View clinical trials related to Tetraplegia.
Filter by:The purpose of this study is to evaluate the effectiveness of an implanted stimulator for providing hand function to individuals with cervical level spinal cord injury. The device stimulates the paralyzed muscles of the hand and forearm. The user of the device controls the stimulation by moving muscles that are not paralyzed, such as a wrist or neck muscle. The ability of the user to pick up and move objects, as well as perform various activities such as eating, drinking, and writing.
The purpose of this study is to determine if tetraplegic individuals with incomplete spinal cord injury (SCI) who remain unable to move their arms normally 1 year after their SCIs are able to sense and move the affected arm(s) better after 10-13 weeks of treatment with a new robotic therapy device. The hypothesis is that using the AMES device on the arm(s) of chronic tetraplegic subjects with incomplete SCI will result in improved strength, sensation, and functional movement in treated limb(s).
Previously it was observed that individuals with tetraplegia have reduced baseline airway caliber and exhibit non-specific airway hyperresponsiveness (AHR). In persons with tetraplegia we have suggested that this is due to overriding cholinergic airway tone. In asthma, the mechanisms underlying bronchoconstriction and AHR are more closely tied to airway inflammation. Whether AHR in tetraplegia is also related to chronic airway inflammation is unknown. Recently, a non-invasive technique for assessing airway inflammation has been established in asthma that involves measurement of nitric oxide (NO) concentrations (FeNO) in expired air. FeNO is elevated in asthma likely due to excess NO production by inflammatory cells within the airway Measurement of FeNO in persons with tetraplegia would help in assessing the role of airway inflammation in this population. This may have therapeutic significance in such individuals. NO in the lung is felt to be the principal inhibitory neurotransmitter of the non-adrenergic, non-cholinergic (NANC) system. It is thought that inhalation of NO has no effect on airway tone in healthy individuals but reduces methacholine responsiveness while having weak direct bronchodilatory effect in asthmatics. The primary purpose of this study is to determine the levels of exhaled NO (FeNO) in individuals with chronic cervical spinal cord injury (SCI), and to compare them with those obtained in age and sex matched able-bodied individuals and subjects with stable mild to moderate asthma. If the FeNO levels are high and comparable to those found in asthmatic subjects, this will imply the role of chronic inflammation in reduced baseline airway caliber and non-specific airway hyper-responsiveness (AHR) exhibited by individuals with chronic cervical SCI. If the FeNO levels are comparable with those found in able-bodied controls, this will support our previous statement that unopposed cholinergic innervation is responsible for low baseline airway caliber and AHR in individuals with chronic tetraplegia. Further scientific conclusions about NO and its role in control of airway tone, pulmonary resistances and blood pressure will be drawn upon intravenous and inhaled administration of L-NAME. This compound has been shown promising results for the treatment and prevention of orthostatic hypotension in individuals with tetraplegia. Knowing its effects on airways and potential of easier mode of delivery (inhalation vs. intravenous) is of utmost importance.
1. To evaluate improvements in hand function in stable, cervical spinal cord injured (SCI) subjects treated with functional electrical stimulation (FES)-assisted exercise; 2. To compare the information obtained from existing qualitative and quantitative hand function tests with newly developed tests of sensorimotor performance. Hypotheses: 1. the performance of tasks representative of activities of daily living (ADL) will improve with daily tele-supervised exercise of the affected hand. 2. The improvements will be greater in one exercise protocol than the other, the protocols being a) FES-assisted exercise on a workstation, b) cyclical FES, weight training and precision tasks. 3. Scores derived from quantitative data obtained from sensors on the workstation will correlate with the qualitative scores of the primary outcome measure, the ARAT hand function test.
The purpose of this study is to evaluate a surgically implanted functional electrical stimulation (FES) system to facilitate exercise, standing, stepping and/or balance in people with various degrees of paralysis.
The purpose of this study is to evaluate the effectiveness of an implanted stimulator and sensor for providing hand and arm function for individuals with cervical level spinal cord injury.
The purpose of this study is to determine if replacing melatonin function with a melatonin agonist (ramelteon) in individuals that lack endogenous melatonin production (tetraplegia) helps to alleviate self-reported sleep disruption.
This proposal investigates the hypothesis that progressive aerobic exercise with Lokomat is feasible in people with motor incomplete spinal cord injury, and three months of training will improve cardiovascular fitness and gait functionality when compared to physical therapy controls
People with high spinal lesions are at risk of respiratory complications because they have partial or complete paralysis of breathing muscles. Previous work has shown that tetraplegic lung volumes can be increased by using abdominal FES during expiration. The technique is attractive because it is non-invasive, painless in tetraplegia and completely reversible. It may provide a treatment for augmenting the patient’s breathing both in the acute presentation of spinal injury (when half of cervical injuries require ventilation) and in long term management of tetraplegia and high paraplegia. We propose a pilot study in a small group of subjects to see if the technique is feasible from both a clinical and engineering viewpoint. The aims of the study are: 1)To examine the effects of abdominal FES on lung mechanics and gas exchange in tetraplegic subjects. 2)To optimise the stimulation pattern and intensity via electronic stimulators and to design a trigger to allow the FES to follow the subject’s own breathing cycle automatically.