View clinical trials related to Spinal Cord Injuries.
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The goal of this clinical trial is to assess the safety and feasibility of providing extra doses of rehabilitation therapy for persons with a recent stroke, traumatic brain injury (TBI) and/or spinal cord injury (SCI). The therapy treatment targets to improve arm function by introducing telerehabilitation to the bedside of participants during the inpatient rehab admission period. Participants will use a newly developed functional training system (HandyMotion) to access therapy treatment program directly from their hospital room. HandyMotion is a sensor-based training system that can connect to the TV set in the hospital room, enabling patients to access their therapy training program to practice rehab-oriented games and exercises ad libitum, at any time of the day.
Patients arriving to rehabilitation up to 2 months following SCI will be given (study group) or not (control group) Lyrica (75X2). They will be followed for central pain development.
After spinal cord injury (SCI), there is a disruption in neural circuits resulting in paralysis. There is not yet a cure for paralysis. In persons with Cervical SCI (pwC-SCI) recovery of arm-hand function is very important as it has a significant impact on the patients' level of independence and quality of life. Recovery is assumed to involve alterations in both central and peripheral motor systems. Motor training at an intensive dosage potentially provides a powerful stimulus for neurological recovery. This project exploits the peripheral and central neuroplastic effect of an early (<10 weeks after injury) and intensive (10 weeks of 12 hours in addition to usual care) upper limb motor training program (EIUMT) directed at recovery below the level of the injury in pwC-SCI within an international multi-center randomized controlled trial including 40 pwC-SCI. It has 4 objectives: to investigate 1)central neural plasticity by identifying alterations in cortical neuroplasticity and corticospinal excitability; 2)peripheral neural plasticity by identifying alteration in axonal excitability and number of motor units; 3)behavioral motor recovery of upper limb and 4)relationships between dose dimensions of motor intervention and behavioral and neurophysiological outcome measures aer EIUMT. Cutting-edge neurophysiological measures are used to provide insight in the mechanism of neuroplasticity after EIUMT and will be taken before and after EIUMT and at 6 months follow-up.
Sport is a physical activity that has many physical, psychological and social benefits for those with spinal cord injury (SCI). However, most sport research involves people with SCI who are <50 years old. This is a problem because many people are >50 years old when first injured. Moreover, people with a SCI are now living longer lives, meaning they also experience more health challenges. Unfortunately, there is limited research studying the impact of sport for adults with SCI aged ≥50 years old.
Spasticity is one of the most common symptoms manifested in humans with spinal cord injury (SCI). However, the neural mechanisms underlying the development of spasticity over time after an acute SCI are not yet understood. Using electrophysiological and imaging techniques along with traditional measurements of neurological recovery in the acute rehabilitation setting including physical exam and functional assessments; the investigators aim to examine the relationship between development of spasticity, residual descending motor pathways and functional and neurological recovery in humans with SCI from acute to subacute phase
As compared to the general population, those living with a spinal cord injury (SCI) are at a greater risk of cardiovascular (CV) diseases.The investigators know that regular exercise can help lessen the risk of CV diseases. However, those with higher level SCI have a limited ability to exercise due to their loss of function. Heat therapy has been shown to promote significant health benefits in populations with health challenges and has demonstrated a mild exercise like response. The investigators aim to extend these findings and develop a practical passive heat therapy program appropriate for safe home use.
Respiratory complications are among the leading causes of death in patients with chronic spinal cord injury (SCI). Our previous work showed that pulmonary function can be improved by using our original respiratory training method. However, the effectiveness of this intervention is limited due to the disruption of brain-spinal connections and consequently lowered spinal cord activity below the injury level. Our recent studies showed that electrical stimulation of the spinal cord below the level of injury leads to increased ventilation which indicates activation of the spinal cord structures related to respiration. These findings indicate that spinal cord stimulation can be a promising therapeutic additive to the treatment. The goal of this study is to justify the establishment of a new direction in rehabilitation for patients with SCI by using a non-invasive spinal cord stimulation in combination with respiratory training. Our aims are: 1) to evaluate the effects of such stimulation applied to the injured spinal cord on pulmonary function and respiratory muscle activity, and 2) to evaluate the effectiveness and therapeutic mechanisms of the spinal cord stimulation combined with respiratory training. Thirty-six individuals with chronic SCI will be recruited and assigned to three groups to receive respiratory training or spinal cord stimulation alone or a combination of them. All participants will be tested before and after cycles of experimental procedures with/or without stimulation. Our hypotheses will be confirmed if the respiratory training combined with spinal cord stimulation results in the most enhanced positive effects.
Acute intermittent hypoxia (AIH) involves brief (1 min), repeated episodes (~15) of breathing low oxygen air to stimulate spinal neuroplasticity. Animal and human studies show that AIH improves motor function after spinal cord injury, particularly with slightly increased carbon dioxide (hypercapnic AIH; AIHH) and task-specific training. Using a double blind cross-over design, the study will test whether AIHH improves breathing more than AIH and whether specific genetic variations are related to individuals' intervention responses.
The purpose of this study is to investigate the effectiveness of bodily illusions combined with transcranial direct current stimulation (tDCS) on neuropathic pain symptoms and sensory functions in participants with spinal cord injury (SCI) and neuropathic pain.