View clinical trials related to Nerve Injury.
Filter by:The aim of this observational study is to answer the following questions in individuals with acute and chronic exposure to organophosphates. The main questions to be addressed are 1. What are the prognostic values of neuroinflammatory markers? 2. What are the genotoxic effects of organophosphates? 3. what are the changes occurring in the levels of traditional oxidative stress and inflammatory markers?
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.
A novel temporary peripheral nerve stimulation system that delivers a single dose of electrical stimulation therapy for 1 hour will be evaluated for safety and effectiveness.
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.
Chronic neuropathic pain is defined as pain caused by a lesion or disease of the somatosensory nervous system. It is highly prevalent, debilitating, and challenging to treat. Current available treatments have low efficacy, high side effect burden, and are prone to misuse and dependence. Emerging evidence suggests that the transition from acute to chronic neuropathic pain is associated with reorganization of central brain circuits involved in pain processing. Repetitive transcranial magnetic stimulation (rTMS) is a promising alternative treatment that uses focused magnetic pulses to non-invasively modulate brain activity, a strategy that can potentially circumvent the adverse effects of available treatments for pain. RTMS is FDA-approved for the treatment of major depressive disorder, obsessive-compulsive disorder, and migraine, and has been shown to reduce pain scores when applied to the contralateral motor cortex (M1). However, available studies of rTMS for chronic neuropathic pain typically show variable and often short-lived benefits, and many aspects of optimal treatment remain unknown, including ideal rTMS stimulation parameters, duration of treatment, and relationship to the underlying pain etiology. Here the investigators propose to evaluate the efficacy of high frequency rTMS to M1, the region with most evidence of benefit in chronic neuropathic pain, and to use functional magnetic resonance imaging (fMRI) to identify alternative rTMS targets for participants that do not respond to stimulation at M1. The central aim is to evaluate the pain relieving efficacy of multi-session high-frequency M1 TMS for pain. In secondary exploratory analyses, the investigator propose to investigate patient characteristic that are predictive of responsive to M1 rTMS and identify viable alternative stimulation targets in non-responders to M1 rTMS.
Evaluation of potential nerve damage after radial CAG/PCI.
The purpose of this open, multicenter trial is to assess the impact of a nerve regeneration conduit made of allogeneic artery or vein from umbilical cord lining on the regeneration of wrist nerve.
Sagittal split osteotomy (SSO) is a common operation done to move the mandible to correct dentofacial deformities and obstructive sleep apnea (OSA). Inferior alveolar nerve (IAN) injury and associated paresthesia is a well-known negative outcome following SSO, causing temporary or sometimes, permanent numbness in the chin and/or lip. There are limited methods to decrease the occurrence and duration of neurosensory dysfunction. Recent research has shown that platelet-rich fibrin (PRF) aids neurosensory recovery after SSO. Another method to minimize nerve injury is proximal segment grooving (PSG) to create space for the nerve to rest. This grooving method has never been formerly reported. The purpose of this study is to answer the following question: Among patients undergoing bilateral sagittal split osteotomy (BSSO) for dentofacial deformity or OSA, do those who receive PRF with or without PSG, compared to those who do not, have shorter times to functional sensory recovery (FSR) of the IAN? The null hypothesis is that there is no difference among 4 treatment groups and neurosensory outcomes. The specific aims of this proposal are to 1) enroll and randomize subjects who will undergo BSSO for correction of dentofacial deformity or OSA into 4 different treatment groups (PSG with PRF, PSG alone, PRF alone, neither PSG or PRF), 2) measure objective and subjective post-operative nerve function at fixed intervals post-operatively for up to 1 year, 3) compare differences in neurosensory outcomes among treatment groups, and 4) identify other variables that might be associated with differences in neurosensory outcomes.
This study is evaluating a new therapeutic use of electrical stimulation to promote nerve healing and improve functional recovery following surgical intervention for nerve compression. A single dose of the therapeutic stimulation is delivered as part of the surgical intervention to address compression of the ulnar nerve at the elbow.
Chronic pain affects 1 in 4 US adults, and many cases are resistant to almost any treatment. Deep brain stimulation (DBS) holds promise as a new option for patients suffering from treatment-resistant chronic pain, but traditional approaches target only brain regions involved in one aspect of the pain experience and provide continuous 24/7 brain stimulation which may lose effect over time. By developing new technology that targets multiple, complimentary brain regions in an adaptive fashion, the investigators will test a new therapy for chronic pain that has potential for better, more enduring analgesia.