View clinical trials related to Peripheral Nerve Injuries.
Filter by:Peripheral nerve injury is common and can result in loss of sensation and motor function, reduced quality of life, and prolonged time to return to work. Maladaptive cortical reorganization occurs after nerve injury or immobilization and can further impair the recovery process. To improve the sensorimotor prognosis of people with peripheral nerve injury, methods such as mirror therapy, motor imagery, and electrical stimulation have been used in addition to usual care. However, no studies have shown the effect of integrating mirror therapy, motor imagery, and electrical stimulation in these individuals. Furthermore, the real-time effect of mirror therapy on cortical activation in this population remains unexplored. This study aims to determine the real-time cortical modulation effects of mirror therapy combined with electrical stimulation in individuals with peripheral nerve injury.
The goal of this trial is to evaluate the effects of mirror therapy combined with contralaterally controlled functional electrical stimulation on motor recovery and neuroplasticity in patients with peripheral nerve injury. The main questions it aims to answer are Question 1: To compare corticomuscular coherence between the groups of mirror therapy combined with contralaterally controlled functional electrical stimulation, sham mirror therapy combined with contralaterally controlled functional electrical stimulation, and control group. Question 2: To compare sensorimotor recovery between the groups of mirror therapy combined with contralaterally controlled functional electrical stimulation, sham mirror therapy combined with contralaterally controlled functional electrical stimulation, and control group. Question 3: To evaluate the effects of each intervention on corticomuscular coherence and sensorimotor recovery 12 weeks post-intervention. Participants will be asked to exercise their affected hand together with the unaffected hand while receiving contralaterally controlled electrical stimulation in front of the mirror or sham mirror. Researchers will compare the effects of mirror therapy combined with contralaterally controlled functional electrical stimulation on corticomuscular coherence and sensorimotor recovery with the other groups.
In this clinical trial, participants with nerve pain after shingles or nerve injury will receive injections with NT 201 or placebo. The purpose is to measure the decrease of nerve pain with NT 201 compared to placebo. Trial details include: - Trial duration: 22-23 weeks; - Treatment duration: 1 injection visit with a 20-week follow-up period; - Visit frequency: 2 remote visits by phone/video call (1 week and 12 weeks after the injection); 2 on-site visits (6 weeks and 20 weeks after the injection).
Over the last years a rising medical need for treatment of chronic pain was identified. Based on previous findings indicating the pain modulating effects of cannabinoids in chronic pain disorders, this clinical trial investigates the long term efficacy and tolerability of the THC-focused nano endocannabinoid system modulator AP707 in patients with chronic pain disorders due to traumatic or post-operative peripheral neuropathy. Patients receive AP707 or placebo over the course of 14 weeks as an add-on to the standard of care. Changes in pain intensity, quality of life and sleep and others measures are monitored through different scales to assess the efficacy of AP707 in patients with chronic pain due to traumatic or post-operative peripheral neuropathy.
Over the last years a rising medical need for treatment of chronic pain was identified. Based on previous findings indicating the pain modulating effects of cannabinoids in chronic pain disorders, this clinical trial investigates the efficacy and tolerability of the THC-focused nano endocannabinoid system modulator AP707 in patients with chronic pain disorders due to traumatic or post-operative peripheral neuropathy. Patients receive AP707 or placebo over the course of 14 weeks as an add-on to the standard of care. Changes in pain intensity, quality of life and sleep and others measures are monitored through different scales to assess the efficacy of AP707 in patients with chronic pain due to traumatic or post-operative peripheral neuropathy.
This study is evaluating a new therapeutic use of electrical stimulation to promote nerve healing and improve functional recovery following surgical intervention for peripheral nerve injury in arm. Participants will be randomized into one of two groups, treatment or control, with all participants receiving standard of care treatment for the nerve injury. The treatment group will also receive a single dose of the therapeutic stimulation during the surgical intervention for their nerve injury.
The good effects of using guided plasticity for a rehabilitative purpose in case of nerve damage have been shown, but a problem that has been presented is that some individuals find it difficult to assimilate these effects due to difficulties in carrying out abstract training or due to a lack of motivation. In early sensory training, the plasticity of the brain is used. Methods for early sensory training that have been described are: 1) mental imagery of touch (mental imagery), 2) observation of touch, 3) mirror training, 4) use of images for visualization of touch. The method needs to be developed and refined to be able to offer individual training plans in order to find a motivating and meaningful form of training.
The primary purpose of this research study is to evaluate the safety and possible harms of injecting one's own Schwann cells along with nerve auto-graft after a severe injury to a major nerve has occurred.
The goal of this study is to determine which parts of the brain make it possible for some people to move skillfully with their left non-dominant hand.
Virtual reality creates interactive, multimodal sensory stimuli that have demonstrated considerable success in reducing pain. Much research so far has focused on VR's ability to shift patients' attention away from pain; however, these methods provide only transient relief through means of distraction and therefore do not offer long-term analgesic remediation. An alternative and promising approach is to utilize VR as an embodied simulation technique, where virtual body illusions are employed as tools to improve body perception and produce potentially more enduring analgesia. Disturbances in body perception (i.e., alterations in the way the body is perceived) are increasingly acknowledged as a pertinent feature of chronic pain, and include aberrations in perceived shape, size, or color that differ from objective assessment. The degree of body perception distortion positively correlates with pain, and prior interventions have evinced that treatments aimed at reducing body perception distortions correspondingly ameliorate pain. Several recent experimental research studies have demonstrated the analgesic efficacy of body illusions in a range of pain conditions. Immersive VR multisensory feedback training signifies a promising new avenue for the potential treatment of chronic pain by supporting the design of targeted virtual environments to alter (distorted) body perceptions. Various illusions have been described to alter pain perception; however, they. Have not been directly compared to each other. The multimodal stimulus control of VR enables physical-to-virtual body transfer illusions, resulting in the feeling that the virtual body is one's own. These virtual body illusions can modulate body perception with ease and could therefore be used to alter the perceived properties of pain, consequently utilizing a virtual avatar to specifically shape interactive processing between central and peripheral mechanisms.