20.9 % 142 31.9 115 25.8 1-II 1 0.3 % 149 50.2 % 139 46.8 % 8 2.7 % III 50 9.0 % 45 8.1 % 325 58.7 % 134 24.2 % IV 46 19.6 % 17 7.2 % 70 29.8 % 102 43.4 % Unkown 27 43.6 % 20 32.3 % 10 16.1 % 5 8.1 % 1 2 2.5 % 31 38.3 % 34 41.9 % 14 17.3 % 2 4 2.2 % 32 17.8 % 108 60 % 36 20 % 3 9 3.9 % 22 9.7 % 133 58.3 % 64 28.1 % Unkown 109 16.5 % 146 22.2 % 269 40.8 % 135 20.5 % No histology 58 82.9 % 0 0% 1 1.4 % 11 15.7 % Other 0 0% 30 63.8 % 16 34.0 % 1 2.1 % Epithelial 66 6.4 % 201 19.5 % 527 52.1 % 237 22.9 % Period of diagnosis <=2002 Treat. location Area of residence 46 10.4 % 99 22.4 % 219 49.6 % 78 17.7 % 2003–2007 34 9.4 % 64 17.7 % 193 53.2 % 72 19.8 % > = 2008 44 12.9 % 68 19.8 % 132 34.5 % 99 28.9 % Private 41 6% 141 21.7 % 336 51.8 % 131 20.2 % Public Univ 33 9.2 % 62 17. 163 45.4 % 101 28.1 % Public non-Univ 20 23.8 % 24 28.6 % 30 35.7 % 30 11.9 % Unknown 30 53.6 % 4 7.1 % 15 26.8 % 7 12.5 % Rural 17 10.3 % 34 20.6 % 82 49.7 % 32 19.4 % Urban 1077 10.9 % 197 20.0 % 462 47 % 217 22.1 % between treatment and age linked to the introduction of chemotherapy and its association with surgery: for surgery OR >70 vs ≤70 years = 0.46 [0.16–0.55], for chemotherapy OR >70 vs ≤70 years = 0.29 [0.16–0.55] and OR >70 vs ≤70 years = 0.13 [0.08–0.25] for surgery plus chemotherapy (data not shown). The concordance test (data not shown) showed that younger patients had a 34 % [26–42 %] chance of receiving guidelines-recommended therapy, whereas elderly patients had only a 19 % [11–27 %] chance, p <0.001. By univariate analysis, the variables associated with the application of standard (guidelines-recommended) treatment were age (p <0.0001), stage (p = 0.0019) and histology (p = 0.0443). Multivariate analysis showed that elderly patients had more than 50 % less likelihood of receiving guidelines-recommended therapy (OR = 0.48 [0.36–0.64]) (Table 5). For the survival analysis, 1056 women were followed between 1997 and 2010, including 692 deaths and 364 censored. The median was 39.4 months for overall survival, and 39.9 for net survival. Overall and net survival plotted by the Kaplan Meier stratified according to the implementation (or not) of standard guidelines-recommended therapy, P-value <0.0001 <0.0001 <0.0001 <0.0001 0.0003 0.0001 0.8609 showed that elderly patients had poorer survival than younger patients (log-rank test p < 0.001), all the more so when guidelines-recommended was not administered in the elderly (Fig. 1a and b). Use of guidelinesrecommended therapy improved survival in elderly women, bringing it up to a level almost equivalent to survival in younger women who did not receive guidelines-recommended treatment. There was no significant difference in use of guidelines-recommended therapy in older vs younger women for survival durations <10 years (p = 0.20). However, a significant difference was observed when overall survival exceeded 10 years (p = 0.02) and a trend towards a difference was observed for net survival (p = 0.08). In a Cox regression model for overall mortality, including terms for age, stage, grade, histology and standard of treatment (Table 6), older age (>70 years) was associated with an almost twofold increase in the risk of death, and stage III and stage IV disease were associated with significantly greater risks of death compared with stage I disease (hazard ratios of 3.8 and 5.2, respectively). Application of standard (guidelines-recommended) therapy was also associated with a significant reduction in the relative risk of death Fourcadier et al. BMC Cancer (2015) 15:937 Page 7 of 10 Table 5 Multivariate analysis of the factors associated with application of guidelines-recommended therapy Age Stage Grade Histology Treatment location Standard treatment applied = No Standard treatment applied = yes ORa (95 % CI) N % N % <= 70 169 30.2 % 390 69.8 % 1 >70 153 47.9 % 166 52,0 % 0.48 (0.36–0.64) I-II 60 31.4 % 131 68.6 % 1 III 172 34.6 % 325 65.4 % 1.81 (1.2–2.81) IV 90 47.4 % 100 52.6 % 1.64 (1.16–2.33) 1 24 32.8 % 49 67.1 % 1 2 56 32.9 % 114 67.1 % 1.17 (0.64–2.14) 3 73 34.1 % 141 65.9 % 1.17 (0.64–2.11) Unknown 169 40.1 % 252 59.9 % 0.95 (0.55–1.67) No histology 6 60,0 % 4 40,0 % 1 Epithelial 305 35.9 % 544 64.1 % 0.62 (0.17–2.3) Other 11 57.9 % 8 42.1 % 0.37 (0.14–0.98) Private 188 35.9 % 335 64.1 % 1.33 (0.97–1.82) Public Univ. 122 39.7 % 170 60.3 % 1 Public non-Univ. 16 32,0 % 34 68,0 % 1.56 (0.78–3.06) Unknown 6 26.1 % 17 73.9 % 0.96 (0.54–1.67) OR (95%CI) Odd Ratio and 95 % Confidence Interval, ORa Odd Ratios were adjusted for factors associated with treatment with a p-value <0.10 by univariate analysis (hazard ratio = 0.74) after adjustment for age, stage, grade and histology. Discussion Our study shows that elderly women with ovarian cancer receive less treatment than their younger counterparts, regardless of the type of treatment considered. We found that the difference between age groups was greater for chemotherapy than for surgery, and was highest for the combination of surgery plus chemotherapy. The cancer characteristics being equal, elderly women had less chance of receiving standard therapy, i.e. the recommended treatment by current guidelines. Elderly patients in whom guidelines-recommended treatment was not applied had poorer likelihood of survival as compared to elderly patients who received guidelines-recommended therapy, and as compared to younger women. In line with previous reports [4–6, 13, 20, 21], our findings also show that ovarian cancer in elderly women were more often discovered at an advanced stage as compared to younger women, and are less often submitted to histological testing. We found that elderly women with ovarian cancer were three times less likely to have chemotherapy than younger women. As regards surgery, elderly patients were 3.6 times less likely to have surgical treatment than their younger counterparts. The association between surgical treatment and age was different according to cancer stage at diagnosis, since treatment differences were age-related for the higher stages rather than lower stages. Our results are in line with several previous studies [4, 5, 11, 13, 14, 22], and in particular, our findings are concordant with two recent studies [11, 13] showing that age is an independent predictor of non-administration of either surgery or chemotherapy. Despite medical progress, and the introduction of a national cancer plan by the French government in 2003 to promote better management of cancer patients and highlight the problem of health inequity, our study, like several others [5, 11, 13, 14, 20], found that elderly patients were less likely to be treated as aggressively as younger patients. The association between treatment and age showed a gradient effect linked to the use of chemotherapy. Indeed, compared to younger patients, elderly women had less surgery, and the chances of being treated decreased even more when chemotherapy was the treatment of choice, and even further still when chemotherapy was combined with surgery. Furthermore, we showed than standard guidelines-recommended therapy was less frequently applied in the elderly, and hence, elderly patients were 50 % less like to receive standard therapy than younger patients. The reasons for this discrepancy could be related to more advanced disease, or to functional impairment in the elderly, which may be incompatible with implementation of recommended treatment. However, some studies have reported that age remains an independent predictor of under-treatment. Recent reports [4, 11, 14, 23] have Fourcadier et al. BMC Cancer (2015) 15:937 Page 8 of 10 Fig. 1 10-year overall survival (panel a) and net survival (panel b) by age and treatment recommendation suggested that elderly patients are much less likely to receive standard treatment, even after adjusting for comorbidities. Maas et al reported in a population of patients with FIGO II or III ovarian cancer that elderly (≥70 years) patients were seven times less likely to receive guidelinesrecommended treatment (surgery + chemotherapy) than younger patients, even after adjustment for comorbidities (OR ≥70 vs <70 years = 0.14 [0.07 to 0, 21] and OR comorbidities vs no comorbidities = 0.91 [0.78 to 0.93]) [14]. This suggests that under treatment cannot be explained by poorer functional status in elderly patients. Other potential explanatory factors could include patient and/or physician choices. The strengths of this study include its 14 year coverage of all cancer cases in the Herault Department, the relatively large size (1151 incident cases) and its populationbased nature. We analyzed the variable “treatment” in the form of treatment sequences, which is rarely found in the literature, and confirmed our hypothesis that elderly women with ovarian cancer are under-treated. Another strongpoint is the use of a variable to take compliance with guidelines into account, by evaluating the application of guidelines-recommended therapy. This variable allowed us to highlight that older women were two times less likely to receive guidelines-recommended treatment than younger women, and this had a Fourcadier et al. BMC Cancer (2015) 15:937 Page 9 of 10 Table 6 Adjusted effect of age on overall mortality by multivariate Cox regression analysis HR Age Stage Grade Histology Standard treatment 95 % CI <= 70 1 >70 1.96 I–II 1 III 3.78 (2.84–5.03) IV 5.18 (3.77–7.12) 1 1 2 1.36 (0.90–2.05) 3 1.05 (0.69–1.58) Unknown 1.38 (0.84–2.02) No histology 1.52 (0.80–2.88) Epithelial 1 Other 1.35 (0.69–2.64) No 1 (0.62–0.89) Yes 0.74 (1.65–2.33) HR (95%CI) Hazard Ratio and 95 % Confidence Interval deleterious effect on overall survival. Indeed, overall survival in elderly women who did not receive standard treatment was worse than overall survival younger women, but it was also worse than elderly women who did receive standard treatment. Our study suffers from some limitations. The analysis did not take into account factors such as comorbidities or functional status because these variables were not available in the registry. However, the fact that overall survival in this study was similar to the net survival (defined as the survival that would be observed if cancer was the only possible cause of death) suggests that the effect of comorbidities could be negligible, and probably did not modify the independent effect of age on treatment. In our study, we chose to present the results in terms of net survival, as calculated using the Pohar Perme estimator [19]. This estimator of net survival has been shown in the literature to be more appropriate for registry data [17, 18]. This is due to the fact that classical “relative-survival” methods used to estimate net survival provide biased estimates. The Pohar-Perme net survival estimator may be prone to random variation and result in biased estimates when exact follow-up times are not available, or when follow-up is incomplete [24]. However, this situation is avoided in our study, since survival data (i.e. follow-up times) recorded in the registry was exhaustive, we have exact data on the number of deaths or patients lost to follow-up, with the exact dates when the events occurred. Our analysis is therefore not at risk of biased estimates, since the exact follow-up times are known, and the follow-up is fully complete. Second, there was a considerable proportion of missing data. However, our data show that diagnostic tests (grade, stage, histology) are more often overlooked in elderly patients vs their younger counterparts. The fact that there are many patients with unknown histology or unknown grade is precisely the reflection of this phenomenon, as this indicates that the diagnosis is not pursued in detail to obtain this information in elderly patients. This could also be explained by the fact that the group of patients who underwent surgery comprises patients who had surgery after having chemotherapy, which may render analysis of the surgical specimens more difficult, or even impossible, thus leading to more missing data. Furthermore, no information about the reasons for non-treatment, or the treatment modalities (e.g. type of surgery: complete or incomplete debulking) was available in our data. As highlighted by literature data [25], there exist large inequalities in access to healthcare and this is particularly valid for the elderly. We cannot exclude the fact that elderly patients differ with respect to their tolerance of treatment and their comorbidities, and some elderly patients might yield benefit from more aggressive therapy than they actually receive in reality. Previous studies [21, 26, 27] have indicated that in general, the elderly tolerate surgery well and are able to tolerate chemotherapy in the same conditions and modalities (schedule, dosage, complete courses…) as their younger counterparts. Therefore, age itself does not constitute the sole reason for withholding treatment. Although age was found to have an independent effect on undertreatment in our study, further research is warranted to evaluate whether this effect persists when individual comorbidities and treatment patterns (e.g. type of surgery, duration of treatment, completion of treatment,…) are accounted for, as these are all factors that may contribute to under-treatment of elderly patients. Other variables that were not available in our study may also influence the association between treatment and age. One study reported that being cared for by a gynecologic oncologist influenced the type of treatment administered, and for advanced stages (FIGO III or IV), treatment by a gynecologic oncologist increased the probability of receiving chemotherapy twofold [10]. Other variables such as marital status or socio-economic status also deserve be taken into account, since some studies have suggested that single people or people with a low level of education are more likely to have chemotherapy [15]. Conclusion In conclusion, our study showed that elderly were under treated. For similar cancer characteristics, the probability of undergoing guidelines-recommended treatment was twotimes lower in elderly patients compared to the younger Fourcadier et al. BMC Cancer (2015) 15:937 counterparts. Elderly patients have improved likelihood of survival when recommended treatment is applied. Further research, however, is warranted to investigate whether the independent effect of age persists in the presence of comorbidity. Acknowledging the under-treatment of elderly patients constitutes a first step in the broader process of improving therapeutic management of these patients. Several possibilities for improving patterns of care have been proposed. Geriatric assessment could help determine which patients are too frail to undergo standard treatment, and is essential for the initiation of treatment, particularly burdensome therapy. Abbreviations OR: Odd Ratio; HR: Hazard Ratio; CI: Confidence Interval. Competing interests The authors declare that they have no competing interests. Authors’ contributions FB and BT have made substantial contributions to conception and design; BT and FB have contributed to the acquisition of data. CAG and FB controlled the quality of data. EF, FB, JPD and BT analyzed and interpreted data and statistics. EF, FE and FB prepared and edited the manuscript. All authors read and approved the final manuscript. Acknowledgements We would like to thank all those who contributed to this work, especially the pathologists, oncologists, Department of Medical Data Processing of public and private hospitals and medical practitioners for access to medical records. Author details 1 Cancer Registry of Hérault Departement of France - ICM, 208, rue des apothicaires, 34298 Montpellier, Cedex 5, France. 2Department of Cardiology, EA3920, University Hospital Besançon, Besançon, France. Received: 21 April 2015 Accepted: 20 November 2015 References 1. Binder-Foucard F, Bossard N, Delafosse P, Belot A, Woronoff A-S, Remontet L, et al. Cancer incidence and mortality in France over the 1980-2012 period: solid tumors. Rev Dépidémiologie Santé Publique. 2014;62(2):95–108. 2. Jemal A, Siegel R, Xu J, Ward E. Cancer statistics, 2010. CA Cancer J Clin oct. 2010;60(5):277–300. 3. Yancik R, Ries LG, Yates JW. Ovarian cancer in the elderly: an analysis of Surveillance, Epidemiology, and End Results Program data. Am J Obstet Gynecol. 1986;154(3):639–47. 4. Petignat P, Fioretta G, Verkooijen HM, Vlastos AT, Rapiti E, Bouchardy C, et al. Poorer survival of elderly patients with ovarian cancer: a populationbased study. Surg Oncol. 2004;13(4):181–6. 5. Ries LA. Ovarian cancer. Survival and treatment differences by age. Cancer. 1993;71(2 Suppl):524–9. 6. Chi DS, Liao JB, Leon LF, Venkatraman ES, Hensley ML, Bhaskaran D, et al. Identification of prognostic factors in advanced epithelial ovarian carcinoma. Gynecol Oncol. 2001;82(3):532–7. 7. Markman M, Lewis JL, Saigo P, Hakes T, Rubin S, Jones W, et al. Impact of age on survival of patients with ovarian cancer. Gynecol Oncol. 1993;49(2):236–9. 8. de Rijke JM, Schouten LJ, Schouten HC, Jager JJ, Koppejan AG, van den Brandt PA. Age-specific differences in the diagnostics and treatment of cancer patients aged 50 years and older in the province of Limburg, The Netherlands. Ann Oncol Off J Eur Soc Med Oncol ESMO. 1996;7(7):677–85. 9. Aebi S, Castiglione M, ESMO Guidelines Working Group. Epithelial ovarian carcinoma: ESMO clinical recommendations for diagnosis, treatment and follow-up. Ann Oncol Off J Eur Soc Med Oncol ESMO. 2008;19 Suppl 2:ii14–6. 10. Cress RD, O’Malley CD, Leiserowitz GS, Campleman SL. Patterns of chemotherapy use for women with ovarian cancer: a population-based study. J Clin Oncol Off J Am Soc Clin Oncol. 2003;21(8):1530–5. Page 10 of 10 11. Jordan S, Steer C, DeFazio A, Quinn M, Obermair A, Friedlander M, et al. Patterns of chemotherapy treatment for women with invasive epithelial ovarian cancer–a population-based study. Gynecol Oncol. 2013;129(2):310–7. 12. Chan JK, Urban R, Cheung MK, Osann K, Shin JY, Husain A, et al. Ovarian cancer in younger vs older women: a population-based analysis. Br J Cancer. 2006;95(10):1314–20. 13. Jørgensen TL, Teiblum S, Paludan M, Poulsen LØ, Jørgensen AYS, Bruun KH, et al. Significance of age and comorbidity on treatment modality, treatment adherence, and prognosis in elderly ovarian cancer patients. Gynecol Oncol. 2012;127(2):367–74. 14. Maas HA, Kruitwagen RF, Lemmens VE, Goey SH, Janssen-Heijnen ML. The influence of age and co-morbidity on treatment and prognosis of ovarian cancer: a population-based study. Gynecol Oncol. 2005;97(1):104–9. 15. Carney ME, Lancaster JM, Ford C, Tsodikov A, Wiggins CL. A populationbased study of patterns of care for ovarian cancer: who is seen by a gynecologic oncologist and who is not? Gynecol Oncol. 2002;84(1):36–42. 16. Les Plans cancer de 2003 à 2013 - Plan cancer | Institut National Du Cancer [Internet]. [cité 28 sept 2015]. Disponible sur: http://www.e-cancer.fr/Plancancer/Les-Plans-cancer-de-2003-a-2013 17. Danieli C, Remontet L, Bossard N, Roche L, Belot A. Estimating net survival: the importance of allowing for informative censoring. Stat Med. 2012;31(8):775–86. 18. Roche L, Danieli C, Belot A, Grosclaude P, Bouvier AM, Velten M, et al. Cancer net survival on registry data: use of the new unbiased Pohar-Perme estimator and magnitude of the bias with the classical methods. Int J Cancer. 2013;132:2359–69. 19. Perme MP, Stare J, Estève J. On estimation in relative survival. Biometrics. 2012;68(1):113–20. 20. Yancik R. Ovarian cancer. Age contrasts in incidence, histology, disease stage at diagnosis, and mortality. Cancer. 1993;71(2 Suppl):517–23. 21. Hightower RD, Nguyen HN, Averette HE, Hoskins W, Harrison T, Steren A. National survey of ovarian carcinoma. IV: Patterns of care and related survival for older patients. Cancer. 1994;73(2):377–83. 22. Hershman D, Fleischauer AT, Jacobson JS, Grann VR, Sundararajan V, Neugut AI. Patterns and outcomes of chemotherapy for elderly patients with stage II ovarian cancer: a population-based study. Gynecol Oncol. 2004;92(1):293–9. 23. Uyar D, Frasure HE, Markman M, von Gruenigen VE. Treatment patterns by decade of life in elderly women (> or =70 years of age) with ovarian cancer. Gynecol Oncol. 2005;98(3):403–8. 24. Seppä K, Hakulinen T, Pokhrel A. Choosing the net survival method for cancer survival estimation. Eur J Cancer Oxf Engl 1990. 2015;51(9):1123–9. 25. Bouchardy C, Rapiti E, Blagojevic S, Vlastos A-T, Vlastos G. Older female cancer patients: importance, causes, and consequences of undertreatment. J Clin Oncol Off J Am Soc Clin Oncol. 2007;25(14):1858–69. 26. Bicher A, Sarosy G, Kohn E, Adamo DO, Davis P, Jacob J, et al. Age does not influence taxol dose intensity in recurrent carcinoma of the ovary. Cancer. 1993;71(2 Suppl):594–600. 27. Thigpen T, Brady MF, Omura GA, Creasman WT, McGuire WP, Hoskins WJ, et al. Age as a prognostic factor in ovarian carcinoma. The Gynecologic Oncology Group experience. Cancer. 1993;71(2 Suppl):606–14. Submit your next manuscript to BioMed Central and we will help you at every step: • We accept pre-submission inquiries • Our selector tool helps you to find the most relevant journal • We provide round the clock customer support • Convenient online submission • Thorough peer review • Inclusion in PubMed and all major indexing services • Maximum visibility for your research Submit your manuscript at www.biomedcentral.com/submit

Under-treatment of elderly patients with ovarian cancer: A population based study

Nội dung