View clinical trials related to Spinal Cord Injuries.
Filter by:Study of the effect of gabapentin used as a preemptive to the emergence and development chronic neuropathic pain in patients after spinal cord trauma
The purpose of the study is to detect the presence of autoantibodies and autoantigens in cerebrospinal fluid early (<48 hours) following spinal cord trauma. The study also aims to define the central or peripheral origin of autoantibodies by looking for their simultaneous presence at the blood level and to evaluate the prognostic value of the presence of autoantibodies within the cerebrospinal fluid, as well as on the initial clinical severity than on the recovery potential.
Pilot Study of Clinical Safety and Feasibility of the Neuro-Spinal ScaffoldTM for the Treatment of Complete (AIS A) Traumatic Acute Spinal Cord Injury at the C5-T1 Neurological Levels The purpose of this study is to support an expansion to support marketing applications as well as future studies.
The overall vision of this proposal is to demonstrate that a virtual reality based motor imagery training program will improve brain computer interface (BCI) performance and motor function in quadriplegic subjects. The ultimate goal is to increase the independence of subjects with spinal cord injury by training to safely control BCI assistive devices and to enhance motor recovery.
- People with cervical spinal cord injury (SCI) and amyotrophic lateral sclerosis (ALS) have reduced connections in the nerve circuits between the brain and the hands. Activating spared nerve circuits is one potential way to improve recovery. - The investigators are testing different combinations of physical wrist and hand movements paired with magnetic brain stimulation and electrical spinal cord or nerve stimulation to see the effects on nerve transmission to hand muscles. - This is a preliminary study. This study is testing for temporary changes in nerve transmission to hand muscles. There is no expectation of long-term benefit from this study. If temporary changes are seen in this study, then future studies would focus on how to prolong that effect.
To determine the biophysical impact of biophysical Impact of Transcutaneous Spinal Cord Stimulation (TSCS) within a single session. We hypothesize that subjects will demonstrate increased volitional muscle strength with TSCS. This will be assessed by isokinetic strength testing of post-injury dominant-side knee extension. Subjects will be tested in both Transcutaneous Spinal Cord Stimulation and sham conditions.
The purpose of this research device study is to learn more about the autonomic nervous system. This system uses nerves to send information from the brain to the rest of the body by electrical signaling and has two divisions, the sympathetic and the parasympathetic branches. It has been thought that electrical stimulation devices could be used to restore balance to the nervous system. Because most of the imbalance seems to happen due to too much sympathetic activity, the investigator plans to focus on the parasympathetic branch. Specifically, the investigator hopes to restore balance by targeting the vagus nerve, which is the main communicator of the parasympathetic branch. The study will examine whether the investigator can decrease sympathetic activity and chronic inflammation by increasing parasympathetic activity. This is a device study that will examine the use of non-invasive vagal nerve stimulation to attenuate inflammatory stress and sympathetic hyperactivity in persons with Spinal Cord Injury and Non-Disabled Controls.
The primary objective of this study is to investigate the pharmacokinetic and -dynamic properties of rivaroxaban after oral administration in cervical spinal cord injury (SCI) individuals. The secondary objective of this study is to determine the steady-state rivaroxaban activity in cervical SCI individuals under long-term therapy. Primary Objective In-house patients will be informed concerning the study and informed consent will be collected. During the screening day, in- / exclusion criteria will be assessed and a blood samples will be taken for assessing haematology, clinical chemistry and coagulation parameters. Furthermore, the evaluation day will be scheduled. On the evaluation day, in- / exclusion criteria will be re-assessed. A venous catheter will be introduced into a forearm or lower leg of each participant for the collection of blood at the specified time points. Skin inspection for subcutaneous bleeding will be performed and vital signs will be recorded. A blood sample will be taken for assessing haematology, clinical chemistry and coagulation parameters. Single administration of oral rivaroxaban in the form of Xarelto® 10mg tablets (Bayer Schering Pharma, Berlin, Germany). Rivaroxaban concentrations will be determined from plasma samples taken before, 30min after and 1, 2, 3, 4, 5, 6, 8, 12, 24 hours after rivaroxaban administration. Rivaroxaban activity will be determined from plasma samples taken before, 30min after and 1, 2, 3, 4, 5, 6, 8, 12, 24 hours after rivaroxaban administration using a factor Xa inhibition test and measuring prothrombin time (PT) and activated partial thromboplastin time (aPTT). Skin inspection for subcutaneous bleeding and measurements of vital signs will be performed 30min and 1, 2, 3, 4, 5, 6, 8, 12 and 24 hours after rivaroxaban administration. Secondary Objective Patients under long-term rivaroxaban therapy will be recruited during their annual check-up visit at the Swiss Paraplegic Centre. In- / exclusion criteria will be assessed, and the patients will be informed concerning the study and informed consent will be collected. Blood samples will be taken for assessing haematology, clinical chemistry and coagulation parameters, and skin inspection for subcutaneous bleeding and measurements of vital signs will be performed. A blood sample (4.3ml citrated venous blood) will be taken for assessing the primary and secondary outcome parameters.
Spinal cord neural circuitry exists in the lumbar enlargement that makes it possible to stand and create synergistic, rhythmic stepping activity in the lower limbs. In the past 20 years, clinicians have tried to reengage such these circuits for standing and walking in the lower spinal cord of paralyzed humans through novel paradigms of physical therapy, pharmacological stimulation of the spinal cord, or recently - epidural stimulation of the spinal cord. Although standing and stepping with these maneuvers are rudimentary at best, these human studies offer promise to restore controlled, lower extremity movement to the spinal cord injured (SCI) individual. Evidence from animal data suggests that more focal activation of intraspinal circuitry (IntraSpinal Micro-Stimulation - ISMS) would produce more fatigue resistant, natural standing and stepping activity in humans. To date, there has been no direct confirmation of such circuitry in the spinal cord of bipedal humans who have been paralyzed. Furthermore, mapping of such circuitry would provide the basis of a novel intraspinal neuroprosthetic that should be able to restore control of standing or walking in a manner that is much more physiologically normal and tolerable than by stimulating each individual muscle group. Proof of the existence of these spinal circuits in man, and the ability to activate and control these circuits by first mapping the spinal cord is the basis of this proposal.
This study seeks to evaluate the efficacy of nerve transfers in restoring hand function in patients with cervical spinal injuries.