View clinical trials related to Spinal Cord Diseases.
Filter by:This study will comprehensively evaluate the outcomes and endpoints of these two different FDA-approved artificial disc implants used to treat cervical spondylotic myelopathy and/or radiculopathy today: Biomet Zimmer Mobi-C and Nuvasive Simplify. Both implants are structurally different with the Nuvasive Simplify implementing a three-piece design with two endplates and a semi-constrained mobile core while the Biomet Zimmer Mobi-C implements an unconstrained three piece design. Subjects will be age-matched and randomly assigned to either implant with informed consent. All subjects will undergo a variety of assessments that evaluate neck disability, quality of life, pain, physiological outcome (radiographic assessments), and neck range-of motion before and after their procedure. One baseline testing will be conducted along with three post-operation visits (three months, six months, and one year) in accordance to standard follow-up procedure. Thus, the duration of participation in the study will be approximately one and a half years.
The purpose of this trial is to assess fusion rates in 3 and 4 level ACDFs in patients implanted with DePuy Conduit 3D printed titanium cages supplemented with SKYLINE Anterior Cervical Plate System and 1 CC DBM. This will be a non-inferiority study, looking to show that Synthes Conduit 3D printed titanium cages fuse as well as cages.
The goal of this study is to evaluate if non-invasive electrical spinal stimulation can help people with paralysis caused by SCI improve strength and function of their arms, legs, hands or feet. The study will involve therapy sessions involving exercises done at the same time as electrical stimulation therapy. This study has multiple parts to evaluate the effectiveness and safety of "smart" electrical stimulation of the spinal cord, which involves stimulating the spinal cord at precise locations and times to improve movement and function.
The programme is designed to investigate the application of robotic exoskeleton in different levels of local rehabilitation facilities. Feasibilities, efficacy, cost-effectiveness, patient and therapist's view of the application of robotic exoskeleton will be evaluated.
The overarching aim of this study is to investigate the contribution of peripheral afferent input to spontaneous and evoked central neuropathic pain after a spinal cord lesion or disease.
The proposed project seeks to maximize the functional recovery achieved during the rehabilitation of the paretic upper limbs in individuals with SCI. The investigation will work towards optimizing the use of transcranial direct current stimulation (tDCS), an adjunct known to improve the effectiveness of rehabilitation. In particular, the relationship between the specificity of current delivery and functional benefit will be explored, and findings may lead to a framework that can be translated to the clinic setting.
Spinal cord injury following posterior decompression in patients suffering from chronic, cervicothoracic spinal cord compression is a known complication with multiple etiologies. Currently, intraoperative neuromonitoring (IONM) remains the gold standard for predicting and preventing post-operative deficits from these procedures. However, there is a paucity in the field of spine surgery for further, non-invasive biomarkers that can help detect and prognosticate the degree of spinal cord injury intraoperatively. Contrast enhanced ultrasound (CEUS) is a radiation free imaging modality that utilizes nanobubble technology to allow for visualization of the macro- and microvascular architecture of soft tissue structures. Despite being currently approved for the use in hepatology and cardiology, it has remained absent from the field of spinal cord injury. The study team aims to evaluate and quantify micro- and macrovascular changes that lead to areas of hyper-perfusion as well as areas of ischemia intraoperatively in patients that undergo elective cervicothoracic posterior decompression for chronic compression. In addition, the study team aims to assess the efficacy of CEUS in detecting microvascular changes that correlate with IONM changes and predicting degree and recovery of post-operative neurologic deficits from intraoperative spinal cord injury. The study team hypothesizes that following decompression, subjects will have detectable levels of microvascular changes causing areas of hypoperfusion and reperfusion injury. Second, the study team hypothesizes that these perfusion changes will correlate with intraoperative neuromonitoring changes and can predict and prognosticate the degree of post-operative neurologic injury.
For many people with spinal cord injury or brain injury, seeking employment after injury is an important goal. There are services available to help people with disabilities. However, the best ways to coordinate and deliver these services are not yet known. This project will compare two ways of coordinating and delivering services that are designed to help people with spinal cord injury or brain injury obtain employment.
For many people with spinal cord injury, seeking employment after injury is an important goal. There are services available to help people with disabilities. However, the best ways to coordinate and deliver these services are not yet known. This project will compare two ways of coordinating and delivering services that are designed to help people with spinal cord injury obtain employment.
To create a research repository of patients with known degenerative cervical myelopathy (DCM) and a control cohort of subjects who have non-myelopathic spinal disease. This repository will be used to assess functional and/or biological measures that may allow for improved prediction of symptomatic progression and response to treatment in patients with DCM. In addition, this repository will be used to develop a risk assessment scale to accurately predict functional outcomes following operative management of DCM.