Active clinical trials for "Spinal Cord Injuries"

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.

The aim of this study is to investigate two different modalities of functional electrical stimulation (FES) leg exercise in patients with spinal cord injury (SCI). The primary outcomes being compared are 1. FES-induced leg aerobic fitness, and 2. FES-induced leg strength. There will be two FES-leg training groups, and sub-acute patients with SCI will be randomised between the groups - high-short [HI-SHORT] and low-long [LO-LONG]. Both groups (n=10 per group) will exercise on the Hasomed RehaStim™ exercise ergometer for 6-8 weeks, three-four times per week (24 therapy sessions). [HI-SHORT] will perform 10 x 2-min of high-intensity interval training with a recovery of 1-2 min between exercise bouts. [LO-LONG] will perform 20+ min of continuous exercise at a low-moderate exercise intensity. Exercise intensity for [HI-SHORT] and [LO-LONG] will be titrated by neuromuscular stimulation characteristics. The primary outcomes will be assessed before training commences and after 6-8 weeks of training has been completed.

Umbilical cord blood mononuclear stem cells (UCBMSCs) transplant followed by the intensive locomotor training for up to 5±1 hours a day, 5±1 days a week, and for 3-6 months for treatment in patients with chronic, stable and complete spinal cord injury.

Bowel dysfunction is consistently rated as one of the most common complications affecting daily life for individuals with spinal cord injury. The overall objective of this study is to investigate whether the use of specific spinal cord epidural stimulation will affect bowel function. This study will also examine how alterations in bowel function influence quality of life outcomes. The results of this study may aid in the development of treatments to help individuals with spinal cord injuries that have impaired bowel function.

The investigators are conducting a research study to try to improve rehabilitation interventions for individuals with spinal cord injury (SCI). In this study, the aim is to determine if temporarily numbing non-paralyzed arm muscles with an over-the-counter numbing cream while exercising paralyzed muscles, can improve the strength, function, and sensation of paralyzed muscles after a spinal cord injury.

A spinal cord injury (SCI) disrupts the communication within the nervous system, leading to limitations in sensorimotor activities such as walking. Regular use of functional electrical stimulation (FES) can result in recovery of voluntary muscle control and muscle strength. Locomotor training with FES may be a promising method to improve gait function. The primary objective of this pilot study is to assess the feasibility and safety of an FES-assisted gait training intervention. Secondary objectives are to assess the effects of an FES-assisted gait training intervention on gait function.

The overarching goal of this research study is to evaluate a sensor-enabled, just-in-time adaptive intervention (JITAI) strategy to increase and sustain physical activity levels among individuals with spinal cord injury (SCI) in their communities. A primary objective of this study is to evaluate the integration of a JITAI with a web-based physical activity intervention program. We hypothesize that the integration of web-based physical activity intervention program with JITAI will result in significantly higher physical activity levels compared to the standard web-based physical activity intervention program alone. A secondary objective of this study is to extend existing algorithms that use commercial wearable technology to robustly detect physical activity behaviors to facilitate the delivery of tailored just-in-time actionable feedback and physical activity recommendations for individuals with SCI.

The goal of this pilot study is to examine the effect of repetitive acute intermittent hypoxia on motor learning in persons with chronic, incomplete spinal cord injury.

Patients with traumatic spinal cord injury (tSCI) often suffer from spinal cord swelling inside the thecal sac, which contains the spinal cord and surrounding fluid, leading to increased pressure on the spinal cord tissue and decreased spinal cord blood flow at the site of injury. The combination of increased pressure and decreased blood flow causes vascular hypo-perfusion of the spinal cord and exacerbates the severity of injury. This is also referred to as secondary injury. Thus, knowledge of spinal cord hypo-perfusion would allow the treating physician to optimize the hemodynamic condition of patient with acute spinal cord injury and potentially improve functional outcome. We plan to use contrast-enhanced ultrasound (CEUS) to determine decrease of blood flow in the spinal cord at the site of injury, during the routine surgery that these patients require to decompress and stabilize their injured spine. This may help us to determine the efficacy of certain treatments in improving blood flow and patients suffering from tSCI.

Currently, there are a variety of approaches utilized in attempts to improve upper extremity function, including: traditional therapy, neuroprostheses, botulinum toxin injections, or surgical interventions. In addition, regenerative and restorative therapies, such as: epidural stimulation, functional electrical stimulation, and stem cell therapies, show promise in animal models, but are not ready for clinical translation. Subsequently, there is a clear need to develop new strategies that can stimulate spinal plasticity and strengthen existing synaptic connections in order to maximize the benefits of training paradigms. This study proposes the examine the effects of Acute Intermittent Hypoxia (AIH) in combination with upper extremity training, over the course of a month, to evaluate changes in upper extremity function, dexterity, and ability to complete activities of daily living. The use of acute intermittent hypoxia (AIH) has been demonstrated, through human and animal studies, to be an effective way of increasing spinal motor excitability and strengthening residual synaptic connectivity. AIH utilizes short duration (<2 min) exposures to reduced oxygen levels (~10% inspired oxygen), with alternating exposures to air with normal oxygen levels (~21% inspired oxygen). Previous publications demonstrate that AIH is a safe and effective intervention to modify motor function in individual with chronic incomplete spinal cord injuries. The use of AIH has been shown to influence the activation in musculature, within 60-120 minutes of administration. In addition, when coupling AIH with overground gait training, an increase in functional endurance, as evaluated through the 6 minute walk test, and gait speed, as evaluated through the 10 meter walk test, were demonstrated. In addition, the use of hypoxic training has been studied in healthy individuals and athletes; however, literature examining the effect of a single bout of AIH on performance is limited.