View clinical trials related to Plegia.
Filter by:The cervical spine is most commonly injured, accounting for 53.4% of spinal injuries. More than 40% of all spinal injuries occur at either C4, C5 or C6 levels leading to variable loss of function in the upper extremities. Traditionally, patients sustaining a cervical spine injury were followed for 2 years to ensure that recovery had stabilized before offering upper extremity reconstruction. This type of reconstruction includes active muscle transfer, tendon transfer and joint fusion. Patients are most commonly assessed immediately at the time of injury. Muscle testing is commonly performed using Medical Research Grading System (MRC). Although complete neurologic stabilization may not be complete until 2 years post-injury, in the group with initial grade 0 muscle strength after the acute phase of injury, expectations of improved muscle strength to or beyond grade 3 after 4-6 months is minimal. And grade 3 muscle strength is felt to be the minimum useful functional strength in a muscle group. The investigators propose an early nerve reconstruction approach to the tetraplegic patient with dysfunction of the upper extremity to augment the available tendon transfers. A comparative pilot study is proposed to determine the effectiveness of supinator branch to posterior interosseous nerve (PIN) transfer in 5 patients with cervical spine injury. Patient who fits inclusion criteria will be offered the opportunity to be involved in the study and reviewed at 6 months from injury. If the patient still has not regained Grade 3 power in finger or thumb extension, they will be randomized to be in a surgical group or non-surgical group. If informed consent is obtained, then surgery will be completed between 6-9 months from the patient's original cervical spine injury. The patient will be followed at regular intervals post-operatively with expectation of 18-24 month follow-up. Measures will be used pre and post-operatively for comparison. Measures will include MRC muscle grade (EDC), range of motion, Disability of the Arm, Shoulder, and Hand Questionnaire (DASH), and The Graded Redefined Assessment of Strength Sensibility and Prehension (GRASSP) (Kalsi-Ryan, 2011).
The procedure involves: (1) assisted hand movement by a mechanical device, (2) mechanical vibration applied to the surface of the forearm, and (3) stimulation of the brain with either transcranial magnetic stimulation (TMS) or transcortical direct current stimulation (DCS). These 3 components of the procedure are carried out simultaneously. Each subject will be evaluated pre- and post-treatment with several clinical tests of functional movement. The hypotheses of this project are that the AMES+rTMS and AMES+tDCS procedures are safe and will enable most of the stroke patients to recover finger extension.
The purpose of this study is to determine if individuals who had a stroke more than one year before entering the study and who remain unable to open their affected hand are better able to sense and move their affected arm after 10-15 weeks of treatment with a new robotic therapy device (the AMES device) and EMG biofeedback.
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).