Active clinical trials for "Spinal Cord Injuries"

People with a Spinal Cord Injury can develop chronic pain within months of the injury. Up to 80% of the patients will develop chronic pain called "central pain" and describe the pain as: burning, stabbing, or "like electricity." Central pain mechanism is unknown and therefore treatment is currently not effective. It is hypothesized that chronic pain is associated with impaired function of the systems regulating pain, however, this hypothesis has not been tested among Spinal Cord Injury patients. Presence of such a connection, between the regulating system dysfunction and central pain, will help both predicting the risk of central pain and develop a treatment. The current research objective is to make several sensory measurements which will measure the functioning mechanisms of regulation and control of the pain. These measurements are accepted throughout the world and are based on psychophysical assessment of patients. these Measurements are designed to assess whether Spinal Cord Injury chronic central pain patients demonstrate impairment in the regulation of pain. Finding such a link between central pain and impaired regulation could shed light on the mechanism of central pain. In addition, these measurements are designed to assess whether fresh spinal cord injury patients that have not yet developed central pain demonstrate impairment in the regulation of pain immediately after the injury. By repeated assessments of pain regulation capabilities, which will be made to fresh Spinal Cord Injury patients during the first months of injury, and comparing the results of these measurements between those who will develop center pain and those who will not, we could identify indicators for predicting the risk of central pain. Another goal of the study is to investigate the efficacy of central pain treatment, using a TENS, when the parameters of the TENS treatment will be built according to the level of functioning of the regulating systems of the individual.

The purpose of this study is to develop and field-test new tools for diagnosis and hazard assessment of cardiometabolic risk (CMR) in people with chronic spinal cord injury (SCI) and to advance the evidence base with much needed information on CMR and cardiovascular disease (CVD) burden in people with SCI. These data can be used to develop screening guidelines for early identification and prevention of CMR in SCI, as well as targeted approaches to primary disease management.

Although conventional risk factors for coronary heart disease (CHD) have been identified and routinely used to determine risk for CHD in the general population, a systematic approach to determine population-specific risk for CHD has not been performed prospectively in those with SCI. CHD is a leading cause of death in spinal cord injury, occurring at younger ages than in the able-bodied population. Conventional risk factors for CHD are high serum concentrations of low-density lipoprotein (LDL), low serum concentrations of high-density lipoprotein (HDL), diabetes mellitus (DM), positive smoking history, and positive family history of premature CHD. Coronary Artery calcification (CAC) is a commonly occurring phenomenon that does not necessarily indicate significant obstructive disease. Studies have shown that a strong association exists between coronary calcification and coronary heart disease. The purpose of this study is to compare the CAC scores in persons with SCI with a historical control group of able-bodied persons from a national data base who will be matched for conventional risk factors for coronary artery disease (CAD) and to determine the relationship between CAC scores and conventional and emerging risk factors for CAD. Additionally, postprandial lipemic (elevated levels of lipids following ingestion of food) responses among individuals with SCI and control subjects will be compared, as well as the response of inflammatory markers following a high fat meal. Participants will only be tested once for these parameters.

Respiratory dysfunction is the leading cause of death in individuals with spinal cord injuries (SCIs). Nearly one quarter of all SCI cases involve injury to the upper spinal cord segments which impairs neural activation of the diaphragm muscle and compromises breathing. Although mechanical ventilation can be life-saving after cervical SCI (C-SCI), it also triggers rapid and profound diaphragm muscle atrophy, thereby complicating (or even preventing) ventilator weaning. Intramuscular diaphragm stimulation, or diaphragm pacing, was developed to replace long-term ventilator support, and is now used acutely post C-SCI (<4 months following injury) to promote ventilator weaning. The impact of diaphragm pacing on respiratory function and diaphragm muscle activation has not been formally evaluated. This is an essential step in determining the efficacy of intramuscular diaphragm stimulation and its effects on respiratory function after SCI. Accordingly, this research study will evaluate the effects of intramuscular diaphragm stimulation and test the hypothesis that diaphragm pacing enhances neuromuscular diaphragm activation and respiratory function in adults with cervical SCIs. The investigators will test the hypothesis by evaluating the effects of diaphragm pacing on neuromuscular activation of the diaphragm by directly recording electromyogram (EMG) activity from the intramuscular pacing electrodes. Recording from these surgically-implanted electrodes allows direct comparisons of EMG activity across time, minimizing methodological limitations inherent with surface or percutaneous EMG recordings. This approach, in association with respiratory assessments, will be used to investigate the impact of diaphragm pacing in adults with intramuscular diaphragm pacing electrodes following acute, traumatic C-SCIs.

This is a feasibility study to test the use of epidural stimulation to restore volitional function previously lost due to spinal cord injury. Previous studies conducted in animal models, performed elsewhere and here at Mayo Clinic, have shown that direct electrical stimulation of the spinal cord increases the excitability of spared neuronal connections within the site of injury, thereby enhancing signal transmission and allowing recovery of previously lost volitional function. Recently, epidural electrical stimulation of the lumbosacral spinal cord in four individuals with spinal cord injury (SCI) has restored motor and autonomic function below the level of injury. Despite positive results, further translational research is needed to validate these findings. The goal of this proposal is to perform epidural stimulation to restore volitional function in patients with SCI. In two patients, we will implant an epidural stimulator onto the dorsal aspect of the lumbosacral spinal cord dura mater. Patients will undergo a structured program of daily physical rehabilitation, treadmill step training, and epidural stimulation to recover motor, sensory, and autonomic function.

The investigation is a multi-year observational study following the completion of the open-label, single dose Phase I/II study involving transplantation of allogeneic HuCNS-SC cells into 12 subjects with thoracic spinal cord injury. Subjects will be monitored at routine intervals for safety and preliminary efficacy for 5 years post-transplantation of the Phase I/II investigation CL-N02-SC.

Adaptive gait assessements will be evaluated as a potential new marker for tracking locomotor recovery throughout rehabilitation of spinal cord injury subjects. To this end, controls, subacute and chronic patients will be assessed at two timepoints with 3 month standard rehabilitation inbetween. The specific assessments will require the participant to acitvely modulate their gait pattern to fullfill specific task constraints. Their performance will be assessed via 3D kinematics, kinetics and EMG and these measures will be used to describe the adaptive capacity that the patient retains. Sensitivity and specificity of these markers will be determined. With more sensitive descriptors of gait function and quality, locomotor rehabilitation for SCI can be better designed and smaller effects can be accurately measured.

The investigators conducting this study to investigate the relation between the respiratory muscle strength and respiratory complications. To understand more about respiratory complications the influence of different factors (such as in- and expiratory muscle strength, lung function parameters, physical activity, smoking, medications,…) on respiratory complications (such as pneumonia) will be investigated.

CSI:Brainwave is a multidisciplinary neurophysiological project, developed by the Lab of Medical Physics, School of Medicine, Aristotle University of Thessaloniki and supported by two Neurosurgical Departments. The project officially commenced on April 2014 and the first year was awarded the 2013 Mario Boni Research Grant by the Cervical Spine Research Society-European Section (CSRS-ES). The website for the project can be accessed at http://medphys.med.auth.gr/content/csi-brainwave. The investigation's primary objectives include the development, testing and optimization of a mountable robotic arm controlled with wireless Brain-Computer Interface, the development and validation of a self-paced neuro-rehabilitation protocol for patients with Cervical Spinal Cord Injury and the study of cortical activity in acute and chronic spinal cord injury.

The present study will analyze if exercise is able to elicit the well-known anti-atherogenic effects in patients with SCI. This will be evaluated by measuring vascular parameters such as endothelial and inflammatory blood markers, echocardiography of the heart and peripheral vessels, as well as blood pressure and arterial stiffness, in subjects performing either wheelchair dancing, wheelchair marathon or no sports. Further, it will be investigated, whether there is an association between neuroplasticity and cardiovascular health, as measured by electroencephalography (EEG), transcranial magnetic stimulation (TMS) and blood levels of the brain-derived neurotrophic factor (BDNF). We hypothesize that the cardiovascular, physical and psychological benefits of wheelchair dancing and/or wheelchair marathon parallel improved neuroplasticity in SCI-patients