Active clinical trials for "Quadriplegia"

Evaluate and compare the health benefits of an at home exercise program using functional electrical stimulation (FES) for lower extremity exercise with diet versus a diet alone group in adults with spinal cord injury.

Motor imagery has shown promising results to optimize tenodesis grasp in individuals with C6-C7 tetraplegia. However, efficacy of using motor imagery to improve grasping after tetraplegia requires further study with higher level of evidence. In addition, controlling covert practice remains difficult due to the absence of overt movements. However, similar brain activity measured during both over and cover movements makes possible to provide visual information about the covert practice performance using neurofeedback. The Investigators thus designed this multicentric randomized controlled trial to investigate the effect of motor imagery with or with no visual neurofeedback on grasping capabilities after C6-C7 tetraplegia. They hypothesized that providing neurofeedback based on brain activity measured by electroencephalography namely knowing the covert practice performance would results in greater grasping improvement in response to practice as compared to motor imagery practice alone.

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.

Cerebral Palsy (CP) is is estimated to be around 1.5-3 per live birth, with prenatal factors accounting for 75% of cases. CP appears in early childhood and persists with age and is characterized by permanent lesions or abnormalities affecting the immature brain. It mainly occurs as a motor system disorder (e.g., abnormal movements or posture) with the presence of hemiplegia, diplegia or tetraplegia, and spastic, dyskinetic or atactic syndromes. .This study will explore the potential clinical benefits of the Molliimethod in children with cerebral palsy. Spasticity impacts balance and mobility, halts the patients quality of life and their ability to perform their activity of daily living, and could also increase the risk of fractures and falls. Available interventions that aim on improving spasticity are facing limitations such as varios side effects. Therefore, developing novel therapies such as the EXOPULSE Mollii Suit could help to overcome such limitations and noninvasively improve balance, mobility, quality of life and reduce spasticity and pain in children with CP.

This is a single-cohort early feasibility trial to determine whether an investigational device called the Bidirectional Neural Bypass System can lead to the restoration of movement and sensation in the hand and wrist of up to three individuals with tetraplegia.

The Bidirectional Cortical Neuroprosthetic System (BiCNS) consists of NeuroPort Microelectrode Array Systems and NeuroPort Electrodes (Sputtered Iridium Oxide Film), Patient Pedestals, the NeuroPort BioPotential Signal Processing System, and the CereStim C96 Programmable Stimulator. The goals of this early feasibility study consist of safety and efficacy evaluations of this device.

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.

The Synchron motor neuroprosthesis (MNP) is intended to be used in subjects with severe motor impairment, unresponsive to medical or rehabilitative therapy and a persistent functioning motor cortex. The purpose of this research is to evaluate safety and feasibility. The MNP is a type of implantable brain computer interface which bypasses dysfunctional motor neurons. The device is designed to restore the transmission of neural signal from the cerebral cortex utilized for neuromuscular control of digital devices, resulting in a successful execution of non-mechanical digital commands.

The purpose of this study is to obtain preliminary device safety information and demonstrate proof of principle (feasibility) of the ability of people with tetraplegia to control a computer cursor and other assistive devices with their thoughts.

Individuals suffering from tetraplegia as a result of cervical spinal cord injury, brainstem stroke, or amyotrophic lateral sclerosis (ALS) cannot independently perform tasks of daily living. In many cases, these conditions do not have effective therapies and the only intervention is the provision of assistive devices to increase independence and quality of life. However, currently available devices suffer from usability issues and are limiting for both the patient and caregiver. One of the most progressive alternative strategies for assistive devices is the use of brain-computer interface (BCI) technology to translate intention signals directly from sensors in the brain into computer or device action. Preclinical primate research and recent human clinical pilot studies have demonstrated success in restoring function to disabled individuals using sensors implanted directly in motor regions of the brain. Other preclinical primate research has demonstrated effective intention translation from sensors implemented in cognitive regions of the brain and that this information complements information from the motor regions. The current proposal seeks to build on these studies and to test the safety aspects related to implanting two sensors, each a microelectrode array, into both the motor and cognitive regions of the brain in motor impaired humans. Secondary objectives include feasibility evaluation of the complementary sensors in their ability to support effective assistive communication.