View clinical trials related to Spinal Cord Injuries.
Filter by:The purpose of this study is to determine if electric stimulation to the leg, called transcutaneous tibial nerve stimulation (TTNS), can improve bladder outcomes in acute spinal cord injury.
The purpose of this study is to evaluate a new control (i.e., the vision-guided shared control) for a wheelchair-mounted assistive robotic manipulator among powered wheelchair users. This study will consist of a questionnaire about general demographics, health information, and previous experience with assistive technology. Several tests will also be administered to test upper extremity function and ability as well as to test spatial orientation and visualization ability. Participants till then undergo a training phase with the assistive robotic manipulator mounted on a table to assess if they will be eligible for participation in the study. Eligible participants will move on to a second training phase where they will be asked to learn and practice slightly more complex tasks while using the vision-guided shared controller. After this training the assistive robotic manipulator will be mounted to the participants wheelchair and they will be asked to complete a number of everyday tasks from a task list. At the conclusion of the study, researchers will conduct a brief semi-structured interview with each participant and obtain more insight on how participants perceive the ease-of-use and usefulness of the vision-guided shared control.
A well-managed bowel program is an essential part of daily life for many people with a SCI. Nevertheless, constipation is frequently reported (42-95%). Constipation embraces a spectrum of harms including both physical & psychological distress. Initial exploratory studies suggest abdominal FES may be useful for decreasing overall bowel management time, decreasing colonic transit time and reducing discomfort. The current study will seek to reproduce previous findings in a 12 week study, using overall bowel management time as a benchmark for establishing proof of principle. The study will include 36 people with a spinal cord injury aged 18 and over with an above T12 injury, a complete or incomplete lesion in a medically stable condition, one year or more after injury. Participants will be randomised into two groups. One group will receive abdominal electrical stimulation and the other group low dose abdominal electrical stimulation. Participants will be asked to keep a bowel diary and complete questionnaires examining quality of life and bowel management.
This research study is being done to test a new device developed for spinal cord injury (SCI) patients. The purpose of this study is to collect data on how the nervous system signals travel within the spinal cord of SCI patients. Once the investigators understand that, they hope to develop a device that may help rehabilitation of SCI patients so that they can regain function in their lower limbs. This study involves some imaging studies (e.g. X-rays etc.), surgical implantation of a portion of the electrical stimulation device, various assessments of body function (e.g. balance, movement, gait), and physical rehabilitation procedures. What is new and experimental is the stimulation/sensing device (Intelligent Spine Interface - Commercial, ISI-C) that will be implanted.
Impairments of walking function after spinal cord lesion due to, for example, inflammation, ischemia or trauma are exceptionally diverse. Depending on the size, location and completeness of the spinal cord lesion, gait dysfunction is often multifactorial, arising from weakness of leg muscles, sensory impairments or spasticity. Locomotor function in humans with spinal cord damage can be improved through training. However, there are no evidence-based guidelines for the treatment of gait dysfunctions and no excepted standards of gait training in this large and heterogeneous group of patients. A lack of evidence-based guidance and standardisation prevents the development of optimal training programs for patients with spinal cord damage and rather broad and subjective clinical judgement is applied to determine patient care. Objective and quantitative techniques like three-dimensional (3D) full-body movement analysis capable of identifying the most relevant determinants of gait dysfunction at the single-patient-level are not yet implemented as diagnostic tool to guide physical therapy in this heterogeneous group of patients. The objective of this project is to further advance current clinical locomotor training strategies by applying a deficit-oriented gait training approach based on subject-specific, objective gait profiles gleaned from 3D gait analysis in chronic, mildly to moderately gait-impaired individuals with spinal cord damage due to inflammation (in multiple sclerosis, MS) or with traumatic or ischemic spinal cord injury (SCI; motor incomplete). Within a parallel-group clinical trial, gait impaired subjects will be characterized by detailed kinematic 3D gait analysis and either trained according to their individual deficits or treated with non-specific, standard walking therapy for six weeks. It is hypothesized that individually adapted, deficit-oriented training is superior in improving walking function than purely task-related, ambulatory training in patients with spinal cord damage. This project may pave the way to more efficient training approaches in subjects with spinal cord damage by transferring and implementing modern gait assessment techniques into clinical neurorehabilitation and to move towards individual, patient-tailored locomotor training programs.
Texas Biomedical Device Center at UT Dallas has developed an innovative strategy to enhance recovery of motor and sensory function after neurological injury termed targeted plasticity therapy (TPT). This technique uses brief pulses of vagus nerve stimulation to engage pro-plasticity neuromodulatory circuits during rehabilitation exercises. Recovery is associated with neural plasticity in spared motor networks in the brain and spinal cord. Moreover, an early feasibility study and an independent, double-blind, placebo-controlled study in chronic stroke participants indicate that VNS is safe in participants with upper limb deficits, and yields a clinically-significant three-fold increase in neural connections during rehabilitation exercises. Given the track record of safety and potential for VNS to enhance recovery of upper limb motor function in spinal cord injured individuals, the purpose of this double blind randomized placebo controlled optional open-label extension study is to assess the safety of using a new device to deliver vagus nerve stimulation to reduce symptom severity in participants with SCI. Additionally, the study will assess the prospective benefit of the system and garner an initial estimate of efficacy for a subsequent trial. Participants may undergo additional sessions of training with VNS.
The study team is currently recruiting volunteers who are interested in participating in a brain-spinal cord-muscle response training study that aims to better understand the changes that take place in the nervous system as a result of this type of training. After spinal cord injury, brain-to-muscle connections are often interrupted. Because these connections are important in movement control, when they are not working well, movements may be disturbed. Researchers have found that people can learn to strengthen these connections through training. Strengthening these connections may be able to improve movement control and recovery after injuries. Research participants will be asked to stand, sit, and walk during the study sessions. Electrodes are placed on the skin over leg muscles for monitoring muscle activity. For examining brain-to-muscle connections, the study team will use transcranial magnetic stimulation. The stimulation is applied over the head and will indirectly stimulate brain cells with little or no discomfort. Participation in this study requires approximately three sessions per week for four months, followed by two to three sessions over another three months. Each session lasts approximately 1 hour.
Currently, there is no system in place to allow manual wheelchair users to know their quantities of movement activities and the intensity of effort to be provided during these propulsion movements. Based on recent work by Routhier et al. in 2017, and in light of the scientific literature related to wheelchair propulsion, it would seem appropriate to validate the use of inertial units as tools to quantify and categorize the intensity of manual wheelchair propulsion.
Tetraplegia after a cervical spinal cord injury (C-SCI) radically alters an individual's ability to perform normal activities of daily life due to paralysis in all extremities, resulting in lifelong dependence.[1] Traditional tendon transfer surgery has proven successful in restoring grip functions which greatly improves autonomy, but with a restricted passive opening of the hand. The number of transferrable muscles in the arm is however limited, why nerve transfer surgery is a new attractive option to further improve hand function by enabling active opening of the hand. Significant advantages of distal nerve transfers include less extensive surgical dissection, greatly reduced hospital stay, rehabilitation and restrictions, and thereby less health care use and costs. In an effort to further improve hand function and independence in patients with tetraplegia, hand surgeons at Centre for Advanced Reconstruction of Extremities (C.A.R.E.), Sahlgrenska University Hospital (SUH)/Mölndal have developed a strategy in which a nerve transfer procedure aiming to restore active opening of the hand is done prior to reconstruction of grip functions. To date, no study has compared the efficacy of this combined nerve and tendon transfer (CNaTT) procedure to traditional grip reconstruction by means of tendon transfer alone, thus constituting a major gap in the literature. The purpose of this study is therefore to fill that knowledge gap by comparing the clinical outcomes of a cohort of patients who undergo the CNaTT procedure to restore hand function, to those treated by means of tendon transfer alone.
Depression is more common after a spinal cord injury (SCI) than in the general population. Unfortunately, it is unknown how depression is typically treated in individuals with SCI or if commonly used treatment methods are effective. This study will investigate the safety and impact of a novel method for treating depression called repetitive transcranial magnetic stimulation (rTMS). rTMS is a type of non-invasive brain stimulation. Fourteen individuals with a cervical or thoracic level SCI and depression will complete an approved treatment plan using rTMS. Participants will be treated using rTMS five days a week for four weeks. After four weeks of treatment, the study team will review the safety of rTMS and assess changes in depressive symptoms. If the results are positive, larger studies can be designed to develop better treatment options for individuals with SCI and depression.