View clinical trials related to Spinal Cord Injuries.
Filter by:The purpose of this study is to develop a new paradigm to understand how humans physically interact with each other at a single and at multiple joints, with multiple contact points, so as to synthesize robot controllers that can exhibit human-like behavior when interacting with humans (e.g., exoskeleton) or other co-robots. The investigators will develop models for a single joint robot (i.e. at the ankle joint) that can vary its haptic behavioral interactions at variable impedances, and replicate in a multi-joint robot (i.e. at the ankle, knee, and hip joints). The investigators will collect data from healthy participants and clinical populations to create a controller based on our models to implement in the robots. Then, the investigators will test our models via the robots to investigate the mechanisms underlying enhanced motor learning during different human-human haptic interaction behaviors (i.e. collaboration, competition, and cooperation. This study will be carried out in healthy participants, participants post-stroke, and participants with spinal cord injury (SCI).
The goal of this study is to determine whether administration of sildenafil will decrease urine leakage in patients with spinal cord injuries.
Intraspinal pressure monitoring has been advanced as a potential technique for evaluating spinal cord perfusion after traumatic spinal cord injury. In this study, the investigators aim to validate the technique for insertion of a fiberoptic pressure monitoring device in the subarachnoid space at the site of injury for measurement of intraspinal pressure and spinal cord perfusion pressure. The primary objective of this study is to validate the methodology of invasive intraspinal pressure monitoring to derive parameters for optimal spinal cord perfusion pressure, spinal cord reserve capacity and spinal reactivity index using data obtained during the patient's stay in the intensive care unit. Secondary objectives of this study will be to a) evaluate the safety of invasive intraspinal pressure monitoring, b) prospectively evaluate the overall relationship between spinal cord perfusion pressure and functional outcomes in patients with acute traumatic spinal cord injury and c) evaluate the relationship between spinal cord perfusion pressure, motor evoked potentials and functional outcomes after incomplete spinal cord injury.
Comparing the efficacy of Intracthecal Baclofen dose between the Prometra II and Medtronic SynchroMed II for patients with spasticity and with current a current SyncroMed II pump needing replacement.
The purpose of this study is to evaluate the safety and effectiveness of intrathecal transplantation of autologous bone marrow-derived mononuclear cells for the treatment of traumatic acute spinal cord injury. Spinal cord injury can be divided into three phases, which are acute (within 2 weeks), sub-acute (2 weeks to 6 months), and chronic (over 6 months). Early treatment is the key to improve the prognosis, however, the majority of clinic trails nowadays are focusing on sub-acute or chronic phase because it takes 4-6 weeks to expand the autologous stem cells. In this study, the investigators will treat patients with acute spinal cord injury with autologous bone marrow-derived mononuclear cells and compare with the control group.
The purpose of this research study is to investigate the safety and potential therapeutic effects of autologous, culture-expanded, adipose derived mesenchymal stem cell intrathecal injections in the treatment of spinal cord injury.
This study will assess how the serotonin precursor, 5-HTP, alter nervous system excitability and motor function in individuals with spinal cord injuries of differing chronicity and severity. Participants will visit the lab on 4 separate occasions where they will be administered four different drugs in a randomized, double-blinded, placebo-controlled crossover design.
Neurological disability caused by traumatic lesions of the spinal cord is a significant challenge for medicine and society. These lesions, leading to sublesional central nervous system dysfunction, include sensorimotor, vesico-sphincter and genito-sexual disorders. To date, there is no treatment that enables spinal cord function to be restored. Preclinical studies have been able to demonstrate the recovery of locomotor activity with a combination of locomotor training, pharmacological intervention and epidural electrical stimulation of the lumbosacral spinal cord (EESS) in adult rats with spinal cord transection. An American team have recently been able to show that EESS, combined with locomotor training, caused neurological improvement in four paraplegic patients, with electromyographic muscular activation patterns similar to those observed during walking. In fact, these authors also showed an improvement, under stimulation, of the VS and GS functions, but with no detailed documentation. Starting with a conceptual and preclinical rationale, and with proof of clinical concept demonstrated in several reported cases, we propose a clinical trial with an original cross-over design to validate the hypothesis that EESS combined with training in patients with incomplete spinal cord injuries would, with a good tolerance profile, allow motor, vesico-sphincter (VS) and genito-sexual (GS) disorders to be restored in patients with incomplete spinal cord injuries.
This study looks to characterize gradients of dysfunction in the autonomic nervous system after spinal cord injury. The autonomic nervous system plays key roles in regulation of blood pressure, skin blood flow, and bladder health- all issues that individuals with spinal cord injury typically suffer. Focusing on blood pressure regulation, the most precise metric with broad clinical applicability, the investigators will perform laboratory-based tests to probe the body's ability to generate autonomic responses. For both individuals with spinal cord injury and uninjured controls, laboratory-based experiments will utilize multiple parallel recordings to identify how the autonomic nervous system is able to inhibit and activate signals. The investigators anticipate that those with autonomic dysfunction after spinal cord injury will exhibit abnormalities in these precise metrics. The investigators will further have research participants wear a smart watch that tracks skin electrical conductance, heart rate, and skin temperature, which can all provide clues as to the degree of autonomic dysfunction someone may suffer at home. The investigators will look to see if any substantial connections exist between different degrees of preserved autonomic function and secondary autonomic complications from spinal cord injury. In accomplishing this, the investigators hope to give scientists important insights to how the autonomic nervous system works after spinal cord injury and give physicians better tools to manage these secondary autonomic complications.
This study is non-randomized, multicenter, confirmatory study by intrathecal administration of KP-100IT, code of HGF (Hepatocyte Growth Factor ) formulation for intrathecal injection, in subjects with acute spinal cord injury.