View clinical trials related to Incomplete Spinal Cord Injury.
Filter by:Background: In Switzerland, about 6000 individuals live with the consequences of a spinal cord injury (Brinkhof et al, 2016). One of the major goals after an incomplete spinal cord injury (iSCI) is to regain walking function. To this end, different approaches are used in rehabilitation such as treadmill-based, robotic-assisted (exoskeleton or end-effector) and conventional gait training. According to current literature, the superiority of one of these approaches remains unclear (Mehrholz, Harvey, Thomas, and Elsner, 2017); In the research on gait rehabilitation after iSCI, recent randomized clinical trials (RCTs) found no statistical differences between conventional gait training and robotic-assisted gait training. Nevertheless, according to the comparison of effect sizes obtained from these training, these trials suggested that the conventional training approach leads to larger improvements in gait capacity when compared to robotic-assisted therapy (Field-Fote and Roach, 2011; Nooijen, Ter Hoeve, and Field-Fote, 2009). Therefore, these trials highly recommended further research considering these aspects. However, in clinical settings, the implementation of such systematic and intense training sessions remains challenging. The present study aims to test the hypothesis that conventional training might have larger effect sizes on gait capacity and to evaluate the feasibility of such systematic training in a clinical setting of inpatient rehabilitation. Objectives: To contribute to the current knowledge on best clinical practice in gait rehabilitation within the iSCI population. More specifically, the study objectives are two-fold: A first objective is to compare the effects of conventional training, end-effector based therapy and the combination of these interventions on the gait ability of iSCI. A second objective is the evaluation of the feasibility of systematic gait training protocols in a clinical setting. Participants: Individuals with motor incomplete spinal cord injury (iSCI), presenting a traumatic or non-traumatic iSCI with an injury onset <6 months. Intervention: Participants will be trained in one of the three groups by trained physical therapists during 10 sessions, 3x/week with an average duration of 30 minutes. Outcomes: To attain the first objective the effects will be quantified by the following main outcomes: Walking capacity (independence), walking speed, and safety. Feasibility of the systematic intervention will be evaluated using the drop-outs of therapy interventions.
The purpose of this study is to further establish safety and efficacy of the BQ EMF treatment of chronic SCI subjects who demonstrate stability in The Graded and Redefined Assessment of Strength, Sensibility and Prehension (GRASSP) strength score following a one-month physical therapy run-in period.
This study will investigate the effects of transcutaneous direct current stimulation (tsDCS) on walking function in individuals with incomplete spinal cord injury. Following rehabilitation, individuals with ISCI often demonstrate improved walking function, but continue to have serious impairments that limit mobility, community participation and quality of life. Adjuvants to rehabilitation that increase spinal excitation during training may enhance its effectiveness. tsDCS is a non-invasive neuromodulation approach that uses a mild electrical current, applied over the skin of the low back, to alter the membrane potential of spinal neurons. tsDCS will be applied during locomotor training, a well-established rehabilitation strategy that promotes walking recovery. Locomotor training emphasizes repetitive and task-specific practice of coordinated walking, often with therapist assistance or cueing to promote high quality movement patterns. The study team will explore if tsDCS combined with locomotor training increases spinal excitation and thereby improves the effectiveness of walking rehabilitation.
In Taiwan, there are more than 23,000 individuals with spinal cord injuries (SCI, mean age: 27 years), with an increment of new 1,200 SCI individuals each year. Recovery of ambulatory function is among the most important therapeutic goals because 92% of the individuals with SCI have to use the wheelchair for the rest of their lives. The lower limb powered exoskeleton robot, FREE Walk, used for training in this research was developed by FREE Bionics Inc. The main purpose of this research is to test the safety and feasibility of FREE Walk exoskeleton robot. In addition, the research will further investigate the range of injury levels for the intended SCI users and the learning time needed for the users to independently operate the exoskeleton robot.
The objective of the study is to assess the efficacy of the Exo-H2 robotic exoskeleton for walking rehabilitation of people with incomplete spinal cord injury.
The purpose of the study is to investigate the effects of a novel therapeutic approach with transcutaneous spinal direct current stimulation (tsDCS) to promote functional recovery and spasticity in chronic spinal cord injury (SCI).
The purpose of this study is to develop an algorithmic-based evaluation and treatment approach for wearable robotic exoskeleton (WRE) gait training for patients with neurological conditions.
Background: - Cerebral palsy (CP) is the most common motor disorder in children. CP often causes crouch gait, an abnormal way of walking. Knee crouch has many causes, so no single device or approach works best for everybody. This study s adjustable brace provides many types of walking assistance. Researchers will evaluate brace options to find the best solution for each participant, and whether one solution works best for the group. Objective: - To evaluate a new brace to improve crouch gait in children with CP. Eligibility: - Children 5 17 years old with CP. - Healthy volunteers 5 17 years old. Design: - All participants will be screened with medical history and physical exam. - Healthy volunteers will have 1 visit. They will do motion analysis, EMG, and EEG described below. - Participants with CP will have 6 visits. - Visit 1: <TAB>1. Motion analysis: Balls will be taped to participants skin. This helps cameras follow their movement. <TAB>2. EMG: Metal discs will be taped to participants skin. They measure electrical muscle activity. <TAB>3. Participants knee movement will be tested. <TAB>4. Participants will walk 50 meters. <TAB>5. Participants legs will be cast to make custom braces. - Visit 2: - Participants will wear their new braces and have them adjusted. - Steps 1 3 will be repeated. - EEG: Small metal discs will be placed on the participants scalp. They record brain waves. - Participants will have electrical stimulation of their knees and practice extending them. - Participants will take several walks with the braces in different settings. - Visits 3 5: participants will repeat the walking and some other steps from visit 2. - Visit 6 will repeat visit 2.
The purpose of this study is: (1) to establish assessment techniques (in our laboratory) to identify the functional integrity of long spinal tracts associated with adaptive walking recovery post-spinal cord injury and (2) to preliminary investigate locomotor outcomes associated with an adaptive locomotor training approach post-spinal cord injury.
Spinal cord injury (SCI) is a disabling condition that impairs fundamental abilities, such as ambulation, respiration, and toileting. Compromised ambulation is a common, devastating impairment following SCI. Yet, despite the fundamental desire to walk, no conventional rehabilitation regimen reliably improves ambulation after SCI, and many SCI patients do not have reliable transportation access, decreasing community integration and access to needed services, including rehabilitation. Little is also known about the subtle neural events that may predict motor recovery in incomplete SCI patients. This study will test a novel, safe, easy to implement technique that has shown promise in improving gait in incomplete SCI patients. The investigators expect that this study will confirm the efficacy of this technique, by showing that it increases the speed and efficiency of walking. This outcome is expected to produce a therapy that improves outcomes and health, and reduces care costs, for community dwelling patients with incomplete SCI.