Stroke is the leading neurological disease in the world that causes long-term disability. The most common cause of disability after stroke is motor impairment resulting from brain damage which ultimately causes mobility and functional limitation. Worldwide, the incidence of stroke has been increased by 30% in the last decade. In Europe, more than one million cases have been reported each year and six million stroke survivors are known to be alive till now. The annual estimated cause of stroke treatment in Europe is twenty-seven billion Euros. By 2030, it is estimated that the cost of stroke treatment will be triple the current amount and can reach up to 184 billion dollars. Therefore, it is necessary to develop an economical rehabilitation program that prevents or reduces long-term disability after stroke.
Blood flow restriction combined with resistance training may be an economic and time-efficient alternative to High-Intensity Training to manage the risk factors of stroke and can also be useful in reducing stroke-related impairment effectively. During BFRT, the blood flow of the exercising muscle is restricted by placing the inflated tourniquets at the most proximal part of the legs or arms. By restricting the blood flow to the limbs, the desired muscle group will work in an ischemic environment and can trigger a significant increase in muscle mass, power, and strength by recruiting the fast-twitch muscle fibers. BFRT could be a promising type of exercise for high-risk groups of patients such as Cardiovascular disease, stroke, etc, and the hypertrophy responses induced by is comparable to that produced by high-intensity training. It was found that BFRT and high-intensity training produced similar effects on both systolic, diastolic blood pressure, and heart rate (HR) in young individuals and older adults. Previous evidence from neurological studies showed that resistance combined with blood flow restriction can improve muscle strength, balance, walking capacity, and cognitive function in Multiple Sclerosis and spinal cord injury patients. Recent study showed that BFR combined with resistance training has improved brain-derived neurotrophic factor (BDNF) and vascular endothelial growth factor (VEGF) and rate of perceived exertion in ischemic stroke patients. Kaatsu training society also reported a few cases in which BFRT has produced a positive effect on the recovery of stroke patients, but the evidence is insufficient to support this assertion.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
SINGLE
Enrollment
32
The blood flow restriction training group will perform 3 sets of Sandbag (SB) resistance exercises, targeting the large muscles of the legs, at 40% of 1-RM. The SB protocol consists of 3 sets of 4 SB exercises. Each set consists of 10 repetitions of 1-RM with a 1-min recovery interval between sets and 3-min between exercises. Blood flow to the active muscle during training will be restricted by a blood flow restriction band (tourniquet) placed at the proximal end of the lower limbs. When the subjects performed training with BFR, the proximal portions of their lower limbs will be compressed at the pressure of 120-160 mmHg by electronically controlled air pressure belts. The air pressure belt will be inflated before the exercise and will remain inflated during one-minute intervals between the sets and will be deflated during the three-minute interval between the exercise.
The high-intensity restriction training group will perform 3 sets of Sandbag (SB) resistance exercises, targeting the large muscles of the legs, at 80% of 1-RM. The SB protocol consist of 3 sets of 4 SB exercises. Each set consists of 10 repetitions of 1-RM with a 1-min rest interval between sets and 3-min between exercises.
Göztepe Prof. Dr. Süleyman Yalçın City Hospital
Istanbul, Turkey (Türkiye)
Change score of Sit to stand Test
Five time sit to stand test will be used to assess lower extremity muscle strength, balance and risk of fall in stroke patients. The test measure amount of time taken to complete five repetitions of sit to stand task. The test will be performed with standard height chair without an armrest and with straight back (43-45 cm high). He patients will be instructed to stand up and sit down as quickly as possible 5 times, keeping their arms folded across their chest. Timing began when the patient's back left the backrest and stopped once the back touched the backrest for the fifth time.
Time frame: Baseline, Post-intervention (Approximately 5 weeks), follow-up (up to 3 Months)
Change score of 10 Meter walk Test
The Comfortable 10-m Walk Test (10 MWT) will be used to determine the speed of comfortable walking. The test will be applied in a 14-m corridor. The patients will be instructed to walk comfortably and allowed to use walking aid. At the 2nd meter, the stopwatch will be started and stopped when the patient reached the 12th meter. Walking time and number of steps will be assessed to calculate gait speed (m/s), stride length (m), and cadence (steps/min). After three trials, the average of the three trials will be recorded as m/s.
Time frame: Baseline, Post-intervention (Approximately 5 weeks)
Change score of Timed up and Go Test (TUG)
The Timed Up \& Go test is a functional mobility test used to assess dynamic balance, transfer, and gait. The patient is instructed to stand up from a chair (46 cm high) with support for the arms, walk for a short distance (3 m), turn, go back and sit down as quickly as possible. The stopwatch will be used to measure the time to perform these tasks from start to end. The patients will be allowed to use their walking aids. After three trials, the average of the three trials will be recorded.
Time frame: Baseline, Post-intervention (Approximately 5 weeks)
Change score of 6 Minute walk Test
The walking distance will be measured by the 6 Minute walk Test (6MWT), the most commonly used for measuring the physical performance of individuals after stroke. The patients will be asked to walk as far as possible throughout the 30-meter course within 6 minutes by following the standardized instructions provided by the physiotherapist. Participants will be allowed by the physiotherapist to use aiding device if necessary. Physiotherapist will guard the participants during the walk test but will not offer any assistance or support to the participant.
Time frame: Baseline, Post-intervention (Approximately 5 weeks)
Change score of Barthel Index
The Barthel Index measures a person's performance in activities of daily living. The Barthel Index consists of 10 items of mobility and self care activities of daily living. This score will be measured on admission and at the end of intervention (at the end of 5th week). The minimum score is 0 and the maximum is 100. A higher score indicates a better outcome.
Time frame: Baseline, Post-intervention (Approximately 5 weeks)
Change score of Hospital Anxiety and Depression Scale (HADS)
The Hospital Anxiety and Depression Scale (HADS) is a fourteen-item scale scoring from 0 to 3 for each item. The first seven items relate to anxiety (HADS-A), and the remaining seven items relate to depression (HADS-D). The global scoring ranges from 0 to 42 with a cut-off point of 8/21 for anxiety and 8/21 for depression. The higher the score, the greater anxiety or depression symptoms. HADS will be performed at the beginning and after four weeks of treatment.
Time frame: Baseline, Post-intervention (Approximately 5 weeks)
Attendance
Attendance of training sessions measured via Hospital entry sheet.
Time frame: Number of sessions attended will be measured during the 5 weeks of intervention protocol.
Adverse Events
Any adverse event or near miss is required to be reported.
Time frame: Any adverse event reported during the 5 weeks of intervention protocol.
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