Combined Application of Electrical Stimulated Antagonist Contraction During Walking (Walking Study)
Keywords
Abstract
Description
Osteoarthritis of the knee (KOA) is the most common cause of disability not only in the United States but also in Japan. KOA is associated with pain, quadriceps weakness, swelling, instability, decline of range of motion, physical function, and quality of life (QOL) (1). In particular, quadriceps weakness may contribute to incident symptomatic and progressive disease (2, 3), cause functional limitations and disability (4) and increase the risk of mortality (5). Both aerobic exercise and resistance exercise are recommended for the treatment of people with knee osteoarthritis (KOA) (6). However, exercise at a moderate or severe intensity is often a problem for people with knee pain or a history of knee injury.
Neuromuscular electrical stimulation (NMES) is widely used as a method to increase muscle strength and improve physical function even at a low-moderate exercise intensity (7). However, NMES effect may prove to be insufficient because the exercise intensity is determined by the electrical stimulation endurance level of the user (7). On the other hand, transcutaneous electrical stimulation, so-called transcutaneous electrical nerve stimulation (TENS), is effective for pain relief (8). Knee pain independently reduced quadriceps strength and activation (9). TENS restores inhibited quadriceps motor function (central and muscle activation) through pain relief (10). Moreover the combined application of electrical stimulation (ES) and volitional contractions (VC) is said to be more effective than ES or VC alone (11). Therefore, a hybrid training system (HTS) that resists the motion of a volitionally contracting agonist muscle using the force generated by its electrically stimulated antagonist (NMES) was developed as a way to combine the application of electrical stimulation and voluntary contraction (12). HTS is a method that eliminates the disadvantages of both volitional exercise and NMES (13). It has been reported that HTS is a new training technique that can increase both muscular strength and muscle mass (12, 13, 14, 15). Recently, HTS is showing promise as a countermeasure for the musculoskeletal disuse of astronauts because the HTS technique can generate exercise resistance within the body even if there is no gravity (1). In addition, HTS can be utilized during many different types of exercise (e.g. knee extension exercise, squat and hip flexion, walking exercise, and cycling exercise) (17, 18). It seems to be more effective for improvement of muscle strength and physical function to combine HTS with easy exercise (e.g. knee extension, walking, and squats) for KOA patients.
The main purpose of exercise therapy for KOA is not only muscular strength improvement (the quadriceps femoris muscle in particular) and but also pain relief (19, 20). Muscular strength improvement protects joints and relieves nociceptive stimulation. However, exercise sometimes increases pain. In addition to the pathological change in articular structures, changes in central pain processing or central sensitization appear to be involved in KOA pain (19). Murphy et al. reported that 36% of a heterogenous sample of patients with hip and KOA demonstrated evidence of central sensitization (22). This finding has been incompletely characterized, but it is necessary to consider central sensitization in the treatment of patients with KOA. From a theoretical perspective, exercise has the potential to treat the process of central sensitization: e.g. exercise activates brain-orchestrated endogenous analgesia (23). An initial bout of high intensity eccentric exercise induces central sensitization, but a repeated round of exercise facilitates inherent protective spinal mechanisms (repeated bout effect) (24). Moreover, ipsilateral resistance exercise may possibly prevent the central sensitization (25). Therefore, a time-contingent approach which implies that the patient does not cease exercise bouts once local pain severity increases is recommended (22). A few reports about the dysfunctional endogenous analgesia for patients with musculoskeletal pain response to aerobic exercise were shown, but neither type of aerobic exercise was able to activate endogenous analgesia (24). At present, there is no report of an exercise method that is effective in central sensitization pain patients. Brain-derived neurotrophic factor (BDNF) belongs to the neurotrophic family of growth factors. The loss of BDNF usually leads to neurodegeneration in these motor centers and eventually results in several severe motor diseases, such as amyotrophic lateral sclerosis, spinocerebellar ataxias, Parkinson's disease, Huntington's disease, as well as vestibular syndrome. These neurotrophic factors (e.g., decreasing brain-derived neurotrophic factor) are promising new avenues for diminishing hyperexcitability of the CNS in central sensitization pain patients (2). Da Graca-Tarrago et al. showed that a 30-minute electrical intramuscular stimulation in osteoarthritis decreased pain, increased the local pain pressure threshold (PPT), and decreased BDNF (27). Gajewska-Wozniak et al. reported that low-threshold electrical stimulation of peripheral nerves to stimulate Ia afferent fibers (proprioceptive signaling) might affect the expression of BDNF in rats (28). HTS is an exercise technique that uses electrically eccentric muscle contraction. Yamaguchi et al. showed that the soleus H-reflex increased after one HTS adversely in conventional resistance exercise (29). This seems to indicate that HTS serves to activate Ia fibers. HTS may affect central sensitization and relieve pain in KOA patients.
Dates
Last Verified: | 05/31/2018 |
First Submitted: | 03/31/2016 |
Estimated Enrollment Submitted: | 03/31/2016 |
First Posted: | 04/05/2016 |
Last Update Submitted: | 06/12/2018 |
Last Update Posted: | 06/14/2018 |
Date of first submitted results: | 03/27/2018 |
Date of first submitted QC results: | 06/12/2018 |
Date of first posted results: | 06/14/2018 |
Actual Study Start Date: | 01/31/2016 |
Estimated Primary Completion Date: | 01/19/2017 |
Estimated Study Completion Date: | 01/19/2017 |
Condition or disease
Intervention/treatment
Device: Hybrid Training System (HTS)
Device: Transcutaneous Electrical Nerve Stimulation (TENS)
Phase
Arm Groups
Arm | Intervention/treatment |
---|---|
Experimental: Hybrid Training System (HTS) HTS stimulation while walking at a comfortable pace for 30 minutes. | Device: Hybrid Training System (HTS) Electrodes (15 cm x 6 cm) will be placed over the quadriceps and electrodes (11 cm x 6 cm) (Sekisui Plastics Co., Tokyo, Japan) will be placed over the hamstrings. Electrical stimulation parameters will be based on a standard Russian waveform in which a 5,000 Hz carrier frequency is modulated at 40 Hz (2.4 ms on, 22.6 ms off) to deliver a rectangular voltage biphasic pulse. Acceleration sensors as a joint motion sensor (EWTS9PD, Home Appliances Development Center Corporate Engineering Division, Appliances Company Panasonic Corporation 2-3-1-2 Noji-higashi,Kusatsu City, Shiga, Japan) is placed on the front of each leg 88mm above the patellar edge. It analyzes the algorithm of each exercise pattern, and stimulates the antagonist of the motion of each bilateral knee joint during exercise. Electrical stimulation intensity will be set to ~50-60% of 1RM based on the subject's tolerance. The subject's tolerance gradually increases, and electrical stimulation intensity is reset every 2 weeks. |
Active Comparator: Transcutaneous Electrical Nerve Stimulation (TENS) Sensory TENS while walking at a comfortable pace for 30 minutes. | Device: Transcutaneous Electrical Nerve Stimulation (TENS) The electrical stimulation intensity will be set under the muscle contraction threshold (but at a level at which the subject can perceive as sensory TENS). Electrical stimulation parameters (i.e. waveform and pulse duration) will be the same of HTS, while the amplitude will be lower. The subject will be stimulated using the same device as for HTS. |
Eligibility Criteria
Ages Eligible for Study | 39 Years To 39 Years |
Sexes Eligible for Study | Female |
Accepts Healthy Volunteers | Yes |
Criteria | Inclusion Criteria: 1. Female 2. Age 40-70 years 3. Knee symptoms (pain, aching, or stiffness) on most of the last 30 days (categorically defined) 4. Body Mass Index (BMI) 30-45kg/m2 Exclusion Criteria: 1. Resistance training at any time in the last 3 months prior to the study 2. Bilateral knee replacement 3. Lower limb amputation 4. Lower limb surgery in the last 6 months that affects walking ability or ability to exercise 5. Back or hip problems that affect walking ability or ability to exercise 6. Unable to walk without a cane or walker 7. Inflammatory joint or muscle disease such as rheumatoid or psoriatic arthritis or polymyalgia rheumatica 8. Multiple sclerosis or other neurodegenerative disorder 9. Known neuropathy 10. Currently being treated with insulin for diabetes 11. Currently being treated for cancer or having untreated cancer 12. Terminal illness (cannot be cured or adequately treated and there is a reasonable expectation of death in the near future) 13. Peripheral Vascular Disease 14. History of myocardial infarction or stroke in the last year 15. Chest pain during exercise or at rest 16. Use of supplemental oxygen 17. Inability to follow protocol (e.g. lack of ability to attend visits or understand instructions) 18. Staff concern for participant health (such as history of dizziness/faintness or current restrictions on activity) 19. Unable to attend more than 2 days within any 1 week or unable to attend 4 or more sessions during the study 20. Implanted cardiac pacemaker, spinal cord stimulator, baclofen or morphine pump or other implanted electrical device. 21. Dermatitis or skin sensitivity to tape used in the study. 22. Pregnancy |
Outcome
Primary Outcome Measures
1. Change in Knee Extensor Strength Assessed by Isokinetic Dynamometer. [Baseline and 12-week follow-up]
Secondary Outcome Measures
1. Change in Knee Flexor Strength Assessed by Isokinetic Dynamometer [Baseline and 12-week follow-up]
2. Change in Knee Pain Assessed by a Visual Analog Scale (VAS) [Baseline and 12-week follow-up]
3. Change in Knee Pain Assessed by Knee Injury and Osteoarthritis Outcome Score (KOOS) [Baseline and 12-week follow-up]
4. Change in Quality of Life (QOL) Assessed by Knee Injury and Osteoarthritis Outcome Score (KOOS) [Baseline and 12-week follow-up]
5. Change in 20-meter Walk Time. [Baseline and 12-week follow-up]
6. Change in 5-chair Stand Time. [Baseline and 12-week follow-up]
7. Change in Stair Climb Time. [Baseline and 12-week follow-up]