Abstract
Objective
Anthracyclines are potent antineoplastic agents in the treatment of lymphoid malignancies, but their therapeutic benefit is limited by cardiotoxicity. The American Heart Association (AHA) recommends routine surveillance, early diagnosis and treatment of anthracycline-based chemotherapy (AC) induced cardiomyopathy (AC-CMP). We aimed to assess the prevalence of AC-CMP in patients with lymphoma, surveillance patterns of left ventricular ejection fraction (LVEF) in those receiving AC and management of patients with AC-CMP at an academic medical centre prior to the development of a comprehensive cardio-oncology programme.
Methods
We performed a retrospective cohort study examining 218 patients with aggressive B cell non-Hodgkin's lymphomas (B-NHL) who received AC 1992–2012 and had serial follow-up. AC-CMP was defined as LVEF decrease ≥10% with final LVEF≤50% or LVEF reduction ≥15% regardless of final LVEF.
Results
Of 218 patients treated with AC, 73 (34%) had LVEF assessment both prior to and after receiving AC. Of these 73 patients, 24 developed AC-CMP and had higher cumulative all-cause mortality than those without AC-CMP (HR 2.35, p=0.03). Coronary artery disease (CAD) was an independent predictor of AC-CMP (p=0.048). Mean post-AC LVEF was lower in patients with CAD compared with those without CAD when their baseline LVEF was 45% (p=0.0009) or 55% (p=0.001) but was similar at 65% (p=0.33). Less than half of patients with AC-CMP received recommended heart failure medication therapy.
Conclusions
Historically, one-third of patients with B-NHL treated with AC underwent surveillance according to AHA guidelines. There is substantial opportunity for collaboration between oncologists and cardiologists to improve the care of patients with lymphoma receiving AC.
Strengths and limitations of this study.
Comprehensive single institution approach of using evidence-based guidelines to evaluate real-world surveillance and management patterns of patients with lymphoma with anthracycline-based chemotherapy-induced cardiomyopathy.
Retrospective study of 218 patients at a single institution with information on demographics, medical comorbidities, left ventricular ejection fraction and survival data.
Generalisability of the results is limited to a subset of the targeted population that received the expected surveillance and treatment according to the American Heart Association guidelines.
Introduction
The American Cancer Society estimates that in 2014, there were approximately 14.5 million children and adults with a history of cancer including 297 820 male and 272 000 female survivors of non-Hodgkin's lymphoma (NHL).1 While the development of effective diagnostic and chemotherapeutic strategies has resulted in a large population of long-term cancer survivors, the impact of chemotherapy on the long-term health of these survivors is substantial. Cardiac toxicity is a common complication of anthracycline-based chemotherapy (AC), with the clinical course ranging from transient asymptomatic left ventricular dysfunction (LVD) to chronic heart failure (HF) and even cardiac death. The most common clinical presentation of AC cardiotoxicity is a dose-dependent cardiomyopathy (CMP) that leads to HF.2–5 Symptomatic HF is the most serious form of AC-CMP, with an incidence of 5–50%, depending on the cumulative dose of AC received.6–9 Asymptomatic CMP manifested by echocardiographic abnormalities is more common than symptomatic disease and, depending on the definitions applied, can be found in approximately 50% of all patients who received AC.8 9
Compared with other more frequent forms of CMP, AC-CMP has been associated with an especially poor prognosis, with a 2-year mortality rate up to 60%.10 Importantly, AC-CMP also limits the therapeutic choices for patients with relapsed cancer to less intensive and potentially less effective cancer therapies.2 However, recent studies have indicated that in AC-CMP, left ventricular ejection fraction (LVEF) recovery and adverse cardiac event reduction may be achieved when asymptomatic cardiac dysfunction is detected early and modern HF therapy is promptly initiated.3 11 Therefore, the American College of Cardiology/American Heart Association/American Society of Echocardiography (ACC/AHA/ASE) committee gives a class I recommendation for regular LVEF monitoring in patients exposed to cardiotoxic agents in order to facilitate decisions regarding further chemotherapy as well as provide early diagnosis and treatment of AC-CMP.12–14 Echocardiographic surveillance is also supported by the European Society for Medical Oncology (ESMO).15
Despite these recommendations, there are limited data regarding surveillance patterns and cardiovascular treatment for patients with lymphoma receiving AC. NHLs are characterised by abnormal tissue growth in the lymphatic system and is the sixth most common cancer in both men and women, with increasing incidence among all age groups.16 Aggressive subtypes of B cell NHLs (B-NHLs) such as diffuse large B cell lymphoma and Burkitt lymphoma are commonly cured with anthracycline chemoimmunotherapy while other subtypes such as follicular lymphoma and mantle cell lymphoma often require systemic AC.17 We therefore conducted a retrospective cohort study of patients with aggressive B-NHLs who were treated with AC to assess the cardiac surveillance and HF management of these patients at an academic medical centre prior to the development of a comprehensive cardio-oncology programme and to examine clinical characteristics that may impact AC-CMP development or mortality.
Methods
Participants and data collection
We used the Emory University Lymphoma Enterprise Architecture Data-system (LEAD), a database that integrates genetic, clinical, histological, epidemiological and clinical trial information from disparate medical systems for improved research, disease diagnosis, treatment and statistical outcomes measurements. The process for managing the LEAD registry and incorporating new patient data into LEAD is approved by the Emory University Institutional Review Board (IRB) and data collection and extraction procedures have previously been described.18 19 Patients with NHL diagnoses who had received AC were identified through a series of search strategies including International Classification of Disease—Oncology (ICD-O) histology codes and free-text searches of anatomical pathology reports and electronic medical records. An IRB waiver of consent was obtained for the data analysis required for this current study. The retrospective cohort for the current analysis was limited to patients with aggressive B-NHLs who received AC and evaluation during their care at an Emory Healthcare facility.
Predictor variables
Comprehensive chart review was undertaken to identify patients who underwent LVEF evaluation both prior to and after AC and to collect sociodemographic data (eg, age, sex, race), comorbid conditions (eg, hypertension, hyperlipidaemia, diabetes mellitus, coronary artery disease (CAD)), health status and treatment variables (eg, mediastinal radiation, method of LVEF assessment). All available imaging data were reviewed by an independent researcher (JRB). Any disagreements between the reader and the original report (difference in LVEF>5 absolute points) was solved by consensus reached with subsequent joint evaluation (JRB and SP). Independent reports have suggested two-dimensional transthoracic echocardiography (TTE) test–retest variability of around 5–7%.20 21
Outcome variables
The primary outcome measures were (1) documented pre-AC and post-AC LVEF evaluations and (2) development of AC-CMP, among patients with B-NHL treated with AC. Consistent with current guidelines, AC-CMP was defined as a LVEF reduction by ≥10% concomitant with an absolute post-AC LVEF≤50%, or a LVEF reduction of ≥15% regardless of post-AC LVEF.22
Secondary outcome measures included vital status after the first post-AC LVEF evaluation as well as AC-CMP management. Mortality data were obtained using chart documentation and the Social Security Death Index. For three patients referred to hospice but without a verified exact date of death, the last recorded date of patient contact in the electronic medical record was used as the date of death. Follow-up time period was defined from the patient's first AC at our institution to the date of their last known clinic visit or date of death. CMP management was defined using standard guideline recommendations for patients with decreased LVEF,23 such as treatment with ACE inhibitors, β-blocker therapy, serial imaging and/or cardiology referral.
Statistical analysis
The prevalence of CMP was estimated as a single sample proportion. A 95% CI based on Wilson's score method for a single sample proportion was calculated for the prevalence of CMP. ORs were calculated to measure the degree of association between risk factors and AC-CMP. Only risk factors that were significant at p<0.20 in the univariable analyses were included in the multivariable analyses (Cox proportional hazards regression analysis). A p value of 0.20 was used as a significance level to help ensure that all potentially important covariates were included in the final multivariable Cox model. The HR and its 95% CI were calculated for each factor in the presence of others in the final Cox proportional hazards regression model.
Using linear regression, post-LVEF was regressed on initial LVEF and compared in patients with and without specific risk factors for AC-CMP. History of CAD was the only independent predictor identified, so this factor and the interaction between initial LVEF and CAD history were included as covariates. Adjusted post-LVEF means were estimated for patients with and without a history of CAD and defined as the predicted response values obtained by evaluating the regression equation for CAD at the mean initial LVEF. Results are provided as adjusted means with 95% CIs.
Cumulative survival was estimated with the Kaplan-Meier method. Log-rank tests were used to compare survival according to demographic and clinical characteristics. Age of the patient was evaluated as a categorical covariates (above or below the median age of 60, or per 10-year increase) and as a continuous covariate. Only risk factors that were significant at p<0.20 in univariable analyses were included in the multivariable analyses. The HR and its 95% CI were calculated for each factor in the presence of others in the final Cox proportional hazards regression model.
Results
Of 506 patients in the LEAD registry who received AC for aggressive B-NHL between 1995 and 2012, 218 patients completed AC and regular follow-up within the Emory Healthcare system. In total, 73 of the 218 patients (34%) received imaging surveillance of LVEF with either TTE or multigated acquisition scan (MUGA) both prior to and after receiving chemotherapy, whereas 67 patients (30%) had imaging surveillance only prior to receiving chemotherapy, 9 patients (4%) received imaging surveillance only after receiving chemotherapy and 69 (32%) had no documentation of imaging surveillance within the electronic medical record (figure 1). Of the 73 patients who underwent both baseline and follow-up LVEF examinations, 13 patients underwent MUGA, 59 patients underwent echocardiography and 1 patient underwent positron emission tomography prior to receiving AC. The same modality was used for serial LVEF examinations in 93% of patients. Follow-up diastolic function was evaluated in 27 patients.
The prevalence of AC-CMP was estimated at 33% (95% CI 23% to 44%). Eleven of the 24 patients who developed AC-CMP had mildly reduced LVEF (post-AC LVEF>45%) and the remaining 13 had moderately to severely reduced LVEF (post-AC LVEF≤45%). Among patients receiving AC, patients with CAD were more likely to develop AC-CMP (table 1). As CAD history was the only significant independent predictor (p=0.048), adjusted post-AC LVEF means were compared in patients with and without CAD using linear regression (table 2).
Table 1.
Characteristic | Total (n=73) | AC-CMP (n=24) | No AC-CMP (n=49) | OR (95% CI) | p Value |
---|---|---|---|---|---|
Mediastinal radiation | 1.26 (0.27 to 5.76) | 0.77 | |||
Yes | 8 | 3 | 5 | ||
No | 65 | 21 | 44 | ||
Age | 73 | 59.0±15.5 | 60.0±13.2 | 1.00 (0.96 to 1.03) | 0.82 |
Sex | 0.74 (0.27 to 2.00) | 0.55 | |||
Female | 31 | 9 | 22 | ||
Male | 42 | 15 | 27 | ||
Race | 0.91 (0.28 to 3.02) | 0.88 | |||
Black | 17 | 5 | 12 | ||
Caucasian | 51 | 16 | 35 | ||
Unknown | 5 | 3 | 2 | ||
Smoking history | 1.21 (0.38 to 3.85) | 0.75 | |||
Yes | 19 | 6 | 13 | ||
No | 47 | 13 | 34 | ||
Unknown | 7 | 5 | 2 | ||
Hypertension§ | 1.34 (0.50 to 3.61) | 0.56 | |||
Yes | 34 | 12 | 22 | ||
No | 38 | 11 | 27 | ||
Diabetes mellitus§ | 1.85 (0.45 to 7.67) | 0.39 | |||
Yes | 9 | 4 | 5 | ||
No | 63 | 19 | 44 | ||
Hyperlipidaemia§ | 1.38 (0.43 to 4.40) | 0.59 | |||
Yes | 16 | 6 | 10 | ||
No | 56 | 17 | 39 | ||
Coronary artery disease | 3.62 (1.01 to 13.0) | 0.048* | |||
Yes | 12 | 7 | 5 | ||
No | 61 | 17 | 44 |
*Significant p value.
§Total n=62, AC-CMP n=23.
AC-CMP, anthracycline-based chemotherapy-induced cardiomyopathy.
Table 2.
CAD | Pre-LVEF (%) | Adjusted post-LVEF mean (%) | 95% CI |
---|---|---|---|
Yes (n=12) | All, mean=59 | 47 | (41 to 53) |
45 | 36 | (27 to 45) | |
55 | 43 | (37 to 49) | |
65 | 50 | (43 to 56) | |
No (n=61) | All, mean=62 | 54 | (52 to 57) |
45 | 58 | (49 to 67) | |
55 | 56 | (51 to 60) | |
65 | 53 | (50 to 56) |
The median years on study for survivors were 2.99 years.
AC, anthracycline-based chemotherapy; CAD, coronary artery disease; LVEF, left ventricular ejection fraction.
Post-AC LVEF in these two groups differed significantly depending on the baseline LVEF (p=0.01, test for interaction between baseline LVEF and CAD). Mean post-AC LVEF was significantly lower in patients with CAD compared with patients without CAD when baseline LVEF was 45% (36% vs 58%, p=0.0009) and when baseline LVEF was 55% (43% vs 56%, p=0.001). However, mean post-AC LVEF was similar in patients with CAD compared with patients without CAD when their baseline LVEF was 65% (50% vs 53%, p=0.33).
Median follow-up was 2.99 years. Cumulative all-cause mortality rates were higher in patients who developed AC-CMP compared with those who did not (figure 2 and table 3). This difference remained significant (p=0.03) even after adjusting for age, sex, hyperlipidaemia and history of CAD (table 4). Interestingly, hyperlipidaemia was an independent prognostic factor for survival after adjusting for age, sex and CAD history.
Table 3.
Characteristic | Total (n=73) | Death (n=34) | 1-Year survival (SE) | 5-Year survival (SE) | p Value |
---|---|---|---|---|---|
AC-CMP | 0.02* | ||||
Yes | 24 | 15 | 0.58 (0.10) | 0.38 (0.11) | |
No | 49 | 19 | 0.80 (0.06) | 0.68 (0.07) | |
Mediastinal radiation | 0.93 | ||||
Yes | 8 | 4 | 0.88 (0.12) | 0.58 (0.19) | |
No | 65 | 30 | 0.71 (0.06) | 0.59 (0.06) | |
Age (years) | 0.07* | ||||
<60 | 36 | 12 | 0.72 (0.07) | 0.69 (0.08) | |
≥60 | 37 | 22 | 0.73 (0.07) | 0.49 (0.09) | |
Sex | 0.15* | ||||
Female | 31 | 11 | 0.77 (0.08) | 0.63 (0.09) | |
Male | 42 | 23 | 0.69 (0.07) | 0.55 (0.08) | |
Race | 0.57 | ||||
Black | 17 | 7 | 0.82 (0.09) | 0.70 (0.11) | |
Caucasian | 51 | 25 | 0.71 (0.06) | 0.55 (0.07) | |
Unknown | 5 | 2 | |||
Smoking history | 0.67 | ||||
Yes | 19 | 8 | 0.84 (0.08) | 0.71 (0.11) | |
No | 47 | 20 | 0.72 (0.07) | 0.61 (0.07) | |
Unknown | 7 | 6 | |||
Hypertension§ | 0.81 | ||||
Yes | 34 | 17 | 0.76 (0.07) | 0.61 (0.09) | |
No | 38 | 16 | 0.71 (0.07) | 0.58 (0.09) | |
Diabetes mellitus§ | 0.85 | ||||
Yes | 9 | 4 | 0.78 (0.14) | 0.56 (0.17) | |
No | 63 | 29 | 0.73 (0.06) | 0.60 (0.06) | |
Hyperlipidaemia§ | 0.11* | ||||
Yes | 16 | 4 | 0.88 (0.08) | 0.73 (0.12) | |
No | 56 | 29 | 0.70 (0.06) | 0.55 (0.07) | |
Coronary artery disease | 0.16* | ||||
Yes | 12 | 8 | 0.75 (0.13) | 0.34 (0.15) | |
No | 61 | 26 | 0.72 (0.06) | 0.63 (0.06) |
*Variables that were included in multivariate regression model analysis.
§Total n=62, AC-CMP n=23.
AC-CMP, anthracycline-based chemotherapy-induced cardiomyopathy; LVEF, left ventricular ejection fraction.
Table 4.
Characteristic | HR | 95% CI | p Value | |
---|---|---|---|---|
AC-CMP | Yes vs no | 2.36 | (1.11 to 5.02) | 0.03 |
Sex | Female vs male | 0.68 | (0.32 to 1.42) | 0.24 |
Hyperlipidaemia | Yes vs no | 0.27 | (0.09 to 0.86) | 0.03 |
Coronary artery disease | Yes vs no | 1.79 | (0.68 to 4.77) | 0.24 |
Age | Per 10-year↑ | 1.04 | (0.79 to 1.38) | 0.78 |
AC-CMP, anthracycline-based chemotherapy-induced cardiomyopathy; LVEF, left ventricular ejection fraction.
Of the 24 patients with AC-CMP, 11 were referred to cardiology, 7 received β-blocker therapy, 8 received treatment with ACE inhibitors and 8 underwent additional LVEF evaluation. Six patients were prescribed both β-blocker and ACE inhibitor therapy and only three patients received β-blocker and ACE inhibitor therapy in addition to repeat TTE (figure 3).
Discussion
The benefits of AC are limited by cumulative dose-related cardiotoxicity.24 In this study, we observed that (1) 73 patients (34%) who completed AC at a single academic medical centre for aggressive B-NHL had imaging surveillance both prior to and after receiving chemotherapy, (2) 33% of patients who underwent LVEF evaluation both prior to and after receiving AC developed CMP, (3) patients with CAD were more likely to develop AC-CMP and this was influenced by their baseline LVEF and (4) a minority of patients who developed AC-CMP were referred to a cardiologist, started on HF medications such as β-blockers or ACE inhibitors, or had repeat imaging for further LVEF evaluation.
Anthracycline-induced cardiotoxicity ranges from asymptomatic mild LVD to severe HF that decreases patients’ quality of life and life expectancy. In our investigation, we observed that patients with AC-CMP were 2.36 times more likely to die than those without AC-CMP. Furthermore, patients who had CAD and LVD on their baseline LVEF assessment were more likely to develop further reduced LVEF and AC-CMP, thereby supporting the theory that if early LVD is not diagnosed or treated, additional AC may lead to irreversible HF. Many have proposed recommendations for early LVD detection in order to prevent transient LVD from becoming a debilitating complication of chemotherapy. For example, Schwartz et al25 reported that patients at high risk of developing HF could still be treated with AC provided that serial studies were performed after delivering set amounts of chemotherapy and that doxorubicin was discontinued when indicated. The AHA/ACC guidelines advise all patients undergoing treatment with anthracyclines to undergo baseline echocardiogram with assessment of both systolic and diastolic cardiac function and to monitor LVEF after administration of either half the planned dose or a cumulative dose of 300 mg/m2 of doxorubicin, as well as follow-up imaging at least 12 months after AC completion.13 14
This study found that only about one-third of patients who underwent AC for aggressive B-NHLs prior to the establishment of a comprehensive cardio-oncology programme had documentation of receiving the recommended LVEF assessments for AC-CMP monitoring. Cardinale et al11 26 demonstrated that, in the majority of patients, early detection and treatment of AC-CMP with standard of care HF therapy can result in partial or full recovery of LVEF. In our study, we observed that less than half of those who developed AC-CMP were referred to a cardiologist, received serial non-invasive cardiac monitoring or were treated with standard HF medications. These observations suggest that there is substantial opportunity for providers in oncology and cardiology to collaborate and improve on the current delivery of care in patients with AC-CMP.
This study does have several limitations as it is a small retrospective study at a single institution that focused on patients with B-NHL who received AC and regular follow-up. Patients who received care outside the Emory Healthcare system may have received the recommended surveillance and management, but their Emory records may be missing this information. The generalisability of our results is therefore limited to a subset of the targeted population that received the expected surveillance and treatment according to AHA guidelines. Nevertheless, to our knowledge, this is the first study to examine real-world surveillance and management practices of patients with AC-CMP. It is thus a comprehensive single institution approach to use evidence-based guidelines to evaluate practice patterns, which could eventually lead to practice improvement and provide metrics for other academic centres and community practices.
Barriers to improving AC-CMP surveillance patterns include unawareness of the scope of the problem, uncertainty regarding appropriate methods of diagnosis and management and lack of coordination between the two subspecialty fields. For example, the patients in this study were diagnosed with B-NHL during a period prior to the establishment of well-defined guidelines. The precise definition of cardiotoxicity and the recommendations for screening have not always been entirely clear; it has only been recently that both the Annals of Oncology and AHA/ACC guidelines agreed on LVD monitoring and treatment of systolic HF with β-blockers and ACE inhibitors unless contraindicated.14 15 Therefore, management of competing risks such as cancer relapse, treatment complications (eg, development of treatment-related cancers, infections, hypothyroidism, depression and/or atherosclerosis) and psychosocial factors have historically been prioritised.
In conclusion, this study showed that a minority of patients with aggressive B-NHL undergoing AC received guideline-based LVEF surveillance. Considering that reduced LV function is associated with worse morbidity and mortality, early identification of patients with LVD is essential to determine optimal oncological and cardiac management. Ideally, high-risk patients could be identified prior to developing LV dysfunction, and early identification and initiation of appropriate HF therapy could allow patients with mild cardiotoxicity to continue to receive AC under close observation and monitoring by a multidisciplinary team including both oncologists and cardiologists.27 28 This study represents a first step towards overcoming barriers to effective AC-CMP management by documenting the scope of the problem and suggesting specific areas of improvement. Systematically tackling these challenges could lead to improved diagnosis and management of AC-CMP in patients with lymphoma.
Footnotes
Contributors: OYH, JRB, CRF and SP were critically involved in the study design, collection and analysis as well as the preparation and editing of this manuscript. TD and KAE performed all statistical analyses in this study, provided substantial insight into data analysis and helped with manuscript preparation and editing.
Funding: OYH is supported by the National Institutes of Health Ruth L. Kirschstein National Research Service Award training grant (5T32HL007745).
Competing interests: None declared.
Ethics approval: Emory University Institutional Review Board.
Provenance and peer review: Not commissioned; externally peer reviewed.
Data sharing statement: No additional data are available.
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