Introduction

Exercise based rehabilitation has proven its value in reducing morbidity and mortality in patients with established heart disease [1-5]. The cardiovascular benefits of exercise training are multifactorial and include important local and systemic effects on skeletal muscle, the peripheral vasculature, the myocardium and the autonomic nervous system. Both parasympathetic and sympathetic tone have been shown to respectively in and decrease in humans and animals [6,7]. One of the more short term modulations of the autonomic nervous system seems to be the Heart Rate Recovery (HRR) [8]. HRR can be defined as the rate at which heart rate declines, usually within minutes after the cessation of physical exercise [9,10]. A delayed decrease in heart rate during the first minute after graded exercise is a powerful predictor of overall mortality in both patients with and without heart disease, independent of workload, the presence or absence of myocardial perfusion defects, and changes in heart rate during exercise [11].

Whether HRR may also serve as a powerful and convenient instrument to monitor improvement in training status during exercise based rehabilitation of patients with established heart disease remains, to our knowledge, to be proven. Therefore the aim of this study was to conduct a systematic review on the effect of aerobic training on HRR in patients with established heart disease.

Methods

Results

Description of search

We identified a total of 384 records in the initial search and removed 92 duplicate publications. Six records were added through searches in references. We excluded 273 non-relevant records based on title or abstract screening. Full-text articles were retrieved for 25 publications and assessed for eligibility (Figure 1). Four randomized controlled trials and four quasi-randomized controlled trials met the eligibility criteria (Table 1) [18-25]. Giallauria et al. investigated the effect of cycling three times a week with an intensity of 60-70% peak VO₂ in 37 STEMI patients with 38 controls. Legramante et al. trained 43 subjects with CABG on a bicycle for thirty minutes two times a day during six weeks with an intensity of 75-85 % of maximal heart rate. Moholdt et al. studied the effect of training on a treadmill versus exercises as walking, jogging, lunges and squats on 59 subjects with an AMI with 30 controls during 12 weeks. Twelve patients with chronic heart failure were compared with 12 controls by Myers et al. during eight weeks of cycling and walking training vs usual care. In 2012 Ribeiro et al. investigated the effect of aerobic exercise training on 20 patients with CAD compared to 18 patients with usual care. Tsai et al. trained 15 CABG patients with walking and running training during 12 weeks three times a week and compared them with 15 controls. Wu et al. made three groups of 18 patients with CABG and compared a cardiac rehabilitation program with home based exercises and a group with no exercises during twelve weeks. Finally twenty-seven patients with an AMI were trained by Zeng et al. for twenty-six weeks with cycling training three times a week on the anaerobic threshold for thirty minutes. Table S3 shows the studies not included in the review (15 prospective or retrospective cohort studies and 2 RCT’s in which the control group received a different therapy than usual care or no therapy).

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Figure 1. Description of search.

Selection of trials investigating heart rate recovery.

https://doi.org/10.1371/journal.pone.0083907.g001

Author	Study population	Groups	Participants (n)per group	Stress test	Measure-ment HRR	Type of training	Frequency + length of training	Intensity of training	Length of rehab.	Change HRR (60 sec)
Giallauria et al (2011)	STEMI	2	37,38	Bicycle	60 sec	Cycling	E: 3 x p.w. 40 min C: untrained	60-70 % peak VO2	26 wk	E: 13 → 20* C: 14 → 12*
Legramante et al (2007)	CABG	2	43,39	Bicycle	60 sec + other	Cycling	E: 6 x p.w. 2 x p.d 30 min C: untrained	75-85 % HR max	2 wk	E: 8 → 12 C: 7 → 10
Moholdt et al (2011)	AMI	2	59,30	Treadmill	60 sec	Treadmill vs W+J+L+S	E: 3 x p.w. 38 min C: 3 x p.w. 60 min	E: 85-95 % HR max C: Vigorous exercise	12 wk	E: 31 → 33 C: 33 → 34
Myers et al (2007)	CHF	2	12,12	Bicycle	60 sec + other	Cycling Walking	E: 4 x p.w. 45 min + 2 x p.d. 60 min C: usual care	E: 60-80 % HR reserve	8 wk	E: 8 → 14 C: 9 → 10
Ribeiro et al (2012)	CAD	2	20,18	Treadmill	60 sec	Aerobic exercise	E: 3 x p.w. 55 min C: usual care	65-75 % HR max	8 wk	E: 20 → 24* C: 26 → 26*
Tsai et al (2005)	CABG	2	15,15	Bicycle	60 sec	Cycling; Walking	E: 3 x p.w. 30-40 min C: No cardiac rehabilitation	60-80 % HR max	12 wk	E: 4 → 16* C: 5 → 11*
Wu et al (2006)	CABG	3	18,18,18	Bicycle	60 sec	Cycling; Treadmill	E: 3 x p.w. 50-80 min Eh: 3 x p.w. 50-80 min C: No exercise	60-85 % HR max	12 wk	E: 9 → 19* Eh: 8 → 16 C: 9 → 14*
Zeng et al (2008)	AMI	2	27,30	Bicycle	60 sec	Cycling	E: 3 x p.w. 30 min C: No exercise	AT	26 wk	E: 12 → 17* C: 12 → 12*

Table 1. Overview of (quasi) Randomized Controlled Trials included in the review.

Abbreviations: n (number); Change HRR (Change in Heart Rate Recovery from begin- to endpoint); STEMI (ST Elevated Myocardial Infarction); CABG (Coronary Artery Bypass Graft); AMI (Acute Myocardial Infarction);W+J+L+S (Walking, Jogging, Lunges, Squats); CHF (Chronic Heart Failure); CAD (Coronary Artery Disease); E (Exercise group); Eh (Exercise at home group); C (Control group); VO₂ (oxygen uptake); HR (Heart Rate); AT (Anaerobic Threshold) * Significant (p<0.05) between group difference

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Discussion

The present systematic review shows that aerobic training increases heart rate recovery in patients with established heart disease. Of the eight eligible studies found in our systematic review, five met the criteria for methodological quality and three met the requirements for therapeutic validity. Only two studies showed both a low risk of bias and a high therapeutic validity. Both studies showed a significant improvement of HRR after exercise training compared to no training. Although only two out of the eight eligible studies met the predetermined criteria and the total number of patients is limited, they showed a homogenic conclusion. On this basis we conclude that the present systematic review shows a level 1A evidence that aerobic training increases heart rate recovery in patients with established heart disease.

HRR has been identified as a powerful predictor of overall mortality [11]. Cole et al. described an adjusted relative risk of 2,0 (95% CI 1.5 - 2.7) for patients with a reduction in heart rate of 12 beats per minute or less after maximal exercise when adjustments were made for age, sex, the use or non-use of medications, the presence or absence of myocardial perfusion defects on thallium scintigraphy, standard cardiac risk factors, the resting heart rate, the change in heart rate during exercise, and workload achieved. Several studies were started thereafter in an attempt to increase HRR in patients with heart diseases using aerobic training, but a systematic review to elucidate the real effects was lacking to our knowledge.

Exercise-based cardiac rehabilitation has proven its value in reducing total and cardiovascular mortality and hospital admissions with reported relative risk of 0.87 (95% CI 0.75 - 0.99), 0.74 (95% CI 0.63 - 0.87) and 0.69 (95% CI 0.51 - 0.93) respectively [1]. CR is widely recommended for all patients with an acute coronary syndrome (ACS), and for those who have undergone coronary artery bypass graft or valvular surgery or even percutaneous coronary interventions (PCI) [26,27]. Cardio pulmonary exercise testing is considered the gold standard for the measurement of exercise capacity in CR. However, it is expensive, time consuming and not always available for all clinics. In contrast, HRR determination is easy to use and inexpensive. When validity and reliability are determined to be sufficient, it may be a powerful and convenient instrument to monitor improvement in training status of patients with established heart disease.

The observation of HRR increase during exercise based CR in cardiac patients is in line with observations in athletes [28]. Daanen et al. conclude that HRR has the potential to become a valuable tool to monitor changes in training status in athletes and less well-trained subjects.

Whether the improvement of HRR by CR also reduces mortality is an important question linked to the validity of HRR monitoring. Jolly et al. not only showed in a retrospective cohort study that HRR improved after CR [29], but also found a strong association between abnormal HRR (HRR values ≤ 12 bpm) at exit of CR with all-cause mortality (hazard ratio, 2.15; 95% confidence interval 1.43–3.25). Patients with abnormal HRR at baseline who normalized HRR with exercise had a mortality similar to that of individuals with baseline normal HRR. They evaluated 1070 patients who underwent exercise stress testing before and after completion a CR program. Of 544 patients with abnormal baseline HRR, 225 (41%) had normal HRR after rehabilitation. Among patients with an abnormal HRR at baseline, failure to normalize after rehabilitation predicted a higher mortality (P < 0.001).

Despite these clear results, other variables than training status have to be considered as possible confounders for the change in HRR during CR programs. Namely.

All patients were diagnosed as having some kind of cardiovascular disease or surgery. Normal physical recovery after cardiac events (AMI, CAD or revascularisation surgery (CABG or PCI) also influence HRR. During normal recovery from surgery HRR will also increase without an exercise intervention in due time [22]. Therefore, the only way to show the additional effect of aerobic training over normal recovery is to have an experimental and control group. Our review showed an additional effect of exercise training compared to no training or usual care in cardiovascular populations. In all studies the training protocols were clearly defined. The usual care or no training protocol, however, showed some variations. Moholdt et al. presented for instance that the exercise intensity of 'usual care' was described vigorous [24].

Secondly HRR is measured over different time frames, generally ranging between 30 seconds and 2 minutes. Most studies use the difference between the end value of exercise and the heart rate after 60 seconds of recovery from an exercise test. In addition to this variation, the exercise intensity during the recovery period is not always described in detail. This can vary from complete rest to a percentage of maximal exercise intensity. In order to be able to compare HRR results, consensus should be reached regarding the way the recovery period is organized. We propose, in line with most studies, to have no exercise at all.

Finally the type of exercise modality can be of influence on HRR. HRR yields higher values for running than for cycling, which is probably related to the higher aerobic demands in running [30]. Although our review consisted of bicycle and treadmill exercise tests, both studies with a low risk of bias and a high therapeutic validity were executed on a bicycle. It can be expected that the relation between training status and HRR is better for treadmill testing than cycling.

While a clear effect exists of exercise therapy per se, no correlation was found between the duration or intensity of exercise therapy and the change in HRR when every included study was taken as a data point. This is probably due to the considerable differences between the studies in terms of training duration, training intensity, type of exercise, patient group included and so on.

An interesting question remains if the results of the present review can be generalized to other cardiac patients or other diseases. We speculate that the benefits of exercise training would extend to these patient groups, although further research will be needed to demonstrate this. For patients with established heart disease HRR has a prognostic value and can be improved by cardiac rehabilitation.

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