Exercise-based cardiac rehabilitation for coronary heart disease

Abstract

Background: Coronary heart disease (CHD) is the single most common cause of death globally. However, with falling CHD mortality rates, an increasing number of people live with CHD and may need support to manage their symptoms and prognosis. Exercise-based cardiac rehabilitation (CR) aims to improve the health and outcomes of people with CHD. This is an update of a Cochrane systematic review previously published in 2011.

Objectives: To assess the effectiveness and cost-effectiveness of exercise-based CR (exercise training alone or in combination with psychosocial or educational interventions) compared with usual care on mortality, morbidity and HRQL in patients with CHD.To explore the potential study level predictors of the effectiveness of exercise-based CR in patients with CHD.

Search methods: We updated searches from the previous Cochrane review, by searching Cochrane Central Register of Controlled Trials (CENTRAL) (The Cochrane Library, Issue 6, 2014) from December 2009 to July 2014. We also searched MEDLINE (Ovid), EMBASE (Ovid), CINAHL (EBSCO) and Science Citation Index Expanded (December 2009 to July 2014).

Selection criteria: We included randomised controlled trials (RCTs) of exercise-based interventions with at least six months' follow-up, compared with a no exercise control. The study population comprised men and women of all ages who have had a myocardial infarction (MI), coronary artery bypass graft (CABG) or percutaneous coronary intervention (PCI), or who have angina pectoris, or coronary artery disease. We included RCTs that reported at least one of the following outcomes: mortality, MI, revascularisations, hospitalisations, health-related quality of life (HRQL), or costs.

Data collection and analysis: Two review authors independently screened all identified references for inclusion based on the above inclusion and exclusion criteria. One author extracted data from the included trials and assessed their risk of bias; a second review author checked data. We stratified meta-analysis by the duration of follow up of trials, i.e. short-term: 6 to 12 months, medium-term: 13 to 36 months, and long-term: > 3 years.

Main results: This review included 63 trials which randomised 14,486 people with CHD. This latest update identified 16 new trials (3872 participants). The population included predominantly post-MI and post-revascularisation patients and the mean age of patients within the trials ranged from 47.5 to 71.0 years. Women accounted for fewer than 15% of the patients recruited. Overall trial reporting was poor, although there was evidence of an improvement in quality of reporting in more recent trials.As we found no significant difference in the impact of exercise-based CR on clinical outcomes across follow-up, we focused on reporting findings pooled across all trials at their longest follow-up (median 12 months). Exercise-based CR reduced cardiovascular mortality compared with no exercise control (27 trials; risk ratio (RR) 0.74, 95% CI 0.64 to 0.86). There was no reduction in total mortality with CR (47 trials, RR 0.96, 95% CI 0.88 to 1.04). The overall risk of hospital admissions was reduced with CR (15 trials; RR 0.82, 95% CI 0.70 to 0.96) but there was no significant impact on the risk of MI (36 trials; RR 0.90, 95% CI 0.79 to 1.04), CABG (29 trials; RR 0.96, 95% CI 0.80 to 1.16) or PCI (18 trials; RR 0.85, 95% CI 0.70 to 1.04).There was little evidence of statistical heterogeneity across trials for all event outcomes, and there was evidence of small study bias for MI and hospitalisation, but no other outcome. Predictors of clinical outcomes were examined across the longest follow-up of studies using univariate meta-regression. Results show that benefits in outcomes were independent of participants' CHD case mix (proportion of patients with MI), type of CR (exercise only vs comprehensive rehabilitation) dose of exercise, length of follow-up, trial publication date, setting (centre vs home-based), study location (continent), sample size or risk of bias.Given the heterogeneity in outcome measures and reporting methods, meta-analysis was not undertaken for HRQL. In five out of 20 trials reporting HRQL using validated measures, there was evidence of significant improvement in most or all of the sub-scales with exercise-based CR compared to control at follow-up. Four trial-based economic evaluation studies indicated exercise-based CR to be a potentially cost-effective use of resources in terms of gain in quality-adjusted life years.The quality of the evidence for outcomes reported in the review was rated using the GRADE method. The quality of the evidence varied widely by outcome and ranged from low to moderate.

Authors' conclusions: This updated Cochrane review supports the conclusions of the previous version of this review that, compared with no exercise control, exercise-based CR reduces the risk of cardiovascular mortality but not total mortality. We saw a significant reduction in the risk of hospitalisation with CR but not in the risk of MI or revascularisation. We identified further evidence supporting improved HRQL with exercise-based CR. More recent trials were more likely to be well reported and include older and female patients. However, the population studied in this review still consists predominantly of lower risk individuals following MI or revascularisation. Further well conducted RCTs are needed to assess the impact of exercise-based CR in higher risk CHD groups and also those presenting with stable angina. These trials should include validated HRQL outcome measures, explicitly report clinical event outcomes including mortality and hospital admissions, and assess costs and cost-effectiveness.

Conflict of interest statement

RST, KR, NO and DRT were authors of the original Cochrane review. RST is an author on number of other Cochrane CR reviews and is currently the co‐chief investigator on the programme of research with the overarching aims of developing and evaluating a home‐based CR intervention for people with heart failure and their carers (PGfAR RP‐PG‐0611‐12004). ADZ is an author on other Cochrane CR reviews and the Principal Investigator of ongoing CR trials (the DANREHAB trial and the CopenHeart trials). NM and LA have no known conflicts of interest.

Figures

1

Summary of study selection process

2

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

3

Total mortality for all studies at their longest follow‐up. Filled diamonds represent the risk ratio (RR) for individual studies at the longest reported follow‐up. The boxes are proportional to the weight of each
 study in the analysis and the lines represent their 95% confidence interval (CI). The open diamond represents the pooled RR, and its width represents its
 95% CI.

4

CV mortality for all studies at their longest follow‐up. Filled diamonds represent the risk ratio (RR) for individual studies at the longest reported follow‐up. The boxes are proportional to the weight of each
 study in the analysis and the lines represent their 95% confidence interval (CI). The open diamond represents the pooled RR, and its width represents its
 95% CI.

5

Fatal and / or nonfatal MI for all studies at their longest follow‐up. Filled diamonds represent the risk ratio (RR) for individual studies at the longest reported follow‐up. The boxes are proportional to the weight of each
 study in the analysis and the lines represent their 95% confidence interval (CI). The open diamond represents the pooled RR, and its width represents its
 95% CI.

6

CABG for all studies at their longest follow‐up. Filled diamonds represent the risk ratio (RR) for individual studies at the longest reported follow‐up. The boxes are proportional to the weight of each
 study in the analysis and the lines represent their 95% confidence interval (CI). The open diamond represents the pooled RR, and its width represents its
 95% CI.

7

PCI for all studies at their longest follow‐up. Filled diamonds represent the risk ratio (RR) for individual studies at the longest reported follow‐up. The boxes are proportional to the weight of each
 study in the analysis and the lines represent their 95% confidence interval (CI). The open diamond represents the pooled RR, and its width represents its
 95% CI.

8

Hospital admissions for all studies at their longest follow‐up. Filled diamonds represent the risk ratio (RR) for individual studies at the longest reported follow‐up. The boxes are proportional to the weight of each
 study in the analysis and the lines represent their 95% confidence interval (CI). The open diamond represents the pooled RR, and its width represents its
 95% CI.

9

Funnel plot of comparison: 1 Exercise‐based rehabilitation versus usual care, outcome: 1.3 Fatal and/or nonfatal MI.

10

Funnel plot of comparison: 1 Exercise‐based rehabilitation versus usual care, outcome: 1.6 Hospital admissions.

1.1. Analysis

Comparison 1 Exercise‐based rehabilitation versus usual care, Outcome 1 Total mortality.

1.2. Analysis

Comparison 1 Exercise‐based rehabilitation versus usual care, Outcome 2 Cardiovascular mortality.

1.3. Analysis

Comparison 1 Exercise‐based rehabilitation versus usual care, Outcome 3 Fatal and/or nonfatal MI.

1.4. Analysis

Comparison 1 Exercise‐based rehabilitation versus usual care, Outcome 4 CABG.

1.5. Analysis

Comparison 1 Exercise‐based rehabilitation versus usual care, Outcome 5 PCI.

1.6. Analysis

Comparison 1 Exercise‐based rehabilitation versus usual care, Outcome 6 Hospital admissions.