View clinical trials related to Tetraplegia.
Filter by:The purpose of this study is to establish the value of combined non-invasive stimulation (tDCS) and behavioral training (robotics) in SCI rehabilitation, and understand the mechanisms of this interaction and its relationship to functional outcome. The investigators hypothesize that supplementary tDCS will augment the functional improvement from robot-training, in chronic SCI.
Patients with C5 or C6 tetraplegia have paralysis of the triceps brachii. Elbow extension can be surgically restored by transferring the tendon from a preserved muscle onto the tendon of the paralyzed triceps brachii. The most frequently used method transfers the posterior deltoid tendon. However, transferring the posterior deltoid can create an imbalance in the shoulder joint and this technique is not recommended when the clavicular head of the pectoralis major is weak. In such cases, a preferred method is a biceps brachii tendon transfer. The success of this intervention relies on the ability of the patient to dissociate the drive between the transferred biceps brachii and the other elbow flexor muscles. Even though tendon transfers are widely used, the subsequent reorganization of muscle coordination strategies remains largely unknown. The identification of muscle synergies and co-coactivations from electromyography (EMG) signals, defined as groups of muscles activated in synchrony, may help to provide a deeper understanding of changes in muscle coordination. The objective of this study is to investigate for the first time the reorganization of muscle coordination after surgical restoration of elbow extension through the identification of muscle synergies and the quantification of muscle co-activations. Four participants with tetraplegia will take part to this study. The experimental procedure will be conducted before their surgery and once a month during 6 months after their surgery. The procedure consists of performing consecutive elbow extension-flexion cycles with the shoulder abducted at different angles. Surface and intramuscular EMG measurements will be collected for several upper limb muscles. Muscle synergies and co-activations will be extracted from the EMG measurements.
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.
This study is for people who have a paralyzed arm and hand from a spinal cord injury, who have also received a recording electrode array in the brain as part of the BrainGate study. The study will look at the ability of these participants to control different grasping patterns of the hand, both in virtual reality and in his/her actual hand. Movement of the participant's hand is controlled by a functional electrical stimulation (FES) system, which involves small electrodes implanted in the arm, shoulder and hand that use small electrical currents to activate the appropriate muscles.
Research indicates that increasing brain excitability might help improve hand function in people with spinal cord injury. Brain stimulation that uses electrodes placed on the surface of the scalp (also called "non-invasive brain stimulation") increases brain excitability and has the potential to make it easier for the brain and nervous system to respond to arm and hand training. The purpose of this study is to compare four different types of stimulation for increasing brain excitability to determine which types are best for helping people with tetraplegia improve their ability to use their arms and hands. To fully evaluate the value of brain stimulation on arm and hand function, the investigators will also evaluate the effect of sham (fake) stimulation. Each participant will receive a single session of each of the five types of stimulation being tested.
People with locked-in syndrome cannot move their limbs or talk because of a motor impairment, but remain conscious and intellectually awake. Restoring the ability to communicate to people with locked-in syndrome will have a positive effect on their quality of life, will enable them to reintegrate into society and increase their capacity to lead productive and fulfilling lives. This study sims to develop a new assisted communication device based on a brain-computer interface, a system that allows the user to control a computer with his brain activity. The investigators will develop this brain-computer system for long-term stability and independent use by using adaptive decoders. The investigators will test the long-term stability and independence of this system with healthy volunteers, people with tetraplegia and people with locked-in syndrome over time periods of several months.
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.
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.
The aim of the study was to evaluate the tetraplegics movement strategies, assisted by Neuromuscular Electrical Stimulation (NMES), on the reach and palmar (RP) grasp to different weights objects.Tetraplegics had their RP grasp movement captured by four infrared cameras and 6-reflexive markers attached on the trunk and right arm, assisted or not by NMES, in the triceps, extensor carpi radialis longus, extensor digitorum communis, flexor digitorum superficialis, opponens pollicis and lumbricalis muscles. The grasp was made in three cylindrical objects (different diameters and weights) placed in trunk midline in an equivalent distance of the arm's length. The patients were able to reach and made palmar grasp in all cylinders using the stimulation sequences assisted by NMES.
Non-invasive brain stimulation has gained increasing popularity and research support over the past several years. Recent research indicates that it might have benefits for improving hand function in people with spinal cord injury. The purpose of this study is to evaluate the effects of a type of non-invasive brain stimulation, known as tDCS, on hand function.