Background: Physical training of lower leg skeletal muscle has been shown to increase exercise tolerance in Chronic Obstructive Pulmonary Disease (COPD) patients. The objective of this study was to measure the effect of concurrent aerobic-resistance interval exercise on lower leg muscle function and local muscle tissue oxygenation in the vastus lateralis muscle (VLM) of COPD patients.
Methods: Peripheral muscle oxygenation in the VLM was measured using Near Infrared Spectrometry (NIRS) during the six- minute walk test (6MWT) in 15 COPD patients: Experimental (EXP., n = 9) and control (CTL., n = 6). Both groups trained for 3 weeks (1 hour/day and 5 days/week). Training sessions consisted of upper body strength exercises for 20 minutes. Next, the CTL. Group performed 30 minutes of aerobic exercise (motorized treadmill or stationary bike), while the EXP. group completed 30 minutes of aerobic-resistance (concurrent training) interval exercise (non-motorized treadmill). Pre and post-intervention NIRS measurements included oxyhemoglobin (O2Hb), deoxyhemoglobin (HHb), hemoglobin difference (HbDif), total hemoglobin (tHb), and tissue saturation index (TSI). Systemic arterial oxygen saturation (SPO2), heart rate and the rating of perceived exertion with the modified Borg scale were also measured pre and post-intervention during the 6MWT.
Results: All patients were able to complete three weeks of training. A significant increase in the 6MWT (51.4%, p < 0.05) distance was noted in the EXP. group and in the VLM HbDiff (69%, p < 0.05). No significant differences were observed in the other muscle oxygenation variables.
Conclusion: Concurrent aerobic-resistance interval exercise increases the total distance covered at the 6MWT (increased functional capacity) and muscle oxygen extraction.
COPD, Muscle oxygenation, Interval exercise, NIRS, Muscle oxygen kinetic, Concurrent aerobic-resistance exercise
VLM: Vastus Lateralis Muscle; NIRS: Near Infrared Spectrometry; 6MWT: Six-Minute Walk Test; O2Hb: Oxyhemoglobin; Hhb: Deoxyhemoglobin; Hbdif : Hemoglobin Difference; Thb: Total Hemoglobin; TSI: Tissue Saturation Index; %SpO2: Systemic Oxygen Saturation
Chronic Obstructive Pulmonary Disease (COPD) is a debilitating condition affecting the lives of millions people world-wide. COPD affects not only the respiratory system, but also peripheral skeletal muscles through type I and type IIA muscle fiber atrophy that leads to impairment in both muscle oxidative capacity and muscle strength [1]. Physical training has been shown to improve muscle function and structure in COPD patients [2]. Physical training improves muscle fiber oxidative capacity, increases the cross-sectional area of muscle fibers type I and IIa, and reduces submaximal exercise lactate concentration [3].
It is well established that pulmonary rehabilitation programs are important in the treatment of patients with COPD because they increase exercise tolerance, reduce symptoms of dyspnea and improve health-related quality of life [4]. There are substantial variations in exercise protocols used in pulmonary rehabilitation programs [5]. One modality that appears promising to offer sustainable high intensity exercise for COPD patients while allowing for short periods of recovery preventing high lactate accumulation is interval exercise [6]. During the training session, patients exercise at high intensity followed by a period of lower intensity or rest. This alternating cycle could be repeated several times. This training modality has been shown to induce less dynamic hyperinflation, and better exercise tolerance than continuous exercise in COPD patients [7,8]. Thus, investigators have shown that both aerobic and resistance type training help to alleviate respiratory and peripheral muscle discomfort [9]. However, to the best of our knowledge, no studies have reported the use of concurrent aerobic-resistance as a training modality.
Non-motorized belt driven treadmills involve propelling the treadmill belt while either walking or running [10]. The potential benefit of non-motorized treadmills is that they produce a simultaneous demand of lower leg force production (resistance) and an overall increased aerobic demand. Although recent studies have shown that healthy participants exercising on non-motorized treadmills improved both muscle force and aerobic capacity, non-motorized treadmills have not been used with COPD patients [11]. The overall objective of this study was to use a non-motorized treadmill as part of a pulmonary rehabilitation program with moderate to severe COPD patients. The specific objective was to measure the effect of concurrent aerobic-resistance exercise on local muscle tissue oxygenation in the VLM and consequently, on functional walking capacity of COPD patients. The hypothesis was that the combined effect of aerobic-resistance exercise would improve VLM oxygenation.
Twenty-four patients with COPD, referred for inpatient pulmonary rehabilitation at Mount Sinai Hospital, Montreal, were invited to participate in the study. All patients underwent spirometry at the pulmonary function laboratory. Inclusion criteria were men and women aged 50-80, who were hospitalized and part of the rehab program at Mt. Sinai Hospital with a conformed moderate to severe COPD diagnosis, were stable and ambulatory, and had a < 70% FEV1VC < 70% and a FEV1 greater than 30% but less than 80% of the predicted value according to the Global Initiative for Obstructive Lung Disease (GOLD) criteria [12].
Exclusion criteria were severe or unstable cardiovascular disease, cognitive impairment, musculoskeletal limitation and neuromuscular disorders. A total of 24 patients were recruited. Nine patients did not complete the training and were excluded from the study. The final sample for analysis was composed of 15 patients.
Upon arrival at Mount Sinai Hospital, each patient received an explanation about the purpose and procedures involved in the study and were able to ask questions before giving their informed written consent. The study received IRB approval (approval number 2013_A_130064) by the ethics committee of the Mount Sinai Hospital and the University of Quebec in Montreal.
Patients followed a 3-week multidisciplinary pulmonary rehabilitation program, including exercise training sessions. Before and after the program, all patients retained for the study underwent an anthropometric evaluation (height, weight, leg circumference and skin fold thickness) and a 6MWT that included an assessment of peripheral muscle oxygenation kinetics using NIRS. Measurement details are provided below. The study was designed as a randomized controlled clinical trial. Patients were randomly divided into two groups: The control (CTL.) group had endurance training alone (n = 6) and the experimental (EXP.) group received the concurrent training modality (aerobic-resistance, n = 9).
The 6MWT adhered to the guidelines outlined by the American Thoracic Society [13]. All participants completed the 6MWT. In all patients, before, during and after the 6MWT, dyspnea severity was measured with a modified Borg Scale, while systemic oxygen saturation (%SpO2) and heart ratewere monitored using a finger probe pulse oximeter (MD300 Wrist Pulse Oximeter, HH, DE) and a heart rate monitor (RS800, Polar, Fi). Peripheral tissue muscle oxygenation (%StO2) was measured before, during and after the 6MWT, with a NIRS device (Portamon, Artinis, Medical System, NL).
Vastus lateralis %StO2 was continuously measured with the NIRS device during rest, the 6MWT, and recovery periods. The theory of NIRS has been described in detail elsewhere [14]. The Beer-Lambert law was used to calculate micromolar changes in tissue oxygenation [(O2Hb) and (HHb)]. The changes in concentration of O2Hb, HHb, tHb, HbDiff, and TSI were measured during the entire 6MWT.
Arterial %SpO2 was continuously measured during rest, the 6MWT, and recovery periods with a pulse oximeter (MD300 Wrist Pulse Oximeter, HH, DE) using a finger probe attached to either the index or major finger of the participant.
Exercise training in the pulmonary rehabilitation program was either the standard training (CTL. group) typically used at Mount Sinai Hospital (details provided below) or the experimental (EXP.). The exercise training consisted of 5 sessions per week (Monday to Friday) for 3 consecutive weeks for a total number of 15 sessions. Each session lasted 60 minutes and consisted of a 5 minute warm-up followed by 20 minutes of strength exercises for upper body (hand weights or elastic bands), 30 minutes of specific training (aerobic or concurrent aerobic-resistance), and then 5 minutes of cool-down.
For the CTL. group, the exercise training included treadmill walking (initial speed at 1.5 km/h increased every week by 0.5 km/h, and 0° elevation) or cycling on stationary ergocycles. Pedaling cadence was gradually adjusted according to the patient's tolerance. For the EXP. group, the patients exercised with concurrent interval workouts on a non-motorized treadmill (HiTrainer, Bromont, QC), where the intervals were 30 secs of walking at an intensity of 85-90% of maximal predicted heart rate followed by a 30 sec rest period (standing still on the treadmill) before beginning the next interval. The number of intervals ranged from 3-5 in the 1st week and for weeks, 2 and 3 progressed to 8 intervals.
All values were reported as mean ± S.D. The Shapiro-Wilks test was performed to verify the normal distribution of the data. Repeated measures ANOVA was used to test for within and between group effects across time. If significant differences were detected, a Bonferroni adjusted t-test was used to detect the differences between groups. For all analyses, the level of significance was set at p < 0.05. The statistical analysis of the collected data was performed with Statistical Package for the Social Sciences, version 20 (SPSS Inc., Chicago, IL, USA).
Both groups were closely matched in gender, age, height, weight, and body mass index (see Table 1). The pulmonary function test revealed moderate to severe air flow limitation, on the basis of global initiative (GOLD) for COPD [12]. After 3 weeks of pulmonary rehabilitation, the 6MWT was significantly increased in both the CTL. and EXP. groups and revealed a significant difference between groups. A greater significant increase in total distance was observed in the EXP. Group [! 6MWT; EXP.=130.9 m (p = 0.00); CTL. = 48.2 m (p = 0.03)]. The perception of effort, however, did not show significant changes; although there was a slight decrease post-intervention in the EXP. group compared to the CTL. group (intra and intergroup, respectively, ! Borg; EXP. = -0.56, p = 0.44; CTL. = 0.33, p = 0.70; and EXP. vs. CTL. = -1.61, p = 0.14).
The dynamic behavior of O2 during the 6MWT is shown in Figure 1. This shows that after three weeks of pulmonary rehabilitation, the HbDiff for the CTL. group of 14.07 ± 9.35 μM was significantly different than the EXP. group of 13.72 ± 7.29 μM (p = 0.004). The O2Hb, however, was not significantly different (p = 0.149) between the CTL. group (25.12 ± 20.03 μM) and the EXP. group (16.48 ± 16.64 μM), as was the HHb (CTL. 38.06 ± 19.22 vs. EXP. 30.20 ± 11.27 μM, p = 0.078). Table 2 shows a summary of muscle oxygenation during the 6MWT. The CTL. group showed no significant change in local muscle tissue oxygenation variables, but there was a significant change in the HbDiff. (p = 0.004) for the EXP. group. In both groups there were no significant changes in O2Hb, HHb, tHb, TSI, but a consistent tendency to decrease for the 6MWT with an apparent evident increase in HbDiff.
Following the intervention, the EXP. group showed a significant increase (p = 0.023) for HR, while SpO2 significantly decreased (p = 0.022) in Figure 2.
It can be observed that the EXP. group had a greater significant (p = 0.003) arterial desaturation post-intervention where %SpO2 for the EXP. group was 87.2 ± 3.4 when compared to 91.4 ± 2.3% for the CTL. group.
The purpose of this study was to evaluate peripheral muscle oxygenation in COPD patients during the 6MWT following a concurrent aerobic resistance interval exercise program. A unique feature of the present study was that oxygen kinetics were continuously measured with NIRS during the 6MWT, before and after the pulmonary rehabilitation program. NIRS has been found to be effective when examining conditions of increased O2 demand in COPD patients [15]. In contrast, several studies in COPD have documented oxygen kinetics during exercise or at rest, but not pre and post exercise programs [16-19].
In the current study, it was observed that a 3-week concurrent aerobic-resistance exercise training intervention increased 6MWT distance in COPD patients. The EXP. group showed an average increase of ~130 meters or ~48%, while the CTL. group increased only by 48 meters or ~17%, after the program. An important outcome was the increase of 131 meters for the EXP. group, which is much greater than the clinically relevant distance of 30.5 meters [20]. There is no doubt that the EXP. group in the current study improved their functional walking capacity. A possible advantage of the procedure is that the progressive resistance on a self-propelled treadmill (HiTrainer) accelerates leg muscle gains in strength (force) and power.
Puente-Maestu, et al. reported that high intensity training improves muscle oxygen capacity and oxygenation recovery kinetics due to the increased oxidative enzymes in COPD patients [17]. Thus, it is possible that the EXP. patients in the present study improved muscle oxygenation capacity of the lower legs based on the high intensity training they received. The observed improvements were obtained with an exercise program that took place five times a week for three consecutive weeks. This is in contrast to the American Thoracic Society that recommends a minimum of 3 times per week over an 8-week period to reach physiological adaptations and benefits in peripheral skeletal muscles [13]. Importantly, the proposed interval exercise modality in the current study may be an alternative for sites where time constraint is an issue. Nonetheless, further research is necessary to ascertain the efficiency of this type of training in COPD patients.
Oxygen saturation is a surveillance parameter that characterizes exercise performance on the 6MWT and helps determine the degree of disability linked to a disease during physical effort [21]. We found that the EXP. group had a greater desaturation compared to the CTL. group post 6MWT. Some studies have shown that during the 6MWT there was an oxygen desaturation in patients with COPD, while others have shown an improvement in this parameter [22,23]. It is difficult to understand why in this study the EXP. group had a higher desaturation; however, this might represent a better anaerobic effort, indicating an improvement in lower leg muscle endurance and represents the effect of the resistance training component in the EXP. group.
In the current study, the EXP. group showed an increase in the HHb. The EXP. group intra-group analysis nearly reached statistical significance (p = 0.07) with an effect size of 0.14 (small effect), but not for the inter-group (p = 0.38). A possible explanation for the lack of an effect is that only one site was measured and that more than one point on the quadriceps may have revealed an effect. Nonetheless, a study by Koga, et al. showed results similar to ours where the HHb measured on 10 different points of the quadriceps during exercise had intra-group muscle deoxygenation variation, but no inter-group differences [24].
We also assessed O2Hb, tHb, and TSI that exhibited a consistent tendency to decrease in both EXP. and CTL. groups during the post-intervention 6MWT, but these changes were not statistically significant. Similar results have been reported using different types of exercise trainings, such as endurance training, tapering, or strength training [18,25,26].
Regarding HbDiff., there was no significant difference between groups, but it is important to note that the EXP. group had a significant increase compared to the CTL. group (p = 0.004), suggesting that the concurrent aerobic-resistance training modality could have a better effect on oxygen extraction in the muscle (ES = 0.82). The HbDiff. is a parameter that describes the difference between oxy-Hb and deoxy-Hb concentration (ΔO2Hb-ΔHHb). As the exercise effort increased, the difference was greater, indicating a higher O2 extraction in the muscle. Interesting to note, as shown in Figure 3, is the distance traveled by the EXP. group in the 6MWT was significantly correlated to the ΔHbDiff, possibly indicating an improved muscle oxygen extraction following a concurrent aerobic-resistance interval exercise program.
There were some limitations to our study. One of the limitations is the small sample size, which included fifteen participants distributed over two groups: 1) Experimental (n = 9); and 2) Control (n = 6). Another limitation is the length of intervention. A 3-week intervention remains short to observe significant changes in participants. Further studies with a larger sample size and longer intervention would be beneficial in the future.
In conclusion, the current study shows that a concurrent aerobic-resistance interval exercise program is well tolerated by COPD patients and produces changes in vastus lateralis skeletal muscle oxygenation as well as exercise capacity. A significant association was found between HbDiff and exercise capacity (6MWT). We suggest that the increase in HbDiff appears to be the result of improved local muscle oxygen consumption resulting from a concurrent aerobic- resistance interval exercise program. Another important observation is the improved efficiency in obtaining significant gains in the 6MWT in only three weeks (half the time) in contrast to other approaches that typically span over 6 to 8 weeks.