@article { , title = {Improving outcomes for women aged 70 years or above with early breast cancer: research programme including a cluster RCT}, abstract = {Background: In breast cancer management, age-related practice variation is widespread, with older women having lower rates of surgery and chemotherapy than younger women, based on the premise of reduced treatment tolerance and benefit. This may contribute to inferior outcomes. There are currently no age-and fitness-stratified guidelines on which to base treatment recommendations. Aim: We aimed to optimise treatment choice and outcomes for older women (aged > 70 years) with operable breast cancer. Objectives: Our objectives were to (1) determine the age, comorbidity, frailty, disease stage and biology thresholds for endocrine therapy alone versus surgery plus adjuvant endocrine therapy, or adjuvant chemotherapy versus no chemotherapy, for older women with breast cancer; (2) optimise survival outcomes for older women by improving the quality of treatment decision-making; (3) develop and evaluate a decision support intervention to enhance shared decision-making; and (4) determine the degree and causes of treatment variation between UK breast units. Design: A prospective cohort study was used to determine age and fitness thresholds for treatment allocation. Mixed-methods research was used to determine the information needs of older women to develop a decision support intervention. A cluster-randomised trial was used to evaluate the impact of this decision support intervention on treatment choices and outcomes. Health economic analysis was used to evaluate the cost-benefit ratio of different treatment strategies according to age and fitness criteria. A mixed-methods study was used to determine the degree and causes of variation in treatment allocation. Main outcome measures: The main outcome measures were enhanced age-and fitness-specific decision support leading to improved quality-of-life outcomes in older women (aged > 70 years) with early breast cancer. Results: (1) Cohort study: The study recruited 3416 UK women aged > 70 years (median age 77 years). Follow-up was 52 months. (a) The surgery plus adjuvant endocrine therapy versus endocrine therapy alone comparison: 2854 out of 3416 (88\%) women had oestrogen-receptor-positive breast cancer, 2354 of whom received surgery plus adjuvant endocrine therapy and 500 received endocrine therapy alone. Patients treated with endocrine therapy alone were older and frailer than patients treated with surgery plus adjuvant endocrine therapy. Unmatched overall survival and breast-cancer-specific survival were higher in the surgery plus adjuvant endocrine therapy group (overall survival: Hazard ratio 0.27, 95\% confidence interval 0.23 to 0.33; p < 0.001; breast-cancer-specific survival: Hazard ratio 0.41, 95\% confidence interval 0.29 to 0.58; p < 0.001) than in the endocrine therapy alone group. In matched analysis, surgery plus adjuvant endocrine therapy was still associated with better overall survival (hazard ratio 0.72, 95\% confidence interval 0.53 to 0.98; p = 0.04) than endocrine therapy alone, but not with better breast-cancer-specific survival (hazard ratio 0.74, 95\% confidence interval 0.40 to 1.37; p = 0.34) or progression-free-survival (hazard ratio 1.11, 95\% confidence interval 0.55 to 2.26; p = 0.78). (b) The adjuvant chemotherapy versus no chemotherapy comparison: 2811 out of 3416 (82\%) women received surgery plus adjuvant endocrine therapy, of whom 1520 (54\%) had high-recurrence-risk breast cancer [grade 3, node positive, oestrogen receptor negative or human epidermal growth factor receptor-2 positive, or a high Oncotype DX® (Genomic Health, Inc., Redwood City, CA, USA) score of > 25]. In this high-risk population, there were no differences according to adjuvant chemotherapy use in overall survival or breast-cancer-specific survival after propensity matching. Adjuvant chemotherapy was associated with a lower risk of metastatic recurrence than no chemotherapy in the unmatched (adjusted hazard ratio 0.36, 95\% confidence interval 0.19 to 0.68; p = 0.002) and propensity-matched patients (adjusted hazard ratio 0.43, 95\% confidence interval 0.20 to 0.92; p = 0.03). Adjuvant chemotherapy improved the overall survival and breast-cancer-specific survival of patients with oestrogen-receptor-negative disease. (2) Mixed-methods research to develop a decision support intervention: An iterative process was used to develop two decision support interventions (each comprising a brief decision aid, a booklet and an online tool) specifically for older women facing treatment choices (endocrine therapy alone or surgery plus adjuvant endocrine therapy, and adjuvant chemotherapy or no chemotherapy) using several evidence sources (expert opinion, literature and patient interviews). The online tool was based on models developed using registry data from 23,842 patients and validated on an external data set of 14,526 patients. Mortality rates at 2 and 5 years differed by < 1\% between predicted and observed values. (3) Cluster-randomised clinical trial of decision support tools: 46 UK breast units were randomised (intervention, n = 21; usual care, n = 25), recruiting 1339 women (intervention, n = 670; usual care, n = 669). There was no significant difference in global quality of life at 6 months post baseline (difference-0.20, 95\% confidence interval-2.7 to 2.3; p = 0.90). In women offered a choice of endocrine therapy alone or surgery plus adjuvant endocrine therapy, knowledge about treatments was greater in the intervention arm than the usual care arm (94\% vs. 74\%; p = 0.003). Treatment choice was altered, with higher rates of endocrine therapy alone than of surgery in the intervention arm. Similarly, chemotherapy rates were lower in the intervention arm (endocrine therapy alone rate: Intervention sites 21\% vs. usual-care sites 15\%, difference 5.5\%, 95\% confidence interval 1.1\% to 10.0\%; p = 0.02; adjuvant chemotherapy rate: Intervention sites 10\% vs. usual-care site 15\%, difference 4.5\%, 95\% confidence interval 0.0\% to 8.0\%; p = 0.013). Survival was similar in both arms. (4) Health economic analysis: A probabilistic economic model was developed using registry and cohort study data. For most health and fitness strata, surgery plus adjuvant endocrine therapy had lower costs and returned more quality-adjusted life-years than endocrine therapy alone. However, for some women aged > 90 years, surgery plus adjuvant endocrine therapy was no longer cost-effective and generated fewer quality-adjusted life-years than endocrine therapy alone. The incremental benefit of surgery plus adjuvant endocrine therapy reduced with age and comorbidities. (5) Variation in practice: analysis of rates of surgery plus adjuvant endocrine therapy or endocrine therapy alone between the 56 breast units in the cohort study demonstrated significant variation in rates of endocrine therapy alone that persisted after adjustment for age, fitness and stage. Clinician preference was an important determinant of treatment choice. Conclusions: This study demonstrates that, for older women with oestrogen-receptor-positive breast cancer, there is a cohort of women with a life expectancy of < 4 years for whom surgery plus adjuvant endocrine therapy may offer little benefit and simply have a negative impact on quality of life. The Age Gap decision tool may help make this shared decision. Similarly, although adjuvant chemotherapy offers little benefit and has a negative impact on quality of life for the majority of older women with oestrogen-receptor-positive breast cancer, for women with oestrogen-receptor-negative breast cancer, adjuvant chemotherapy is beneficial. The negative impacts of adjuvant chemotherapy on quality of life, although significant, are transient. This implies that, for the majority of fitter women aged > 70 years, standard care should be offered. Limitations: As with any observational study, despite detailed propensity score matching, residual bias cannot be excluded. Follow-up was at median 52 months for the cohort analysis. Longer-term follow-up will be required to validate these findings owing to the slow time course of oestrogen-receptor-positive breast cancer. Future work: The online algorithm is now available (URL: Https://agegap.shef.ac.uk/; accessed May 2022). There are plans to validate the tool and incorprate quality-of-life and 10-year survival outcomes.}, doi = {10.3310/xzoe2552}, eissn = {2050-4330}, issn = {2050-4322}, issue = {6}, journal = {Programme Grants for Applied Research}, note = {Free to read: This content has been made freely available to all.; Contractual start date: 7-2012; Editorial review begun: 2-2021; Accepted for publication: 2-2022}, pages = {1-114}, publicationstatus = {Published}, publisher = {National Institute for Health and Care Research (NIHR)}, url = {https://nottingham-repository.worktribe.com/output/8853377}, volume = {10}, year = {2022}, author = {Wyld, Lynda and Reed, Malcolm W.R. and Collins, Karen and Ward, Sue and Holmes, Geoff and Morgan, Jenna and Bradburn, Mike and Walters, Stephen and Burton, Maria and Lifford, Kate and Edwards, Adrian and Brain, Kate and Ring, Alistair and Herbert, Esther and Robinson, Thompson G and Martin, Charlene and Chater, Tim and Pemberton, Kirsty and Shrestha, Anne and Nettleship, Anthony and Richards, Paul and Brennan, Alan and Cheung, Kwok Leung and Todd, Annaliza and Harder, Helena and Audisio, Riccardo and Battisti, Nicolo Matteo Luca and Wright, Juliet and Simcock, Richard and Murray, Christopher and Thompson, Alastair M and Gosney, Margot and Hatton, Matthew and Armitage, Fiona and Patnick, Julietta and Green, Tracy and Revill, Deirdre and Gath, Jacqui and Horgan, Kieran and Holcombe, Chris and Winter, Matt and Naik, Jay and Parmeshwar, Rishi} }