Multimorbidity and overall survival among women with breast cancer: results from the South African Breast Cancer and HIV Outcomes Study

Breast cancer remains the most commonly diagnosed cancer and the leading cause of cancer death among women worldwide [1]. It is also the most common cancer among women in South Africa accounting for 22.6% of all female cancers and 16% of cancer deaths amongst women [2]. In high-income countries (HICs), which have population-based mammography screening, early-stage diagnosis, and access to diagnostic and treatment resources, breast cancer has a relatively favourable prognosis; in the USA, the 5-year survival is 80% among African American women and 91% among non-Hispanic White women [3]. Among black South African women, 3-year overall survival is estimated to be 59% [4] mainly due to late-stage diagnosis and sub-optimal multi-modality treatment access and completion.

The increasing prevalence of chronic health conditions, and consequent increasing prevalence of multimorbidity defined as the presence of two or more chronic conditions in one person [5], is a major challenge facing healthcare systems, including those in South Africa [6]. Patients from socio-economically disadvantaged communities face numerous complex social and medical conditions that combine syndemically to affect the quality of life and survival outcomes adversely [7, 8]. This clustering of social and health problems is often overlooked in models of epidemiological transition investigations. As infectious disease mortality declines and populations age, more individuals are living longer with multimorbidity [9]. They impose an ever-increasing burden on overstretched public health systems and pose complex problems for patient management and clinical treatment, and patients experience reduced quality of life and increased mortality [6, 9]. Lifestyle modification and treatment advances have significantly reduced the mortality rate from multimorbidity in HICs [10], but have not reached many upper-middle-income countries like South Africa on which multimorbidity is now imposing serious health, social, and health system resource burdens [11].

Currently, among women newly diagnosed with breast cancer in South Africa, approximately 81% are estimated to have at least one self-reported chronic health condition, and 44% multimorbidity [12]. Although many prior studies have assessed the association between individual chronic conditions and survival in patients with breast cancer, few have quantified the multimorbidity burden, in particular the associations of multiple simultaneous conditions with survival [13]. A review evaluating the impact of multimorbidity on breast cancer guideline adherence for treatment decision-making concluded that multimorbidity can have a profound impact on health, day-to-day function, and mortality among patients with breast cancer [14]. The population-based FOCUS cohort of 3,672 Dutch women with breast cancer aged ≥ 65 years showed that the number of comorbidities was associated with worse overall survival [15].

In our previous studies, we found that women who were obese and hypertensive were more likely to present with early-stage breast cancer and that multimorbidity was not associated with the stage of breast cancer diagnosis [12, 16]. We also found that in early-stage breast cancer, women with multimorbidity were less likely to have surgery, less likely to receive chemotherapy, and more likely to receive endocrine therapy than those with a low multimorbidity burden [12]. We now describe the impact of multimorbidity on overall survival in women with breast cancer enrolled in the South African Breast Cancer and HIV Outcomes (SABCHO) Study.

Women who were ≥ 18 years of age, had resided in South Africa for ≥ 5 years, and were newly diagnosed with invasive breast cancer were eligible for enrolment in the SABCHO Study. Women who had a previous cancer diagnosis (other than non-invasive cervical cancer or nonmelanoma skin cancer), or were unable to give informed consent, were excluded. The SABCHO protocol has been published previously [17]. For this analysis, we included women diagnosed between 1 July 2015 and 31 December 2019.

Socio-demographic information (such as age, ethnicity, marital status, the highest level of education, and employment status) and lifestyle factors (alcohol consumption and smoking) were collected at diagnosis. Body weight and height were measured at enrolment. We generated a score for household socio-economic status (HSES) based on self-reported household possessions and facilities (homeownership, car ownership, microwave, washing machine, indoor flush toilet, indoor running water, and gas or electric). One point was allocated to each possession, and we categorized the total HSES score (range 0–7) into low (scores 0–5) and high (scores 6–7). We categorized the hospital site as CHBAH vs. CMJAH vs. Durban vs. Greys vs. Ngwelezana. The two hospitals in Durban share facilities and staff and are analysed here as a single unit. Participants were clinically staged at the time of diagnosis using the 7th edition of the American Joint Committee on Cancer (AJCC) [18]. Clinical stage (1 and 2 vs. 3 vs. 4), tumour receptor status (oestrogen receptor (ER) + /progesterone receptor (PR) + / human epidermal growth factor receptor (HER2)- vs. ER + /PR + /HER2 + vs ER-/PR-/HER2 + vs ER-/PR-/HER2-, and treatment information (surgery, chemotherapy, and radiation therapy) were collected directly from the medical record.

We collected data on seven chronic conditions: hypertension, obesity, diabetes, HIV, cerebrovascular disease, asthma/chronic obstructive pulmonary disease (COPD), and tuberculosis. The women were asked if they had ever been treated for tuberculosis or ever been diagnosed and treated for hypertension, diabetes, cerebrovascular disease, and asthma/COPD. Obesity (body mass index (BMI) ≥ 30.0 kg/m²) was calculated from body weight and height measurements taken at enrolment; HIV status was tested for consenting patients through the National Health Laboratory Services, using an enzyme-linked immunosorbent assay. We defined multimorbidity as having ≥ 2 of these seven chronic conditions.

A total of 3,497 women were enrolled in the SABCHO Study between July 2015 and December 2019. After excluding patients with missing information on hypertension, diabetes, cerebrovascular disease, asthma/COPD, tuberculosis, height, weight, and HIV status, 3,261 women were included in the final analyses. The most prevalent chronic conditions were obesity (53%), hypertension (41%), HIV (22%), and diabetes (13%), whereas asthma/COPD had the lowest prevalence (4%) (Table 1). The prevalence of these chronic conditions was higher in older women (≥ 50 years of age), except for HIV where 67.5% of women were < 50 years old. Most women in the cohort were unmarried and educated. Smoking prevalence though low overall ranged from 8% in HIV-positive women to 23% in those with asthma/COPD (Table 1).

Only 17% of the women (14% of those ≥ 50 years and 23% of those < 50 years) had none of these seven chronic conditions (Fig. 1a–c). Forty-five per cent of the participants met our definition of multimorbidity; 29% of the women had only 2 chronic conditions and 16% had ≥ 3 chronic conditions. Among patients with multimorbidity, the most common combination was obesity and hypertension (13%), followed by obesity and HIV (6%) (Fig. 1a). Age ≥ 50 years, Asian ethnicity, unmarried status, and primary education or less were associated with having more chronic conditions. Most patients with 3 or more chronic conditions presented with stage I-II breast cancer (Table 2).

With a median follow-up time of 32.6 months (IQR 19.5–48.8), 1410 (43.2%) of women had died. The median follow-up time was 32.7 months (20.0–49.0) with 743 (41.4%) deaths among those with < 2 chronic conditions, 32.1 months (18.4–48.6) with 667 (45.5%) deaths among those with ≥ 2 chronic conditions. The absolute survival at 2 years, 3 years, and 5 years is shown in Additional file 1: Table S1. Women with multimorbidity had poorer overall survival at 3 years than women without multimorbidity (60.8% vs. 64.3%, p = 0.036) in the full cohort, which was driven by a marginal survival difference in women ≥ 50 years old at breast cancer diagnosis (60.0% vs. 64.0%, p = 0.051), whereas there were no survival differences associated with multimorbidity among women < 50 years old at breast cancer diagnosis (p = 0.475) (Fig. 2). There was no age interaction with multimorbidity in the full cohort and in the analysis restricted to HIV-negative patients (data not shown). Multimorbidity was also associated with poorer 3-year survival among women with stage I and II disease (80.7% vs. 86.3%, p = 0.005), and stage III disease (53.0% vs. 59.4%, p = 0.024) but not among those with stage IV disease, all of whom had very low survival (27.1% vs. 25.9%, p = 0.796).

In model 1 (unadjusted), we found that women with obesity had lower all-cause mortality than women who were not obese (hazard ratio (HR) = 0.89, 95% confidence interval (CI) = 0.90–0.99), this HR attenuated and became non-significant in model 4. Women with CVD (HR = 1.30, 95% CI = 1.06–1.58), HIV (HR = 1.32, 95% CI = 1.17–1.49), and tuberculosis (HR = 1.23 95% CI = 1.01–1.50) had higher all-cause mortality than women without these conditions. Women who had obesity + HIV (HR = 1.20, 95% CI = 1.01–1.42), HIV + tuberculosis (HR = 1.39, 95% CI = 1.08–1.79), and multimorbidity (HR = 1.12, 95% CI = 1.01–1.24) also had higher mortality risks than women these conditions (Table 3). After adjustment for age, education, household socio-economic status, stage at diagnosis, receptor status, hospital site, and treatment received, the risks of mortality adjusted hazard ratios, given the conditions studied, were: diabetes (HR = 1.20, 95% CI = 1.03–1.41, p = 0.022), CVD (HR = 1.43, 95% CI = 1.17–1.76, p = 0.001), HIV (HR = 1.21, 95% CI = 1.06–1.38, p = 0.006), and obesity + HIV (HR = 1.24, 95% CI = 1.04–1.48, p = 0.017). Survival remained poorer for women with multimorbidity (≥ 2 chronic conditions) (HR = 1.26, 95% CI = 1.13–1.40, p < 0.001) than for women without multimorbidity (Table 3).

To examine if the effect of the difference in survival by multimorbidity is mainly driven by HIV, we ran the model while excluding patients with HIV. We found that overall mortality based on multimorbidity status was marginally different in the whole cohort (p = 0.067) and in women ≥ 50 years (p = 0.072), but no difference in women < 50 years old (p = 0.912). By stage at diagnosis, women with multimorbidity still had worse survival in stage I and II disease (p = 0.006) and in stage III disease (p = 0.009), but not in stage IV disease (p = 0.831) than women without multimorbidity (Additional file 2: Supplementary Fig. S1).

In our cohort of 3261 women newly diagnosed with breast cancer, 44.7% of the women presented with multimorbidity (≥ 2 chronic conditions in addition to breast cancer). With a median follow-up time of 32.6 months, 43.2% of women had died. Women with obesity had better overall survival than non-obese women, but women living with diabetes, CVD, HIV, and obesity + HIV died earlier than women without these chronic conditions. Women with multimorbidity had higher mortality than women without multimorbidity in the whole cohort, a difference that was maintained when looking specifically at women with stages I and II, and those with stage III breast cancer but not in stage IV disease.

A large study in Spain found that breast cancer patients with a higher morbidity burden had poorer survival than those with no morbidity (HR: 2.33 95% CI: 1.76–3.08) [20]. These results support our findings and those of several other recent studies of survival given multimorbidity [15, 21]. Multimorbidity may adversely affect survival in several ways. Concomitant chronic disease may cause non-cancer mortality, as it would among patients without breast cancer [21‐23]. Several studies have found that patients with multimorbidity receive less intensive treatment for their breast cancer than those without multimorbidity, potentially impacting their overall survival [12, 24]; from our findings, women with multimorbidity had a 26% higher mortality rate than women without multimorbidity when we adjusted for treatment received (Table 3, model 4) which was worse than the 19% higher mortality rate when we did not factor in treatment received (Table 3, model 3). If the chronic condition involves organ failure (e.g. compromised cardiac, respiratory, or renal function), curative treatment involving surgery, chemotherapy, and radiation therapy may not be possible, but undertreatment may then adversely affect their overall survival [25]. In addition, the chronic condition may make the patient more vulnerable to toxicity from chemotherapy and radiation therapy, leading to dose reduction or early discontinuation of treatment and, therefore, poorer outcomes [26, 27]. Also, patients with chronic conditions and multimorbidity have been found to have a higher risk of recurrence of their cancer than patients without additional conditions [21]. Clinicians caring for older women with a history of early-stage breast cancer may be concerned that concomitant chronic conditions will increase the toxicity and side effects of cancer treatment, that treatments may be less effective in these women, or that their life expectancy is insufficient to justify the use of potentially toxic agents [21, 28]. Such patients may also decline treatment for their cancer [29]. In addition, medications for the coexisting chronic conditions may affect the risk of side effects from cancer therapies mainly from drug-drug interaction and make treatment less effective [30], or a lack of focus on care for the coexisting chronic condition during cancer treatment may lead to poor survival [31]. Lastly, the risk of dying from a chronic condition may be so high that even patients who are diagnosed at an early stage and receive the recommended breast cancer treatment may not benefit from it [25]. Hence, there is a need for a study of causes of death generally in women with multimorbidity and breast cancer.

We found that women with stage IV breast cancer and multimorbidity did not have poorer overall survival than those without multimorbidity. This is consistent with the findings of other studies that multimorbidity has a greater impact on cancers with a better prognosis [32, 33]. Patients who have cancer associated with a high mortality rate are more likely to die from that cancer, regardless of their co-morbid diseases than patients who have a better cancer prognosis. Higher mortality rates in women with multimorbidity manifest 1 year post-diagnosis in stage III women and after 2 years in stages I and II women with breast cancer. The delayed effect of multimorbidity on lower survival might indicate that the lower survival is not due to higher background mortality which would apply to all periods, but due to a breast cancer-defined attribute, e.g. perhaps women with multimorbidity have lower treatment completion/quality and a thus great chance of recurrence and eventually lower survival.

In a report from the Shanghai Breast Cancer Survival Study of 4,664 women with stage I-III breast cancer, diabetes was associated with poorer overall survival [34] mainly from chronic vascular complications [13]. Other studies have reported poorer overall survival in women with breast cancer and CVD [13]. Our finding that HIV infection was associated with higher all-cause mortality is consistent with prior work from HICs demonstrating higher mortality rates among patients with HIV infection and breast cancer than among HIV-uninfected breast cancer patients [35, 36]. We too have published findings showing that the 2-year overall survival of women with stages I-III breast cancer was poorer among women living with HIV than among HIV-uninfected women as reported by Ayeni et al. (72.4% vs. 80.1%, p < 0.001) and adjusted hazard ratio (HR = 1.49, 95% CI = 1.22–1.83) [37]. Whilst we did not find any statistical evidence of an interaction with age, the p values were small (< 0.1); thus, in future larger studies it would be useful to reexamine whether the multimorbidity effect might be stronger at older ages.

The theory of syndemics offers an innovative way of understanding why diseases cluster together in populations disproportionately affected by poverty and other social and environmental stressors [8, 38]. A syndemic is the clustering of two or more diseases within a population that arise from and contribute to persistent economic and social inequalities [39]. Patients experience morbidity through a combination of complex social, environmental, and medical conditions that impact the quality of life and survival outcomes. The causes, courses, and outcomes of communicable diseases, nutritional conditions, and non-communicable diseases are closely related [40]. They all have common underlying social conditions such as unhealthy environments and poverty, and disease groups entail common comorbidities, causes, and care needs [41]. Individuals may have both communicable diseases and non-communicable diseases and one can increase the impact or risk of the other [42]. In South Africa, we need to recognize the different clusters of socio-economic status and multimorbidity in our women with breast cancer and how they interact with each other and affect health outcomes. This recognition could support new investigative approaches that integrate more than just disease-specific models, incorporating economic, environmental, and social conditions that exacerbate the effects of disease clusters. We must also incorporate syndemic considerations into policies for disease prevention and management of health systems. Screening for common comorbidities like obesity, hypertension, diabetes, HIV, depression, alcoholism, and algorithms for understanding and accommodating socio-economic circumstances for treatment plans should be routinely introduced for single clinic visits in primary care [8, 38, 39].

The strengths of our study include the prospective study design, multi-centre cohort, and large sample size. The 7 chronic conditions were included because of their known high prevalence in the least parts of South Africa where regular treatment may provide an avenue for early cancer detection (e.g. HIV and tuberculosis [43], COPD [44], hypertension and heart disease [45]), their known impact on treatment (e.g. cardiotoxicity and worsening of hypertension [46]), and their known association with breast cancer prognosis (obesity [47], diabetes [48], and HIV [49]). Among the limitations, the 236 participants excluded due to missing information on chronic conditions were not socio-demographically different from the final sample in the analyses; hence, our findings are generalizable. We note that we included only seven chronic conditions at baseline, we may therefore have underestimated the prevalence of chronic conditions and multimorbidity in this study. We also did not assess the severity of chronic conditions, and we did not investigate the role of newly diagnosed chronic conditions after the breast cancer diagnosis, because the objective of the present study was to investigate chronic conditions at diagnosis and survival outcomes. Five of the 7 chronic conditions were self-reported without additional objective laboratory testing and measurement of blood pressure at diagnosis, which may also have led us to underestimate the prevalence of chronic conditions in this cohort [50].

This study confirmed that overall survival was significantly poorer among women with multimorbidity at breast cancer diagnosis than among other women without multimorbidity, particularly in women diagnosed with early-stage or locally advanced breast cancer. Future studies should assess and report the influence of multimorbidity and syndemics on breast cancer treatments and breast cancer-specific mortality.