View clinical trials related to Quadriplegia.
Filter by:This study will evaluate the effects of non-invasive stimulation of the spinal cord in people with spinal cord injury.
This study aimed to investigate the efficacy and safety of extracorporeal shockwave therapy (ESWT) for upper extremity pain related to spasticity in patients with spinal cord injury.
Muscle weakness is one of the most common and debilitating symptoms following a Spinal Cord Injury (SCI). Strength training is recommended as an effective means to increase muscular strength and improve function for individuals with long term SCI. In contrast, the strength training guidance for those with a recent (<1 year) SCI is lacking. Therefore, this study aims to investigate the feasibility of a method of upper limb strengthening - Progressive Resistance Training (PRT) and its impact upon muscle strength and function.
This study will examine a form of non-invasive brain stimulation applied with intensive therapy of the arm and hand. The goal of the study is to determine if arm and hand function can be improved in people with incomplete cervical spinal cord injury (neck spinal cord injury, tetraplegia). Participants will be assigned to receive either active or inactive non-invasive brain stimulation.
Functional electrical stimulation (FES) has been used for decades in rehabilitation centers. Having demonstrated efficacy for prevention of muscle atrophy following spinal cord injury (SCI), FES can also be considered for functional restoration of hand movements in the patients with complete tetraplegia belonging to group 0 or 1 of the classification of Giens. However, the majority of the systems using the FES directly stimulates the muscles (surface electrodes, intramuscular or epimysial), which increases the number of components and requires more electrical energy for the muscle activation. Nerve stimulation would activate more muscles through a reduced number of electrodes, limiting the number of internal components, reduces the risk of spreading infections and require less electrical energy for its operation.
Robotic gait training is often used with the aim to improve walking ability in individuals with Spinal Cord Injury. However, robotic gait training alone may not be sufficient. This study will compare the effects of robotic gait training alone to robotic gait training combined with either low-frequency or high-frequency non-invasive transspinal electrical stimulation. In people with motor-incomplete SCI, a series of clinical and electrical tests of nerve function will be performed before and after 20 sessions of gait training with or without stimulation.
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.
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 purpose of this study is to determine if individuals with incomplete spinal cord injury (SCI) who remain unable to walk normally 1 year after their SCIs are able to sense and move the affected legs better after 10-13 weeks of treatment with a new robotic therapy device. The hypothesis is that using the AMES device on the legs of chronic subjects with incomplete SCI will result in improved strength, sensation in the legs, and improved functional gait in the treated limbs.
The purpose of this research study is to demonstrate the safety and efficacy of using two NeuroPort Arrays (electrodes) for long-term recording of brain activity.