Exercise-based cardiac rehabilitation in stable angina pectoris: a narrative review on current evidence and underlying physiological mechanisms

Stable angina pectoris (SAP) is caused by myocardial ischaemia, with symptoms typically being provoked during increased cardiac demand, such as during physical activity. Several causes can lead to the supply-demand mismatch, with obstructive coronary artery disease being the most common. Although there may also be a role for microvascular dysfunction, we have primarily focussed on the macrovasculature in this review. Currently, initial treatment consists of preventive and antianginal medication to reduce symptoms and to improve quality of life and long-term morbidity and mortality. When symptoms persist, coronary angiography and subsequent revascularisation (i.e. percutaneous coronary intervention (PCI) or coronary artery bypass grafting) are commonly applied. Approximately 35% of all (~40,000) PCIs in the Netherlands are performed in patients with stable coronary artery disease [1]. Although revascularisation can result in rapid symptom relief [2], long-term prognostic advantages seem limited [2‐5] and are increasingly debated. A recent randomised controlled trial (RCT) compared revascularisation with optimal medical therapy in 5179 SAP patients with myocardial ischaemia, and found no between-group differences in mortality or major adverse cardiovascular events (MACE) after a median 3.2-year follow-up [2]. Furthermore, a meta-analysis of 14 trials also showed no difference in all-cause mortality and cardiovascular mortality between revascularisation or optimal medical therapy alone after a median follow-up of 4.5 years [4]. Although this meta-analysis found more freedom of angina in favour of revascularisation, a more recent meta-analysis showed no difference between groups after 12-months of follow-up [5]. Finally, the ORBITA trial, the only double-blind study comparing PCI versus a sham procedure in SAP, showed no difference in symptoms and exercise capacity in 200 patients after a 6-week follow-up [3]. These observations question the value of revascularisation for relief of symptoms, even in the short term, and for prevention of cardiovascular events in the longer term in patients with SAP.

The lack of clinical benefit for revascularisation strategies may be explained by its focus on treating local flow-limiting coronary artery lesions, while the aetiology of SAP relates to the systemic, inflammatory process of atherosclerosis. This dynamic and gradual process involves chronic low-grade inflammation, not only causing the focal development of a flow-limiting stenosis, but also generalised vascular dysfunction and non-obstructive coronary lesions [6]. As a direct consequence, the risk of MACE is not solely related to a flow-limiting stenosis, but more likely relates to the plaque burden and high-risk plaque features along the entire coronary artery tree. Indeed, increasing evidence supports the hypothesis that coronary artery lesions which later cause acute myocardial infarctions often do not narrow the lumen critically [6]. This highlights the need for alternative strategies for patients with SAP to reduce cardiovascular risk and improve quality of life, preferably focusing on improving the cardiovascular system as a whole.

Atherosclerosis is often accelerated by poor medication adherence [7] and a persisting unhealthy lifestyle [8], resulting in recurrent symptoms and cardiovascular events. Therefore, changing lifestyle behaviour should be a central target in the treatment of SAP. As such, cardiac rehabilitation (CR) was shown to improve prognosis, quality of life and medication adherence and reduce hospitalisation rates in patients with coronary heart disease [9]. A meta-analysis showed that contemporary CR in patients with SAP improved exercise capacity and resulted in a reduction of angina [10]. Nonetheless, a 2018 Cochrane review concluded that there is currently insufficient data to validly assess the impact of exercise-based CR on morbidity, mortality and quality of life in this patient group [11]. However, inclusion criteria for patients with SAP were strict, which hampers wider translation, and new studies have since been published.

The aim of this review is first to summarise the physiological mechanisms underlying the potential clinical benefits of exercise-based CR. Secondly, characteristics of exercise-based CR are described, followed by clinical evidence pertaining to the effects of exercise-based CR for SAP. Finally, recommendations for future research are provided. As exercise training is mostly embedded in a comprehensive CR programme, and is not a stand-alone intervention, the term exercise-based CR is used in this review to emphasise the focus on the effect of exercise training. Exercise terms and definitions are described in Tab. 1.

Positive effects of exercise training can be explained by multiple physiological factors [12]. One of these factors is increase in muscle mass and lung capacity, which contributes to increased cardiorespiratory fitness and is associated with a lower cardiovascular risk. In fact, cardiorespiratory fitness is a strong predictor of both cardiac and all-cause mortality in patients with cardiovascular disease (CVD) [13]. For this review, we specifically focus on the effects of exercise-based CR on the vasculature (Fig. 1), including changes in vascular function, vascular structure, atheroma volume and the development of coronary collateral vessels. These effects may be key to reducing symptoms and improving prognosis in patients with SAP.

Whereas exercise-based CR comes in different forms and intensities, the characteristics of the optimal exercise training programme for SAP are still inconclusive. Multiple factors, described by the FITT-principle (frequency, intensity, time and type) may determine the effects on cardiorespiratory fitness (CRF), and therefore possibly health-related outcomes.

Pertaining to exercise intensity, a 2021 meta-analysis comparing the effect of different exercise intensities on CRF (VO2peak) showed moderate-to-vigorous and vigorous exercise were the most effective intensities to enhance CRF [38]. Similarly, meta-analyses show high-intensity interval training to be superior to moderate-intensity continuous training in improving CRF and cardiovascular risk factors [35, 39]. However, further research is needed to assess the safety and effect of higher training intensities, particularly because patients with SAP are underrepresented in previous studies. Although evidence does not indicate that supervised training on or above the ischaemic threshold is unsafe [40], the European Association of Preventive Cardiology advises training intensity between the first and the second ventilatory threshold.

Frequency and duration of exercise bouts are typically combined into the amount or volume of exercise, which is often presented against the risk of cardiovascular events through a curvilinear dose-response relation. The largest relative health benefit is achieved in patients who change from being inactive to some activity, while each additional increase in physical activity leads to a smaller health benefit, eventually leading to a plateau. When focusing on possible adverse effects of physical activity, a large observational cohort study found that large volumes of exercise were associated with more coronary plaques [41]. Although work suggested this may be driven by the vigorous intensity, rather than volume per se [42], training intensities and volumes were not objectively measured and the effect of these adaptations on the risk of MACE is still undefined.

The two most commonly applied exercise training modalities relate to aerobic and resistance training. Aerobic training is typically classified in light-, moderate- and high-intensity training, as discussed in more detail above, and is strongly linked to improvements in cardiorespiratory fitness. In addition, resistance training consists of repetitive exercise bouts and is aimed to improve muscle strength and volume. Given their distinct working mechanisms and effects, it is not surprising that studies support the combination of aerobic and resistance training rather than aerobic training alone to achieve the greatest benefits [37]. Contemporary exercise-based CR indeed includes both types of exercise.

Taken together, the FITT-principles are important factors in designing exercise programmes. Whilst the optimal combination of FITT has not been specified, an emerging challenge of CR and follow-up cardiac care is the continued adherence to a physically active and healthy lifestyle. The optimal approach to achieve this is still unresolved, but may include a more personalised approach, extended guidance after CR, or the possibility of repeat prescriptions. Based on the ‘exercise is medicine’ principle, an important consideration is that, as opposed to most medicine, exercise is largely free of adverse effects.

As shown above, exercise has beneficial, dose-dependent health effects, including in CVD [43, 44]. Higher physical activity levels are associated with a lower risk of death and cardiovascular events, irrespective of country and income [43]. Besides the benefits of exercise training as adjuvant therapy for various disease states, exercise training has also proven to be clinically and economically beneficial as initial therapy, for example for intermittent claudication [45, 46]. Given that both intermittent claudication and SAP share the systemic involvement of atherosclerosis in their pathophysiology, exercise training could also be a beneficial therapy for patients with SAP.

In coronary artery disease, and SAP specifically, studies investigated the effect of exercise-based CR as adjuvant therapy after revascularisation. An observational cohort study using Dutch health insurance data showed a 31% lower risk of all-cause mortality in CR participants compared with nonparticipants with SAP, both with or without revascularisation [47]. This health benefit in SAP is in agreement with the overall 32% lower risk of all-cause mortality associated with CR in this study. Another Dutch population-based cohort study showed that multidisciplinary CR is associated with a substantial 4‑year survival benefit, an effect that was present regardless of the type of intervention or diagnosis (i.e. acute coronary syndrome, SAP) [48]. Moreover, a prospective registry analysis in patients with long coronary artery lesions (~70% SAP) showed that CR resulted in 35% less late luminal loss in the stented segment after 9 months compared with the control group [49]. Taken together, these data suggest that exercise-based CR as an adjuvant therapy following PCI is associated with better survival and a lower risk of MACE.

However, only a few studies have explored exercise-based CR as initial therapy for SAP and directly compared results against revascularisation. A recent retrospective cohort study evaluated health insurer data of 18, 383 patients with chronic coronary syndrome and found that prescription of CR (without revascularisation) is associated with a significantly lower risk of all-cause mortality and acute myocardial infarction compared with revascularisation alone [50]. Whilst these retrospective analyses provide insight, RCTs are needed to directly evaluate effects of exercise-based CR in SAP. To our knowledge, Hambrecht et al. published the only RCT comparing PCI with daily exercise training over a period of 1 year and found a significantly lower event rate and higher exercise capacity in favour of the exercise group [51]. These benefits persisted after 2‑years of follow-up. Taken together, studies suggest superior clinical outcomes following exercise-based CR compared with revascularisation as a primary treatment for SAP, although contemporary, properly designed and powered RCTs are warranted to confirm these observations.

Preliminary studies have provided provocative data supporting the idea that exercise-based CR has the potential to complement and possibly even replace revascularisation as a first-line treatment for SAP in addition to optimal medical therapy. For this reason, high-quality, randomised trials are needed to assess the physiological and clinical benefits of exercise-based CR for patients with SAP. In achieving maximal benefits, both in the short and the long term, investigators should consider comparing different forms of exercise training and should focus on prolonged guidance to optimise long-term adherence to improved physical activity levels. Pertaining to implementation and dissemination of this knowledge, it should be noted that changing clinicians’ views and long-standing paradigms is a great challenge since revascularisation therapy is widely assumed to be a quick and effective strategy to achieve symptom reduction, despite the high costs and the current debate on its effect on prognosis and clinical benefits. Taken together, it is time to view exercise as medicine for the management of SAP and in this attempt it is important to closely involve clinicians, patients and other stakeholders to optimise and implement this novel care pathway.