View clinical trials related to Upper Extremity Paresis.
Filter by:Constraint-Induced Movement Therapy or CI Therapy is a form of treatment that systematically employs the application of selected behavioral techniques delivered in intensive treatment over consecutive day with the following strategies utilized: behavioral strategies are implemented to improve the use of the more- affected limb in life situation called a Transfer Package (TP), motor training using a technique called shaping to make progress in successive approximations, repetitive, task oriented training, and strategies to encourage or constrain participants to use the more-affected extremity including restraint of the less-affected arm in the upper extremity (UE) protocol. Numerous studies examining the application of CI therapy with UE rehabilitation after stroke have demonstrated strong evidence for improving the amount of use and the quality of the more-affected UE functional use in the participant's daily life situation. CI Therapy studies with adults, to date, have explored intensive treatment for participants with a range from mild-to-severe motor impairment following stroke with noted motor deficits and limited use of the more-affected arm and hand in everyday activities. Each CI Therapy protocol was designed for the level of impairment demonstrated by participants recruited for the study. However, often following stroke, patients not only have motor deficits but somatosensory impairments as well. The somatosensory issues have not, as yet, been systematically measured and trained in CI Therapy protocols with adults and represent an understudied area of stroke recovery. We hypothesize that participants with mild-to-severe motor impairment and UE functional use deficits can benefit from CI therapy protocols that include somatosensory measurement and training components substituted for portions of motor training without loss in outcome measure gains. Further, we hypothesize that adults can improve somatosensory outcomes as a result of a combined CI therapy plus somatosensory component protocol.
Constraint-Induced Therapy (CI Therapy) is a behavioral approach to neurorehabilitation and consists of multi-components that have been applied in a systematic method to improve the use of the limb or function addressed in the intensive treatment. CI Therapy for the more-affected upper extremity (UE) post-stroke is administered in daily treatment sessions over consecutive weekdays. Sessions include motor training with repeated, timed trials using a technique called shaping, a set of behavioral strategies known as the Transfer Package (TP) to improve the use of the more-affected hand in the life situation, and strategies to remind participants to use the more-affected UE including restraint. Robust improvements in the amount and qualify of use have been realized with stroke participants from mild-to-severe UE impairment.
The purpose of this study is to evaluate the effectiveness of Fesia Grasp, a Functional Electrical Stimulation device for the rehabilitation of upper limb in post-stroke patients. Fesia Grasp rehabilitation will be compared with usual care rehabilitation of upper limb. - Experimental group: patients will receive Fesia Grasp therapy (intensive, repetitive and functional exercises assisted by functional electrical stimulation) - Control group - patients will receive standard care.
Loss of arm function is a common and distressing consequence of stroke. Neurotechnology-aided rehabilitation could be a promising approach to accelerate the recovery of upper limb functional impairments. This multicentre randomized controlled trial is aimed at assessing the efficacy of robot-assisted upper limb rehabilitation in subjects with sub-acute stroke following a stroke, compared to the traditional upper limb rehabilitation.
Stroke is the most common neurological disease leaving one third dead and one third with permanent impairment despite best medical treatment. The aim of the present study is to investigate why patients differ in how they benefit from neurorehabilitation by collecting clinical, electrophysiological, imaging and laboratory data in the acute phase of stroke as well as later on during rehabilitation and after 90 days. Following a closed-loop approach the data is analyzed by a machine learning algorithm to create a personalized neurorehabilitation strategy.
mCIMT and BIT are therapies applied in children with hemiplegia which have a great evidence, but not in a early age. This research has the objective to know the effects of this therapies in infants diagnosed of infantile hemiplegia from 9 to 18 months applying 50 hours of dose for both interventions during 10 weeks, executing them at home by familes.
Texas Biomedical Device Center (TxBDC) has developed an innovative strategy to enhance recovery of motor and sensory function after neurological injury termed targeted plasticity therapy (TPT). This technique uses brief pulses of vagus nerve stimulation to engage pro-plasticity neuromodulatory circuits during rehabilitation exercises. Preclinical findings demonstrate that VNS paired with rehabilitative training enhances recovery in multiple models of neurological injury, including stroke, spinal cord injury, intracerebral hemorrhage, and traumatic brain injury. Recovery is associated with neural plasticity in spared motor networks in the brain and spinal cord. Moreover, two initial studies and a recently completed Phase 3 clinical trial using a commercially available device demonstrates that paired VNS with rehabilitation is safe and improves motor recovery after stroke. The purpose of this study is to extend these findings and evaluate whether VNS delivered with the new device paired with rehabilitation represents a safe and feasible strategy to improve recovery of motor and sensory function in participants with stroke.
Stroke is the leading cause of severe acquired disabilities in adults. It can affect sensory and motor functions which are closely entangled. Among them, upper limb function is often strongly impaired. In this study the investigators are interested in the eventuality to improve motor recovery by the mean of stimulating the proprioception. Proprioception can be stimulated by tendinous vibrations in order to act on the neuromuscular system through the vibratory tonic reflex and by movement illusion. Stimulation by tendinous vibrations, applied to the musculotendinous endings, has been already proposed in post stroke rehabilitation, but only at late stages. Thus the aim of our study is to observe the effects of repeated tendon vibrations, applied in the early post stroke phase, the effect being measured on the excitability of the motor cortex by the Motor Evoked Potentials and on the motor recovery (motor control and activities).
Among the 795,000 individuals who sustain a stroke annually in the United States, 65% continue to experience moderate-to-severe impairments in one hand six months or more, which limits their ability to perform daily tasks. Currently there is dearth of understanding of the mechanisms of motor recovery after stroke. Understanding the mechanisms can potentially lead to the development of interventions to improve motor performance after stroke. The proposed study will examine how synchronously pairing brain and hand stimulation repeatedly affects the plasticity of the brain and motor performance after stroke. The knowledge gained from this study can be useful to develop interventions to improve hand movement after moderate-severe stroke.
Texas Biomedical Device Center at UT Dallas has developed an innovative strategy to enhance recovery of motor and sensory function after neurological injury termed targeted plasticity therapy (TPT). This technique uses brief pulses of vagus nerve stimulation to engage pro-plasticity neuromodulatory circuits during rehabilitation exercises. Recovery is associated with neural plasticity in spared motor networks in the brain and spinal cord. Moreover, an early feasibility study and an independent, double-blind, placebo-controlled study in chronic stroke participants indicate that VNS is safe in participants with upper limb deficits, and yields a clinically-significant three-fold increase in neural connections during rehabilitation exercises. Given the track record of safety and potential for VNS to enhance recovery of upper limb motor function in spinal cord injured individuals, the purpose of this double blind randomized placebo controlled optional open-label extension study is to assess the safety of using a new device to deliver vagus nerve stimulation to reduce symptom severity in participants with SCI. Additionally, the study will assess the prospective benefit of the system and garner an initial estimate of efficacy for a subsequent trial. Participants may undergo additional sessions of training with VNS.