View clinical trials related to Spinal Cord Injury.
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The study is a phase I/II trial designed to establish the safety and efficacy of intravenous combined with intrathecal administration of autologous bone marrow derived mesenchymal stem cells to patients with spinal cord injury.
This study is an NIH-funded two-part clinical trial to determine the best dose-ratio of individual subjects with central neuropathic pain following spinal cord injury (SCI), when two compounds with different target mechanisms are administered as combination therapy. The investigators will first determine each subjects' maximally tolerated dose (MTD) of chronic oral (PO) administration of dextromethorphan (Dex); the investigators will then randomize subjects to receive multiple dose-combinations of dextromethorphan and lidocaine (Lido). The investigators will be able to determine each subject's individual dose-response relationship for the separate compounds with adequate power, and thus also confirm the analgesic efficacy of high dose dextromethorphan and lidocaine, each in central neuropathic pain.
The trial will compare the effects of 14 days treatment with HP011 101 versus Standard Care in subjects with Stage I or II pressure ulcers as a complication of spinal cord injury, measured as change from baseline in composite wound bed scores of the PUSH 3.0 tool.
Until now, there's still no any strong evidence supported "which is the best way to restoration walking ability" in spinal cord injury. Most of the evidence suggest that, there is somehow better after gait rehabilitation for ASIA classification C and D but not improved walking ability for ASIA classification A and B. There is an RCT showed the evidence of repetitive locomotor training and physiotherapy could be improved walking and basic activities of daily living after stroke, these might be also really effect in SCI patients.
This prospective study will assess thoroughly functional deficits and their significance in the light of rehabilitation in spinal cord injured patients.
The investigators propose a prospective study, designed to analyze the efficacy of High-Resolution Diffusion Tensor Imaging for accurately sensing white matter tracts in subjects with spinal cord injury. Study subjects will not be randomized, as treatment will follow the doctor's "standard of care." Patients will be selected and offered enrollment based upon the clinical diagnosis of spinal cord injury, either due to degenerative disease or trauma. Enrollment will be based on the chronology of patient presentation.
Many people with spinal cord injury (SCI) hold some ability to move their leg muscles, and are therefore considered to demonstrate a motor incomplete injury. After such a spinal cord injury, individuals are able to walk less both in their home and in their community. De-conditioning, or a lack of endurance and fitness also occurs. Several methods are available to try to improve walking ability and the fitness of persons with motor incomplete spinal cord injury. This study examines two of these methods. The first is the use of robotically assisted body-weight supported walking using a device called the Lokomat. The second is aquatic or pool-based exercise. The investigators are researching the impact of these two techniques on walking ability and fitness in people who experienced motor incomplete spinal cord injury for at least 12 months.
The purpose of this study is to investigate the effects of Transcranial Direct Current Stimulation (tDCS) combined with watching a visual illusion on chronic pain due to spinal cord injury. The investigators hypothesize that active tDCS will reduce pain in subjects with spinal cord injury when compared to sham stimulation. The investigators will also measure changes in EEG data (alpha and beta frequencies) as well as motor cortex excitability.
The purpose of this research study is to demonstrate that individuals with upper limb paralysis due to spinal cord injury, brachial plexus injury, amyotrophic lateral sclerosis and brain stem stroke can successfully achieve direct brain control of assistive devices using an electrocorticography (ECoG)-based brain computer interface system.