Abstract
The objective of this study is to evaluate the effect of exercise on cardiac autonomic function as measured by short-term heart rate variability (HRV) in females suffering from rheumatoid arthritis (RA). Females with confirmed RA were randomly assigned to an exercise group (RAE) and a sedentary group (RAC). RAE was required to train under supervision two to three times per week, for 3 months. Three techniques (time domain, frequency domain and Poincaré plot analyses) were used to measure HRV at baseline and study completion. At baseline, RAC (n = 18) had a significantly higher variability compared to RAE (n = 19) for most HRV indicators. At study completion, the variables showing significant changes (p = 0.01 to 0.05) favoured RAE in all instances. Wilcoxon signed rank tests were performed to assess changes within groups from start to end. RAE showed significant improvement for most of the standing variables, including measurements of combined autonomic influence, e.g. SDRR (p = 0.002) and variables indicating only vagal influence, e.g. pNN50 (p = 0.014). RAC mostly deteriorated with emphasis on variables measuring vagal influence (RMSSD, pNN50, SD1 and HF (ms2)). Study results indicated that 12 weeks of exercise intervention had a positive effect on cardiac autonomic function as measured by short-term HRV, in females with RA. Several of the standing variables indicated improved vagal influence on the heart rate. Exercise can thus potentially be used as an instrument to improve cardiac health in a patient group known for increased cardiac morbidity.
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Introduction
Rheumatoid arthritis (RA) patients are usually sedentary, limiting physical activity due to the perceived danger of eliciting pain or damaging their joints [1]. Although there is still no cure for RA, much can be done to manage the condition. There is compelling evidence that exercise can play a significant role in the physical and psychosocial health of RA patients [2, 3]. However, only a limited number of studies exist on the relation of exercise interventions to cardiovascular disease in these patients [4].
Cardiovascular disease is a well-described entity in RA patients [5–7]. Conventional risk factors (abnormal body mass index (BMI), abnormal lipogram, smoking, hypertension, diabetes mellitus, family history of cardiac disease and a personal history of cardiac disease) [8, 9], accelerated atherosclerosis due to inflammation [7, 10, 11], and autonomic dysfunction [12–15] can all play a role in the etiopathogenesis.
Exercise has been identified as one of the most important behavioural strategies for cardiovascular disease prevention, and sedentary individuals (like RA sufferers) will benefit by just a slight increase in physical activity [16, 17]. Previous studies in non-RA groups demonstrated that exercise will improve autonomic function (as measured by heart rate variability (HRV)) [18–21]. Abnormal autonomic function marked by decreased HRV induces an increased dysrhythmogenic potential [22, 23]. An article by Routledge et al. in 2010 reviewed HRV modification via exercise therapy in patients with clinical conditions [24]. Similar studies have not been done in the RA population. The aim of the current study was to evaluate the effect of exercise on cardiac autonomic function as measured by short-term HRV in RA patients.
Materials and methods
This study was a randomised experimental design with a prospective analytical pre-post group comparison. Ethical approval was granted by the Ethical Committee of the Faculty of Health Sciences at the University of Pretoria. Patients in the Pretoria region of South Africa were recruited from private rheumatology practices and state hospital rheumatology clinics.
Patients with RA who conformed to the inclusion and exclusion criteria were invited to an information and orientation meeting. After which, informed consent was signed by all participants. Inclusion criteria included that participants should be females between the age of 30 and 60, with confirmed RA (according to the 1987 American College of Rheumatology criteria) [25], class I or II disease (according to the classification of global functional status in RA) [26], controlled disease (i.e. on stable evidence-based medication for at least 3 months and DAS28 scores of low to moderate activity), and voluntary participation. The exclusion criteria included smoking, known cardiovascular disease, pulmonary disease, diabetes mellitus, neurological disease, use of drugs that can interfere with the autonomic nervous system or the cardiovascular system (anti-hypertensives, anti-arrhytmic drugs, diuretics, anti-epileptics, vasodilators, adrenergic inhibitors, sedatives and hypnotics), liver or kidney disease and participation in a physical training programme in the last year.
Colour-coded buttons representing each group (RA control = yellow, RA exercise = blue) were put in a non-transparent bag. Each participant had to draw one of these colour-coded buttons. The administrator allocated the participants into two different groups according to the colour of the buttons, i.e. an exercise group (RAE) and a control group (RAC). The RAE group was required to train two to three times per week, while the RAC group was instructed to continue with their sedentary lifestyle. The programme was conducted over 3 months (12 weeks). All exercise sessions were supervised by a biokineticist (exercise specialist). Exercise intervention consisted of warm-up exercises, strengthening exercises, aerobic exercises and a cool-down period which included stretching. The duration of each session was approximately 45 min.
The warm-up exercise consisted of 5 min of walking, pool jogging or pool noodle cycling. The aerobic exercise lasted for 20 min at 60–80 % of peak HR doing either treadmill walking, water cycling or water jogging. Flexibility exercise included stretching for each of the major joints (neck stretch, shoulder rolls, lying hamstring stretch, standing hip flexor stretch, calf stretches and pectoral stretch). Five repetitions held for 30 s each were performed. The strength exercises included chest press, bicep curls, lateral pull-downs, hip extension, leg presses, hamstring curls and hip abduction. The intensity and repetitions of these exercises were increased every second week [27, 28].
Measurements for HRV were done at baseline (onset of the programme) and after 12 weeks (study completion). HRV is a validated, non-invasive method to study the influence of the autonomic nervous system (ANS) on the heart. The parasympathetic and sympathetic nerves act on the intrinsic rhythm, and this causes beat to beat variations in the RR interval on the ECG [18, 29, 30].
HRV data sampling
For sampling of the RR-interval data, the participants were instructed not to train for 48 h before data sampling and to fast from 2200 hours the previous evening. A low protein breakfast (cereal with milk only) was permitted on the morning of testing. No alcohol or caffeine was allowed during the preceding 24 h. Data was sampled in the morning in a quiet setting with a room temperature of about 22°C. Recordings were made over a period of 20 min.
Each participant put on a Polar 810i strap and transmitter and was then placed in a supine (resting) position for 10 min, breathing spontaneously without talking. This was followed by a 10-min orthostatic stressor with participants standing (stress) in an upright position, with their backs leaning against the wall and their feet apart. RR intervals from a stationary 5-min resting period and a stationary 5-min standing period were used for analyses.
HRV quantification
Standard Polar software programs with a minimum beat protection zone of six beats per minute and a low filter power were used to remove artefacts in RR-interval data. The data (RR-interval sets) were analysed using software for HRV analysis obtained from the University of Kuopio, Finland. Smoothness priors for trend and Model Eye program settings were used for detrending with an alpha value of 500. The autoregressive model order value was 16, and the interpolation rate was 4 Hz. The techniques used for the evaluation of HRV from RR-interval data sets were grouped into three categories: time domain, frequency domain and non-linear analysis (Poincarè plot analysis) [29, 31]. As there is no gold standard for HRV measurements and no method has been identified as being superior to another, it was decided to use all three techniques as they are complementary to each other [32]. Time domain indicators that were determined included RR interval (the mean of the intervals between successive QRS complexes) and SDRR (the standard deviation of intervals between successive QRS complexes) representing vagal and sympathetic influence, i.e. total variability. RMSSD (root mean square of the standard deviation between RR intervals) and pNN50 (percentage of successive RR interval differences larger than 50 ms computed over the entire recording) representing pure vagal influence on HRV were also determined [29].
Spectral components analysed with frequency domain analysis included high frequency (HF = 0.15–0.40 Hz), low frequency (LF = 0.04–0.15 Hz), HF normalised units (nu), LF (nu) and the LF/HF ratio. The indicators LF/HF, LF (nu) and HF (nu) were used as indicators of autonomic balance or relative power distribution between the sympathetic and parasympathetic branches of the ANS. LF (nu) represents the relative power of the LF component in proportion to the total power minus the VLF component. HF (nu) represents the relative power of the HF component in proportion to the total power minus the VLF component, while LF/HF is used to assess the fractional distribution of power [30]. The Poincarè analysis method produced the indicators SD1 and SD2. SD1 is an indicator of the standard deviation of the immediate, or short-term, RR variability due to parasympathetic efferent (vagal) influence on the sino-atrial node. SD2 is an indicator of the standard deviation of the long-term or slow variability of the heart rate representing global variation [31]. A summary of the HRV analysis techniques, specific HRV indicators and origins of variability is explained in Table 1.
Data analysis
Since most of the variables were skewed, non-parametric tests were conducted. Only two groups (RAE and RAC) were reported on, hence non-parametric Mann–Whitney U tests were performed to determine which dependent variables differed between the two groups. These tests are analogous to independent samples’ t tests.
Data analysis was also performed within the two groups (RAE and RAC), comparing pre- and post-intervention measurements. Wilcoxon signed rank tests, which are analogous to paired sample t tests, were used to determine whether there was a statistical improvement within each group.
The conventional 5 % level of significance was specified, and in all instances, the p values of the non-parametric tests are reported. Effect sizes are reported as a standardised measure of the observed effect. For the few variables that did not violate the assumption of normality, a power analysis was also performed.
Results
At study onset, the RAE group consisted of 24 patients, and the RAC group, of 22. In the RAE group, five (20.83 %) of the subjects did not complete the study, versus four (18.18 %) in the RAC group. Reasons for not completing the study included difficulty to conform to time and frequency of training (four from the RAE group), moved to another town (one from the RAE group), not available for post-intervention measurements due to other commitments (two from the RAC group) and loss of interest (two from the RAC group). Data analyses were only performed on those subjects who completed the study (RAE group 19, RAC group 18) because the study focused on the effect of an exercise intervention and we did not want to bias results by including subjects not completing the study. This sample size is similar to the average sample size of clinical studies that evaluated HRV modification via exercise intervention [24]. Routledge et al. in 2010 evaluated 19 published articles, with the average sample size calculated as 21.2 (±10.6).
Information on age, anthropometric data, disease duration, disease activity, medication used with regard to RA and presence of auto-antibodies is displayed in Table 2. Subjects were required to stay on the same medication regime for the duration of the study, and no intramuscular or intra-articular corticosteroid injections were allowed. BMI has previously been reported by some authors as a confounding factor [33, 34]. From the median test, the medians of the BMI did not differ significantly between the two groups (p = 0.127) although evidence exists that the distribution of the BMI was not identical across the two groups (Mann–Whitney U p = 0.05). Regression models that included BMI as a covariate did not support the evidence that BMI is a confounder in this study.
The heart rate variability of the two groups was compared at baseline, and statistics of variables displaying significant initial bias can be viewed in Table 3. At baseline, the RAC group had significantly higher heart rate variability compared to the RAE group for some of the supine variables and most of the standing variables. The RAE group did not show a significant higher variability than the RAC group for any variable pre-intervention.
To compensate for the initial bias between the two groups, the pre-values were subtracted from the post-values, to assess if the exercise intervention caused changes that favoured any of the two groups. The variables that showed significant differences in changes at study completion are displayed in Table 4. These amounted to medium to large effects [35] and favoured the RAE group in all instances.
To evaluate any changes that occurred within each group from the start of the intervention to the completion, Wilcoxon signed rank tests were performed. The RAE group showed statistical significant changes for SDRR in the supine position and for SDRR and pNN50 in the stress position. The RAC group showed statistical significant changes for SDRR (supine), SDRR (stress), RMSSD (stress), pNN50 (stress), SD1 (stress) and LF/HF (stress). The variables for both groups are displayed in Table 5 and again amounted to medium to large effects [35]. Although not statistically significant at the specified 5 % level of significance, there was moderate evidence (α < 0.10) of change in many variables (RAE group: RR (supine), LF (nu) (supine), RR (stress), HR (stress), RMSSD (stress), SD1 (stress), SD2 (stress), LF (ms2) (stress); RAC group: HF (ms2) (stress), HF (nu) (stress)). Within the RAE group, the variables mostly improved, contrary to the RAC group where the change was mostly a deterioration (i.e. less parasympathetic activity and an increased sympathetic drive in the RAC group at study completion).
Discussion
This study demonstrates that exercise intervention has a positive effect on autonomic function of RA patients, as measured by short-term heart rate variability. Comparing the exercise group to the control group at baseline, the control group showed better heart rate variability. However, at study completion, this change was in favour of the exercise group who then showed better heart rate variability. Our results are confirmed by that of Jurca et al. in 2004 who, after 8 weeks of moderate exercise training in females, showed improved vagal modulation of heart rate on 10-min resting ECGs [36].
Many previous studies done on diseased populations to evaluate the effect of short-term exercise intervention on short-term HRV modification assessed only supine variables [37–43]. Sandercock et al. in 2007 observed significant increases in the supine RR interval, SDRR, LF(ln) and HF(ln) in a group of patients, who had coronary artery bypass grafting and angioplasty following myocardial infarction (MI), after 8 weeks of cardiac rehabilitation [37]. Malfatto in 1996 also showed significant increases for RR interval, SDRR, RMSSD, pNN50 and HF but a decline in LF in patients who followed a training programme after MI [38]. On the other hand, Oya et al. in 1999 could not show any significant difference in HRV in MI patients after a 3-month training programme [39]. Figueroa et al. in 2007 observed a significant increase in LF and HF in a 16-week study in obese women with and without type 2 diabetes mellitus [43]. All the above mentioned studies (except that of Oya et al.) thus showed increased vagal tone (HF, RMSSD, pNN50), but the LF variable seems to be difficult to interpret with changes in different directions in the different studies.
In the present study, only the RR interval increased significantly in the supine position, while the other variables did not show significant changes in favour of the exercise group. It is not clear why increased vagal tone was not picked up in the supine position in our analyses; however, Iwasaki et al. in 2003 did a study where HF and RR interval increased early in the training of young previously sedentary subjects, but at study completion after 1 year, HF regressed towards initial values whereas RR interval uniformly increased. They suggested that initial increases may be due to higher vagal modulation, while other factors such as heart geometry may play a role in further adaptation [44].
It was mainly the variables obtained in the standing position that were affected favourably in our exercise group in comparison to the control group. Zoppini et al. in 2007 found similar results in a study on patients with type 2 diabetes mellitus where they showed significant changes in standing, but not supine variables after a 6-month exercise programme [45]. In the current study, the changes reflected a greater effect on increased vagal rather than on decreased sympathetic influence. Buch et al. in 2002 pointed out that patients may have a better survival advantage with enhanced vagal tone. Reasons offered were that greater vagal influence will decrease heart rate and myocardial contractility (i.e. due to less workload and oxygen consumption), hinder sympathetic influence on the sinus node and reduce the risk of ventricular dysrhythmias [46]. Therefore, improving the vagal tone in RA patients may be an instrument to decrease their cardiovascular morbidity and mortality.
De Meersman commented that “Ultimately, all of these cardiovascular diseases are associated with a common denominator, namely a perturbed autonomic balance. It is tempting, therefore, to hypothesise that preservation of cardiac autonomic function by lifestyle or interventions should be associated with a marked reduction in the risk of cardiovascular disease and death” [47]. Exercise intervention appears to have an advantageous effect on cardiac autonomic function in RA patients as measured by short-term heart rate variability. Especially, vagal modulation seems to improve, and this can lead to improved cardiac health in a patient group already suffering from impaired lifestyle due to joint pain and other complications following a diagnosis of RA.
Limitations of the study
Unfortunately, this study suffers from the implication of low statistical power, due to the unavoidable small sample size; therefore, effect sizes were reported to quantify the effectiveness of the intervention. Similar studies, e.g. on diabetic [43, 45] and cardiac patients [38, 40, 41], had equal or even less participants.
Heart rate variability was the only tool used to assess the function of the autonomic nervous system. Including tests such as analysis of blood pressure variability may add information and support results obtained by HRV analysis.
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Acknowledgments
We thank Brenda Weder and Ria Smuts for their technical assistance, our patients who, through their dedication, made it possible to complete the study and the staff of the Medical Library at the University of Pretoria for their assistance in scrutinising the literature and finding relevant articles.
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Janse van Rensburg, D.C., Ker, J.A., Grant, C.C. et al. Effect of exercise on cardiac autonomic function in females with rheumatoid arthritis. Clin Rheumatol 31, 1155–1162 (2012). https://doi.org/10.1007/s10067-012-1985-5
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DOI: https://doi.org/10.1007/s10067-012-1985-5