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| NL80641.091.22 | Other Identifier | CCMO |
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The Myosuit is a light-weighted lower extremity soft exosuit which provide assistance during walking. In this study the Myosuit will be tested in the home and community setting in patients with incomplete spinal cord injury.
Rationale: People with incomplete spinal cord injury (iSCI) show often impairments and limitations related to gait, which negatively affects daily life gait performance (i.e. ambulation in home and community setting) and quality of life. As a consequence of limited gait capacity, these people are likely to develop a sedentary lifestyle resulting in a vicious circle, causing a further decline in gait capacity and daily life gait performance. One of the potential options to improve gait is the use of assistive technology, such as exoskeletons or exosuits. People with iSCI have voluntary control of the leg muscles may benefit more from light-weighted exosuits which provide assistance during walking. Recently, a lower extremity soft exosuit, the Myosuit (MyoSwiss AG), has been introduced. In a small sample study, participants showed an increased gait speed when using the Myosuit compared to their baseline gait speed. Moreover, only a small number of training sessions was required to use the Myosuit. Hence, the Myosuit seems to have a high potential to increase gait capacity and daily life gait performance in people with residual gait capacity.
Objective: The study consists of two parts, randomized controlled trial (RCT) and experimental design. In the RCT, the primary objective is to test the efficacy of the Myosuit for increasing daily life gait performance in the home and community setting in people with iSCI. Secondary, the efficacy of the Myosuit program on gait capacity and its cost-utility will be investigated. Finally, the usability of the Myosuit for use in home and community setting will be evaluated. In the experimental design, we will investigate differences in gait capacity with and without wearing the Myosuit in people with iSCI, by conducting clinical tests. Secondary, differences in gait capacity measured on an instrumented treadmill with and without wearing the Myosuit will be examined.
Study design: RCT and within subject experiment.
Study population: Thirty-four people with chronic iSCI (>6 months after injury) and reduced gait capacity due to reduced knee and/or hip strength (MRC<5) will be recruited for this study. People with iSCI will be included when having an injury level of C or D on the American Spinal Injury Association Impairment Scale. In addition, participants need to have sufficient hand function to don and doff the Myosuit or they need a caregiver who is available to help the participant to use the Myosuit at home. Patients who have another (neurological) disease which can influence motor performance and/or patients who have small wounds, which can be worsened by wearing the Myosuit will be excluded. For the second objective of the experimental design, only people who are be able to walk consecutively for two minutes on a treadmill without any assistive device and without using the handrails will be included.
Intervention: RCT: The intervention group will perform training sessions with the Myosuit at the Sint Maartenskliniek. Thereafter, they will receive the Myosuit at their disposal at home and a recommendation for physical activity for six weeks. The control group will receive a program of conventional physiotherapy at the Sint Maartenskliniek. Thereafter, they receive a recommendation for physical activity for at home for six weeks.
Experimental design: Participants perform clinical tests and measurements on an instrumented treadmill with and without the Myosuit.
Measurements intervention and control group:
Additional measurements for the control group who receive the Myosuit intervention after the conventional program:
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Myosuit intervention | Experimental | Participants perform Myosuit training sessions. After the clinical Myosuit training program, participants receive the Myosuit at their disposal at home for six weeks and a recommendation for physical activity at home. |
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| Control | Active Comparator | Participants perform conventional training sessions. After the clinical training program, participants receive a recommendation for physical activity at home. After the conventional training program the control group will receive the Myosuit intervention. |
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| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Control | Other | Participants perform five one-hour conventional training sessions at the Sint Maartenskliniek in which they perform functional exercises. After the conventional training program, the control group will receive a recommendation for physical activity at home for six weeks. |
| Measure | Description | Time Frame |
|---|---|---|
| Change from baseline daily life gait performance to the home period as assessed by walking time per day (minutes) | Measured by the Activ8 for 7 days. At baseline (T0) 7 days are averaged to calculate mean walking time per day. During the 6-week home period all days are averaged to calculate mean walking time per day. (RCT) | Baseline: Week 1 (T0), During the 6-week home period: average over week 6, 8, 11 (T2, T3, T4) |
| Change in preferred walking speed between with and without Myosuit as assessed by the 10 meter walk test (m/s) | Measure for gait capacity. (experimental design) | After the clinical training program: Week 5 (Myosuit intervention, T1) or week 16 (Control, T6) |
| Measure | Description | Time Frame |
|---|---|---|
| Daily life gait performance as assessed by gait quality | Measured by inertial measurement units. (RCT) | Baseline: Week 1 (T0), During the 6-week home period: week 6 and 11 (T2, T4) and week 17 and 22 (T7, T9) |
| Change from baseline preferred walking speed at T5 as assessed by the 10 meter walk test (m/s) |
| Measure | Description | Time Frame |
|---|---|---|
| Sex (man/woman) | Descriptive outcome measure. | Baseline: Week 1 (T0) |
| Age (years) | Descriptive outcome measure. | Baseline: Week 1 (T0) |
Inclusion Criteria:
Exclusion Criteria:
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| Name | Affiliation | Role |
|---|---|---|
| Bart van den Bemt | Sint Maartenskliniek | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Sint Maartenskliniek | Ubbergen | Netherlands |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 25254140 | Background | Balasubramanian CK, Clark DJ, Fox EJ. Walking adaptability after a stroke and its assessment in clinical settings. Stroke Res Treat. 2014;2014:591013. doi: 10.1155/2014/591013. Epub 2014 Aug 28. | |
| 26364282 | Background | DiPiro ND, Holthaus KD, Morgan PJ, Embry AE, Perry LA, Bowden MG, Gregory CM. Lower Extremity Strength Is Correlated with Walking Function After Incomplete SCI. Top Spinal Cord Inj Rehabil. 2015 Spring;21(2):133-9. doi: 10.1310/sci2102-133. Epub 2015 Apr 12. |
| Label | URL |
|---|---|
| Link to the research project website | View source |
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| Myosuit | Device | Participants perform five one-hour Myosuit training sessions at the Sint Maartenskliniek in which they perform functional exercises and learn to don, doff and use the device for standing, walking, climbing the stairs and sit-to-stand transitions. After the clinical Myosuit training program, participants receive the Myosuit at their disposal at home and a recommendation for physical activity at home for six weeks. |
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Measure for gait capacity. (RCT) |
| Baseline: Week 1 (T0), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Maximum walking speed as assessed by the 10 meter walk test (m/s) | Measure for gait capacity. (RCT) | Baseline: Week 1 (T0), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Walking speed as assessed by the 6 minutes walk test (m/s) | Measure for gait capacity. (RCT) | Baseline: Week 1 (T0), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Functional ambulation as assessed by the spinal cord injury functional ambulation profile (SCI-FAP) | Measure for gait capacity. The SCI-FAP is composed of 7 tasks: carpet, up & go, obstacles, stairs, carry, step, and door. The highest total score is 2100. The SCI-FAP is a timed measure, a low score indicates better function. (RCT) | Baseline: Week 1 (T0), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Usability as assessed by the System Usability Scale (SUS) | The range is between 0 and 100, with a higher score indicating better usability. (RCT) | After the clinical training program: Week 5 and 16 (T1, T6), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Usability as assessed by the Dutch version of the quebec user evaluation of satisfaction with assistive technology (D-QUEST) | The range is between 1 and 5, with a higher score indicating greater satisfaction. (RCT) | After the clinical training program: Week 5 and 16 (T1, T6), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Quality-adjusted-life years gain assessed by EuroQol five-dimension scale questionnaire (EQ5D-5L) | Measure for quality of life to investigate cost-utility. The EQ5D-5L consists of five levels with a maximum score of 1 which indicates the best health state. In addition there is a visual analogue scale with a maximum score of 100 to indicate general health status. (RCT) | Baseline: Week 1 (T0), After the 6-week home period: Week 12 and 23 (T5, T10) |
| General and Disease Specific Self-efficacy Scale | Questionnaire contains confidence in general, confidence in managing with your physical condition and confidence in walking. The range is between 0 and 160, with a higher score indicating higher confidence. (RCT) | Baseline: Week 1 (T0), After the 6-week home period: Week 12 and 23 (T5, T10) |
| Maximum walking speed as assessed by the 10 meter walk test (m/s) | Measure for gait capacity. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Walking speed as assessed by the 6 minutes walk test (m/s) | Measure for gait capacity. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Preferred walking speed as assessed by walking on the GRAIL (m/s) | Measure for gait capacity. Preferred walking speed is measured during 2 minutes self-paced walking on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Step length as assessed by walking on the GRAIL | Measure for gait capacity. Step length is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Step time as assessed by walking on the GRAIL | Measure for gait capacity. Step time is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Ankle range of motion as assessed by walking on the GRAIL | Measure for gait capacity. Ankle range of motion is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Maximum ankle plantar flexion as assessed by walking on the GRAIL | Measure for gait capacity. Maximum ankle plantar flexion is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Knee range of motion as assessed by walking on the GRAIL | Measure for gait capacity. Knee range of motion is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Maximum knee extension as assessed by walking on the GRAIL | Measure for gait capacity. Maximum knee extension is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Hip range of motion as assessed by walking on the GRAIL | Measure for gait capacity. Hip range of motion is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Maximum hip extension as assessed by walking on the GRAIL | Measure for gait capacity. Maximum hip extension is measured during 2 minutes walking on fixed speed on the GRAIL. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Variable error of the precision stepping task as assessed by walking on the GRAIL | Measure for gait adaptability. (experimental design) | After the clinical training program: Week 5 and 16 (T1, T6) |
| Height (cm) | Descriptive outcome measure. | Baseline: Week 1 (T0) |
| Weight (kg) | Descriptive outcome measure. | Baseline: Week 1 (T0) |
| Body Mass Index | Descriptive outcome measure. Calculated with weight and height. | Baseline: Week 1 (T0) |
| Time since spinal cord injury (years) | Descriptive outcome measure. | Baseline: Week 1 (T0) |
| Spinal cord injury classification defined by the American Spinal Injury Association (ASIA) impairment scale (C or D) | Descriptive outcome measure. The scale has five classification levels (A-E), ranging from complete loss of neural function (A) in the affected area to completely normal (E). | Baseline: Week 1 (T0) |
| Level of spinal cord injury | Descriptive outcome measure. There are four sections that impact the level of spinal cord injury: cervical, thoracic, lumbar and sacral. | Baseline: Week 1 (T0) |
| Muscle strength as assessed by Medical Research Council (MRC) scale | Descriptive outcome measure. Range from 0 - 5 with higher scores indicating more strength | Baseline: Week 1 (T0) |
| Spasticity as assessed by Modified Ashworth Scale (MAS) | Descriptive outcome measure. Range from 0 - 4 with higher scores indicating more spasticity | Baseline: Week 1 (T0) |
| Sensory function as assessed by the American Spinal Cord Injury Association (ASIA) Impairment Scale | Descriptive outcome measure. Range from 0 - 2 with lower scores indicating more impaired sensory function | Baseline: Week 1 (T0) |
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| 42047584 | Derived | Visch L, Groen BE, Geurts ACH, Van Nes IJW, Keijsers NLW. Effect of an exosuit on gait capacity in individuals with incomplete spinal cord injury: A cross-sectional study. J Spinal Cord Med. 2026 Apr 28:1-8. doi: 10.1080/10790268.2026.2660441. Online ahead of print. |
| 41826999 | Derived | Visch L, Groen BE, Geurts ACH, van Nes IJW, Keijsers NLW. Effect of an exosuit on daily life gait performance in individuals with incomplete spinal cord injury: a randomized controlled trial. J Neuroeng Rehabil. 2026 Mar 13;23(1):134. doi: 10.1186/s12984-026-01941-8. |
| 39242508 | Derived | Visch L, Groen BE, Geurts ACH, van Nes IJW, Keijsers NLW. Effect of a soft exosuit on daily life gait performance in people with incomplete spinal cord injury: study protocol for a randomized controlled trial. Trials. 2024 Sep 6;25(1):592. doi: 10.1186/s13063-024-08412-2. |