View clinical trials related to Tetraplegia.
Filter by:A study to compare electrophysiologic activity of epidural stimulation and dorsal root ganglion stimulation, as well as quantify changes in motor performance with both types of stimulation over the course of 10 rehabilitation sessions.
Spinal cord injury (SCI) is a devastating, life-altering injury; requiring tremendous changes in an individual's lifestyle. Cycling, provides an ideal way for individuals with SCI to exercise and address the long-term consequences of SCI by targeting the lower extremity muscles. Cycling with the addition of functional electrical stimulation (FES) allows persons with paralysis to exercise their paretic or paralysed leg muscles. The Queen Elizabeth National Spinal Injury Unit (QENSIU) in Glasgow offers FES cycling for people with spinal cord injuries, which combines functional electrical stimulation (FES) with a motorised ergometer that allows repetitive cycling activity. It stimulates muscles with electrodes attached to the skin, producing muscle contractions and patterned activity. So far no previous randomised control trials on FES cycling in the acute SCI population have reported changes in ability to undertake activities of daily living or the trunk balance.
The aim of this study is to determine the effects of rehabilitation on dexterous hand movements and cortical motor map changes in tetraplegic patients following nerve transfer surgery. The working hypothesis is that robot-assisted, intensive rehabilitation will support the return of hand and arm function and strengthen the cortical representations of targeted muscles. The investigators will assess this through TMS mapping and clinical measures of hand and arm function.
Current treatment strategies of acute cervical spinal cord injuries remain limited. Treatment options that provide meaningful improvements in patient quality of like and long-term functional independence will provide a significant public health impact. Specific aim: Measure the efficacy of nerve transfer surgery in the treatment of patients with complete spinal cord injuries with no hand function. Optimize the efficiency of nerve transfer surgery by evaluating patient outcomes in relation to patient selection and quality of life and functional independence.
Vibration therapy is a possible alternative to drug-based treatments for spasticity following SCI. Research indicates that it may provide temporary relief from spasticity, but many interventions under investigation are not portable and therefore access is limited. The aim of this study is to investigate the feasibility of using a portable vibrating device to decrease UE spasticity.
The purpose of this research is to test the feasibility of an intervention using biofeedback to treat stress and anxiety among individuals with tetraplegia. The expected duration of participation in this study is about 5 hours over the course of about 5 weeks. Participants will be randomly assigned to either a biofeedback training intervention or a control group. After completing questionnaires, participants will undergo physiological monitoring for the purpose of measuring heart rate and breathing. Those assigned to the biofeedback group will undergo 20 minutes of physiological monitoring while also participating in biofeedback training twice a week for 4 weeks (8 sessions) from home. Those assigned to the control group will undergo 20 minutes of physiological monitoring twice a week for 4 weeks (8 sessions) from home, but will not receive biofeedback training. Each session is expected to last 30 minutes to allow for completion of questionnaires over the the phone prior to and following each training session. It is hypothesized that the biofeedback intervention will demonstrate high feasibility and compared to those in the control group, participants who receive the biofeedback intervention will attain greater pre-post reductions in both physiological and self-reported stress.
The purpose of this research study is to examine the feasibility of a system that involves implanting small electrodes in the parts of the brain that control movement and sensation, and combining that with electrodes in the upper arm and shoulder to activate paralyzed muscles of the arm and hand. This system is intended for people with extensive paralysis in their arms. The small electrodes in the brain will be used to attempt to measure intended movements, and the muscles in the arm and hand will be stimulated to attempt to follow those intentions. The study is a prospective, non-randomized, open-label, exploratory safety/feasibility trial of up to 12 subjects. The Primary Endpoint will be evaluation over the first 13 months after implantation, after which the subjects will have the option of removal of the device or continued participation in a long-term study.
This study aims to evaluate the safety of a wireless implantable neurodevice microsystem in tetraplegic patients, as well as the efficacy of the electrodes for long-term recording of neural activities and the successful control of an external device.
In the last decade the stimulation of denervated muscles got more attention. Not at least because of the promising results of the RISE project (Use of electrical stimulation to restore standing in paraplegics with long-term denervated degenerated muscles). In this European project it was shown that electrical stimulation of denervated muscles in spinal cord injuries (SCI) increased muscle mass and improved the trophic situation of the lower extremities. Furthermore, structural altered muscle into fat- and connective tissue could be restored into contractile muscle tissue by stimulation. However, only a few studies investigated the effect of direct muscle stimulation in case of peripheral nerve damage in the upper extremities. None investigated the stimulation effect in denervated or partially denervated muscles in the upper extremities in tetraplegic patients.
The CortiCom system consists of 510(k)-cleared components: platinum PMT subdural cortical electrode grids, a Blackrock Microsystems patient pedestal, and an external NeuroPort Neural Signal Processor. Up to two grids will be implanted in the brain, for a total channel count of up to 128 channels, for six months. In each participant, the grid(s) will be implanted over areas of cortex that encode speech and upper extremity movement.