Journal List > Ann Rehabil Med > v.37(5) > 1149709

Lee, Kang, Im, Kim, Kim, Yoon, and Han: The Effects of Assisted Ergometer Training With a Functional Electrical Stimulation on Exercise Capacity and Functional Ability in Subacute Stroke Patients

Abstract

Objective

To determine if assistive ergometer training can improve the functional ability and aerobic capacity of subacute stroke patients and if functional electrical stimulation (FES) of the paretic leg during ergometer cycling has additional effects.

Methods

Sixteen subacute stroke patents were randomly assigned to the FES group (n=8) or the control group (n=8). All patients underwent assistive ergometer training for 30 minutes (five times per week for 4 weeks). The electrical stimulation group received FES of the paretic lower limb muscles during assistive ergometer training. The six-minute walk test (6MWT), Berg Balance Scale (BBS), and the Korean version of Modified Barthel Index (K-MBI) were evaluated at the beginning and end of treatment. Peak oxygen consumption (Vo2peak), metabolic equivalent (MET), resting and maximal heart rate, resting and maximal blood pressure, maximal rate pressure product, submaximal rate pressure product, submaximal rate of perceived exertion, exercise duration, respiratory exchange ratio, and estimated anaerobic threshold (AT) were determined with the exercise tolerance test before and after treatment.

Results

At 4 weeks after treatment, the FES assistive ergometer training group showed significant improvements in 6MWT (p=0.01), BBS (p=0.01), K-MBI (p=0.01), Vo2peak (p=0.02), MET (p=0.02), and estimated AT (p=0.02). The control group showed improvements in only BBS (p=0.01) and K-MBI (p=0.02). However, there was no significant difference in exercise capacity and functional ability between the two groups.

Conclusion

This study demonstrated that ergometer training for 4 weeks improved the functional ability of subacute stroke patients. In addition, aerobic capacity was improved after assisted ergometer training with a FES only.

INTRODUCTION

Stroke is a leading cause of disability that impairs ambulatory activity and daily living functions [1,2]. Post-stroke functional deficits, such as postural imbalance, muscle weakness, or spasticity may promote physical inactivity and a deconditioning state, which can lead to reduced cardiovascular fitness [2-6]. The low aerobic capacity eventually results in low ambulatory function, social participation, and quality of life [4]. Therefore, it is essential to encourage aerobic exercise in post-stroke patients, but very few can participate in intensive gait training immediately after their stroke event [7], because of muscle weakness, fatigue, or general deconditioning [8].
Cycling exercise is a safe, functional treatment that is accessible by these patients for the relearning of motor skills required for locomotion [9,10]. Pedaling is an aerobic exercise and a repetitive, functional activity, which requires reciprocal contraction of agonist and antagonist muscles of the lower limbs in a repeating pattern similar to that required for walking [11]. The motorized cycling ergometer is an especially useful treatment for severe disabled stroke patients, as automatic pedaling facilitates phasic, coordinated muscle activity with continuous use of the hemiside extremity [12]. This exercise improves cardiovascular fitness, such as peak oxygen consumption, workload, and endurance [13]. Also, because cycling is practiced in the sitting position, it is safe, easy to perform, and can be widely applied, regardless of the severity of motor impairment [14]. Therefore, cycling has been proposed to have potential patient benefit when used as an adjunct to therapy after stroke [13,15-19].
In addition, functional electrical stimulation (FES) exercise can increase strength and prevent atrophy of paralyzed muscles by using stimulation patterns that induce repetitive contractions in selected muscle groups [20]. In a previous study [21], we reported improvement of cardiovascular function after the application of electrical stimulation in healthy adults. FES could be an alternative strategy to increase the muscle work performed in severely disabled patients [22,23].
Motorized cycle ergometers combined with FES became available in 1984 and are used primarily as a therapy for people with spinal cord injury (SCI) [24]. Several studies have reported using the FES-evoked leg cycle ergometer as a rehabilitation therapy for lower limb paralysis following SCI [25-31]. The therapy was found to increase the number of activated muscle fibers, muscle mass, strength, functional performance, and circulation.
However, no previous study has investigated the effectiveness of assisted ergometer training with a FES on hemiparetic legs in subacute stroke patients, including evaluation of the patient's functional ability and aerobic capacity. Therefore, the aim of this study was to evaluate assisted ergometer training with a FES in subacute stroke patients for improving their functional ability and aerobic capacity. We also aimed to determine if concomitant FES provides benefits in addition to the ergometer alone.

MATERIALS AND METHODS

Subjects

This study was conducted in 16 stroke patients who had been treated in the rehabilitation department of our hospital. All subjects provided written informed consent before the selection procedure. The study protocol was reviewed and approved by the Institutional Review Board. The participants 1) suffered a primary ischemic or hemorrhagic stroke as revealed by computed tomography or magnetic resonance imaging scans, 2) had an onset of stroke within 6 months, and 3) presented with mild to moderate paresis of the lower extremities (manual muscle function test>grade 2). Patients who had 1) severe deficits in communication, memory, or understanding, 2) any additional neurological or orthopedic disease causing motor deficits, such as fractures, joint degenerative changes, or clinical instability of the hip or knee joint, 3) psychiatric problems or unstable cardiorespiratory disease, or 4) inability to tolerate, or contraindications to electrical stimulation-e.g., epilepsy, cancer, skin ulcer, pacemaker, pregnancy-were excluded.

Methods

Eligible patients were randomly assigned to two groups. Eight patients (mean age, 63.25±15.00 years) were assigned to the electrical stimulation group and another eight patients (mean age, 63.25±14.12 years) to the control group. All patients underwent assistive ergometer training five times per week for 4 weeks to maintain a pedaling cadence of 30 rpm for 30 minutes. The electrical stimulation group received FES on the paretic quadriceps, hamstring, gluteus maximus, and tibialis anterior muscles using two EMG-FES 2000 (Cyber Medic, Seoul, Korea) during assistive ergometer training. One was applied to paretic quadriceps and tibialis anterior, and the other was applied to hamstring and gluteus maximus. The stimulation protocol consisted of a symmetrical biphasic square pulse at 60 Hz, a constant pulse width of 300 µs, and a duty cycle of 1.0 second on and 1.0 second off alternatively. We endeavored to synchronize FES stimulation timing to the cycling movement according to each muscle activation pattern, although we could not use an automatic synchronizing FES ergometer. The maximum power output of the stimulator was 100 mA. The stimulation intensity was increased within the range of motor threshold to the maximal comfortably tolerated intensity. Both groups underwent the symptom-limited low velocity graded treadmill test using a modified Harbor protocol [32,33]. The exercise test was performed using a CH2000 (Cambridge Heart Inc., Tewksbury, MA, USA) integrated 12-lead ECG for stress testing, Quark CPET (Cosmed, Rome, Italy) breath by breath gas exchange data analysis, a T-2100 treadmill (GE Healthcare, Fairfield, CT, USA), and a blood pressure and heart rate monitor. The initial round of treadmill walking without an incline was used to assess gait safety and to select the target walking velocity for subsequent maximal-effort graded treadmill testing. The zero-incline treadmill test was started at 0.5 mph and slowly advanced by 0.1 mph increments according to the patient's subjective tolerance and observer-rated gait stability. Patients capable of performing ≥3 consecutive minutes of treadmill walking at ≥0.5 mph were allowed 15 minutes of seated rest, after which they underwent constant-velocity, progressively graded treadmill exercise testing. For the initial 2 minutes, patients walked on the treadmill without an incline, followed by 2 minutes at 4% incline, with a 2% increase per 2 minutes thereafter. The exercise test was terminated on patient request or in the presence of gait instability or cardiovascular decompensation sign. Handrail support was minimally allowed, and a gait belt support and close supervision were provided as safety measures.
Peak oxygen consumption (Vo2peak), metabolic equivalent (MET), resting and maximal heart rate (RHR, MHR), resting and maximal blood pressure (RBP, MBP), maximal rate pressure product (MRPP), exercise duration, respiratory exchange ratio (RER), estimated anaerobic threshold (AT), submaximal rate pressure product (SRPP), and submaximal rate of perceived exertion (SRPE)-Borg Scale, from 6 to 20-were determined before and after the exercise test. In addition, functional exercise capacity measured by the six-minute walk test (6MWT) in a 50 m in-hospital corridor, Berg Balance Scale (BBS), and the Korean version of the Modified Barthel Index (K-MBI) were evaluated at the beginning and the end of treatment.

Statistical analysis

Statistical analysis was performed using SPSS ver. 18.0 (SPSS Inc., Chicago, IL, USA) for Windows. The chi-square and Mann-Whitney tests were used to compare the baseline characteristics of the two groups. Wilcoxon rank sum test was also used to compare the exercise capacity and functional ability within each group at baseline and 4 weeks after testing. Repeated measures analysis of variance was used for the inter-group comparison of all parameters of exercise capacity and functional ability between the two groups according to the time period until 4 weeks. The null hypothesis of no difference was rejected if p-values were less than 0.05.

RESULTS

General characteristics of the participants

The baseline characteristics of the participants are summarized in Tables 1 and 2. Eight participants were assigned to each study group and each included four men. The mean age at enrolment was 63.25±15.00 years in the electrical stimulation group and 63.25±14.12 years in the control group. Demographic characteristics including gender, age, time since cardiovascular accident, height, weight, and baseline cardiopulmonary functions of the two groups were not significantly different.

Changes of parameters before and after treatment within each group

At 4 weeks after treatment, the FES assistive ergometer training group showed a significant improvement in both exercise capacity and functional ability (Table 3). The 6MWT increased from 193.63±102.97 to 266.25±113.38 (p=0.01), BBS increased from 43.88±7.14 to 47.13±6.98 (p=0.01), and K-MBI increased from 76.38±10.64 to 84.00±8.59 (p=0.01). In addition, Vo2peak increased from 16.00±2.79 to 17.83±3.09 (p=0.02), MET increased from 4.55±0.82 to 17.83±3.09 (p=0.02), and the estimated AT increased from 11.35±1.36 to 13.72±2.49 (p=0.02). The control group showed no significant changes in exercise capacity, whereas statistically significant improvements occurred in the BBS (p=0.01) and the K-MBI (p=0.02).

Changes of parameters before and after treatment between the two groups

After 4 weeks, no significant intergroup differences were found in the exercise capacity and functional ability (Table 4).

DISCUSSION

The results of this study provide evidence that FES assistive ergometer training in the hemiparetic muscles of subacute stroke patients improved their aerobic capacities as well as functional abilities.
Several investigations [5,8,28,30,34-38] have demonstrated similar beneficial effects of FES assistive ergometer training in patients with SCI, heart failure, and stroke. Szecsi et al. [5] assessed whether FES-assisted cycling on the paretic leg in subjects with subacute stroke hemiparesis could improve quantifiable biomechanical parameters such as smoothness, power, and symmetry of cycling. They showed that FES-assisted cycling was associated with strengthening the affected leg, reestablishing the side balance of forces, and improving pedaling control, particularly in patients with hemiparesis in the early phase of convalescence after stroke. Although they did not evaluate functional abilities and aerobic capacities, they noted that objective goals, such as functional outcomes can be achieved with the clinical application of this therapy. Lo et al. [37] also reported that cycling exercise with FES on the hemiparetic leg improved postural control and spasticity of the extremities in subacute stroke patients. They suggested that the application of FES to the affected leg during cycling training has additional benefits, especially for patients with high muscle tone. These findings emphasized the beneficial effects of FES on hemiparetic legs specifically in subacute stroke patients.
Additionally, FES-induced cycling on the both legs (hemiside and intact-side) has demonstrated significant improvement in lower extremity strength and functional ability in subacute stroke patients. Ferrante et al. [35] and Ambrosini et al. [36] evaluated the effectiveness of FES-induced cycling on both legs in subacute stroke patients. Their studies revealed that FES cycling training significantly improved lower extremity strength, motor control, motor recovery, and walking abilities, such as Motricity Index, Trunk Control Test, Upright Motor Control Test, and maximum isometric voluntary contraction compared to cycling only. These results confirmed that FES cycling training applied in the subacute stroke phase may play an important role in facilitating and accelerating motor recovery. The investigators concluded that the improvements they observed resulted from increased sensorial input provided to the brain by FES.
The improvements observed through the 6MWT, BBS, and K-MBI in our study are in line with the results cited above. However, in our study, FES applied only to the muscles on the hemiparetic side was effective in improving functional abilities. This suggests that FES-induced cycling may facilitate coordinated muscle activity, relearning of how to execute movements of paretic muscles voluntarily, and induction of continuous use of the hemiside extremity.
Janssen et al. [8] reported that their FES assistive cycling training program on paretic lower extremities in chronic stroke patients improved cycling performance, functional performance, and aerobic exercise, such as power of output (POmax), Vo2peak, 6MWT, and BBS performance. Except for muscle strength, it had no additional effect over assistive ergometer only. Our study reached a similar conclusion in subacute stroke patients in that it showed improvements in aerobic capacities, such as Vo2peak, MET, and estimated AT in the FES assistive ergometer training group within 4 weeks. These results could be explained by repetitive voluntary contraction of leg muscles as an adaptation to FES, which also promotes circulatory adaptations, hypertrophy, and histochemical changes in muscles, all of which are helpful in relearning how to execute movements. The changes in response to therapy increase metabolic capacity, prevent muscle atrophy, and induce functional recovery. Also, FES helps patients to focus on treatment during cycling, thus improving the efficiency of the exercise [36]. Moreover, improvement in estimated AT provides meaningful evidence that FES could be used to improve exercise endurance. Also, our study found that FES plus assistive motorized cycling was beneficial for aerobic capacity in subacute as well as chronic stroke patients.
There are several study limitations. The most serious limitation is the small number of subjects evaluated, making it insufficient to monitor the effects of FES training. Second, a therapeutic intervention period of 4 weeks might be too short to demonstrate the added effects of FES training, compared to the control. Third, we could not evaluate the changes in muscle strength, mass, and muscle spasticity, although they might have influenced the functional ability. Fourth, we could not perfectly synchronize FES stimulation timing with the angular movement of the ergometer motor. Finally, we did not use the cycling graded exercise stress test, which could be applied in the sitting position. Thus, symptom-limited exercise tests had to be performed by walking or running, and the participants might have already reached functional recovery at baseline exercise test. Our results support previous additional, large-scale, long-term follow-up studies, including FES synchronization and other relevant factors, evaluating functional ability and aerobic capacity after FES-assisted ergometer training.
In conclusion, this study demonstrated that ergometer training for 4 weeks improved the functional ability of subacute stroke patients. In addition, aerobic capacity was improved after assisted ergometer training with a FES only. Therefore, we suggest assisted ergometer training with a FES as a useful alternative therapy for increasing the aerobic capacity of subacute stroke patients.

ACKNOWLEDGMENTS

This work was supported by a research grant from the Medical Research Fund (institute of medical science academic research fund) of Jeju National University in 2011.

Notes

No potential conflict of interest relevant to this article was reported.

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Table 1
Baseline characteristics of the two groups
arm-37-619-i001

Values are presented as mean±standard deviation or number.

FES, functional electrical stimulation; CVA, cerebrovascular accident.

p<0.05.

Table 2
Exercise capacity and functional ability at baseline
arm-37-619-i002

Values are presented as mean±standard deviation.

FES, functional electrical stimulation; 6MWT, 6 minute walk test; BBS, Berg Balance Scale; K-MBI, Korean-Modified Barthel Index; MI, Motricity Index; Vo2peak, peak oxygen consumption; MET, metabolic equivalent; RHR, resting heart rate; MHR, maximal heart rate; RsBP, resting systolic blood pressure; RdBP, resting diastolic blood pressure; MsBP, maximal systolic blood pressure; MdBP, maximal diastolic blood pressure; MRPP, maximal rate pressure product; AT, estimated anaerobic threshold; SRPP, submaximal rate pressure product; SRPE, submaximal rate of perceived exertion; RER, respiratory exchange ratio; Ex Dur, exercise duration.

p<0.05.

Table 3
Study parameters measured before and after treatment within each study group
arm-37-619-i003

Values are presented as mean±standard deviation.

FES, functional electrical stimulation; 6MWT, 6 minute walk test; BBS, Berg Balance Scale; K-MBI, Korean-Modified Barthel Index; MI, Motricity Index; Vo2peak, peak oxygen consumption; MET, metabolic equivalent; RHR, resting heart rate; MHR, maximal heart rate; RsBP, resting systolic blood pressure; RdBP, resting diastolic blood pressure; MsBP, maximal systolic blood pressure; MdBP, maximal diastolic blood pressure; MRPP, maximal rate pressure product; AT, estimated anaerobic threshold; SRPP, submaximal rate pressure product; SRPE, submaximal rate of perceived exertion; RER, respiratory exchange ratio; Ex Dur, exercise duration.

a)p<0.05.

Table 4
Inter-group comparisons of parameters according to time by repeated-measures analysis of variance
arm-37-619-i004

Values are presented as mean±standard deviation.

FES, functional electrical stimulation; 6MWT, 6 minute walk test; BBS, Berg Balance Scale; K-MBI, Korean-Modified Barthel Index; Vo2peak, peak oxygen consumption; MET, metabolic equivalent; RHR, resting heart rate; MHR, maximal heart rate; RsBP, resting systolic blood pressure; RdBP, resting diastolic blood pressure; MsBP, maximal systolic blood pressure; MdBP, maximal diastolic blood pressure; MRPP, maximal rate pressure product; AT, estimated anaerobic threshold; SRPP, submaximal rate pressure product; SRPE, submaximal rate of perceived exertion; RER, respiratory exchange ratio; Ex Dur, exercise duration.

p<0.05.

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