Active clinical trials for "Quadriplegia"

The main objective of our work is to develop and test the safety and feasibility of a home-based upper limb rehabilitation program for individuals with tetraplegia. The program will consist of simultaneous non-invasive spinal cord stimulation and immersive virtual exercises of the upper limbs, with a focus on shoulder and elbow function.

Corsets are often used in the management of patients with a spinal cord injury. They may help to rigidify the patients' trunk which might help some patients to sit upright; their use may also reduce the sensation of dyspnea some patients have while sitting upright. Due to spinal cord injury, abdominal muscles are weakened which can contribute to alter the respiratory function of the patients. But the corset by rigidifying the abdominal wall can improve the efficiency of the respiratory muscles in some patients and reduce dyspnea in the sitting position for some patients. However, when patients with spinal cord injury are followed over time, one can observe that some patients discontinue corset use. The investigators observed that the patients who pursue the corset use still have a significant improvement of their respiratory function with the corset while the patients who have discontinued the use have improved their respiratory function in the upright position (without the corset). As of now, the investigators do not know whether the use of the corset is discontinued because of a spontaneous improvement of the respiratory function or whether discontinuing the use of the corset may help to develop abdominal spasticity and therefore to improve respiratory function. The investigators seek to investigate this issue in order to optimize the management of patients who present spinal cord injury.

This study is designed to assess the impact of exercise and supplementation on measures of fitness, function, and cardiovascular disease risk factors/modifiers in individuals with spinal cord injury (SCI). The primary purpose of this study is to improve fitness and function, reduce cardiovascular disease risks, and enhance oxidation of dietary and body fats in persons with chronic tetraplegia through acute exercise, exercise conditioning, and dietary supplementation. This study will test the hypothesis that timing of supplementation with regards to exercise bout ('intervention/placebo') affects fitness, function, lipid profiles, lipid oxidation, and inflammatory markers after acute exercise and chronic conditioning.

Bladder dysfunction is a major problem in patients with complete spinal cord lesions. For patients presenting incontinence or risk for kidney, two major conventional alternatives are possible : conservative therapies (muscarinic receptor antagonists, vanilloids drugs and botulinum toxin in association with catheterization) and surgical techniques intervening in the nervous and urinary system. Among these last alternatives, the Brindley technique (anterior sacral root stimulation with posterior rhizotomy) is the only technique allowing for the restauration of bladder function, continence, and micturition. The purpose of the study is to compare the Brindley technique with the first conventional approach in France from a medical and economical point of view.

Respiratory complications continue to be one of the leading causes of morbidity and mortality in people with spinal cord injury, especially among cervical and higher thoracic injuries. Both inspiratory and expiratory function are often severely decreased, leading to respiratory complications, such as atelectasis, pneumonia and ventilatory failure. The prevention of these respiratory complications needs to begin immediately after injury. To achieve effective expelling of secretions before they form mucus plugs, it is essential to improve patients ability to cough. Manually assisting the cough is one way of increasing cough flow, but an effective cough also requires adequate lung volumes. The emphasis should therefore be on expansion of the lungs before coughing. One way of expanding the lungs is by air-stacking. In air-stacking insufflations are stacked in the lungs to maximally expand them. Cough can be valued by measuring Peak Cough Flow (PCF). By combining air-stacking with manually assisted cough the PCF can be increased sufficiently. The aim of this study is to compare the effect of two different air-stacking techniques on PCF, air-stacking on a respirator versus air-stacking with a manual resuscitator.

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.

This research study is being done to develop a brain controlled medical device, called a brain-machine interface or BMI, that will provide people with a spinal cord injury some ability to control an external device such as a computer cursor or robotic limb by using their thoughts. Developing a brain-machine interface (BMI) is very difficult and currently only limited technology exists in this area of neuroscience. The device in this study involves implanting very fine recording electrodes into areas of the brain that are known to create arm movement plans and provide hand grasping information. These movement and grasp plans would then normally be sent to other regions of the brain to execute the actual movements. By tying into those pathways and sending the movement plan signals to a computer instead, the investigators can translate the movement plans into actual movements by a computer cursor or robotic limb. The device being used in this study is called the NeuroPort Array and is surgically implanted in the brain. This device and the implantation procedure are experimental which means that it has not been approved by the Food and Drug Administration (FDA). One NeuroPort Array consists of a small grid of electrodes that will be implanted in brain tissue with a small cable that runs from the electrode grid to a small hourglass-shaped pedestal. This pedestal is designed to be attached to the skull and protrude though the scalp to allow for connection with the computer equipment. The investigators hope to learn how safe and effective the NeuroPort Array is in controlling computer generated images and real world objects, such as a robotic arm, using imagined movements of the arms and hands. To accomplish this goal, two NeuroPort Arrays will be used.

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.

The ability to maintain normal body temperature (Tcore) is impaired in persons with tetraplegia: subnormal Tcore and vulnerability to hypothermia (<95 F) have been documented in this population after exposure to even mild environmental temperatures. However, no work to date has addressed the effect of subnormal Tcore on cognitive performance in persons with tetraplegia despite studies with able-bodied (AB) individuals that have documented progressive decline in various aspects of cognitive performance associated with the magnitude of the depression in Tcore. The investigators' study will confirm and extend their initial observations in persons with higher cord lesions who have subnormal Tcore to show that cognitive performance will be improved by raising Tcore to euthermic levels. This improvement should be associated with greater function and independence, reintegration into society, and an improved quality of life. Specific Aims: During exposure to 95 F for up to 120 minutes in the seated position, the investigators' aims are: Primary Specific Aim: To determine if a modest rise in Tcore to euthermic levels has a positive effect on cognitive performance (attention, working memory, processing speed, and executive function) in persons with higher-level spinal cord injury (SCI). Primary Hypothesis: Based on the investigators' pilot data: (1) 80% of persons with SCI will demonstrate an increase of 1 F in Tcore, while none of the AB controls will demonstrate such an increase; (2) 80% of persons with SCI will have an improvement of at least one T-score in Stroop Interference scores (a validated measure of executive function), while none of the AB controls will demonstrate a change in cognitive performance. Secondary Specific Aim: To determine changes in: (1) The average of distal skin temperatures; (2) Sweat rate; and (3) Subjective rating of thermal sensitivity. Secondary Hypothesis: Persons with SCI will have less of a percent change in average distal skin temperatures and sweat rate, and will report blunted ratings of thermal sensitivity compared to that of AB controls.

The ability to maintain normal body core temperature (Tcore = 98.6°F) is impaired in persons with tetraplegia. Despite the known challenges to the ability of persons with spinal cord injury (SCI) to maintain Tcore, and the effects of hypothermia to impair mental function in able-bodied (AB) persons, there has been no work to date addressing these issues in persons with tetraplegia. The aim of this study is to determine if exposure of up to 2 hrs to cool temperatures (64°F) causes body core temperature to decrease in persons with tetraplegia and if that decrease is related to a decrease in mental performance. After sitting in a cool (64°F) room for up to 2 hours the investigators hypotheses are: Hypotheses (1): Tcore of most of the persons with tetraplegia will decline approximately 1.8°F (e.g., 98.6 to 96.8°F) while Tcore of controls will not decline at all; (2) Most of the persons with tetraplegia will show a decline in mental performance (memory or clear-headedness) while only some of AB controls will show a decline. The second aim of this study is to determine if a 10 mg dose of an approved blood pressure raising medicine (midodrine hydrochloride) will (1) reduce the decrease in body core temperature and (2) prevent or delay the decline in mental performance in the group with tetraplegia compared to the exact same procedures performed on the day with no medicine (Visit 1) in the same group. Hypotheses (3 & 4): The changes in blood flow to the skin caused by taking a one-time dose of midodrine will lessen the decline in Tcore and prevent or delay the decline in mental performance compared to the changes in Tcore and mental performance during cool temperature exposure without midodrine in the group with tetraplegia.