Active clinical trials for "Wounds and Injuries"

Blood flow restriction (BFR) therapy is a brief and partial restriction of venous outflow of an extremity during low load resistance exercises. It is a safe and effective method of improving strength in healthy and active individuals, recovering from orthopedic pathologies and procedures. This prospective, randomized study will look at the implications this form of treatment has on the rehabilitation of Achilles injuries.

The E-TIPS trial will evaluate an evidence-based, telehealth pain self-management intervention compared to standard care (a waitlist) for chronic pain in adults with physical disabilities who are employed. Participants from anywhere in the US will be randomized to either E-TIPS, a cognitive-behavioral pain self-management intervention delivered by telephone, or a waitlist control. Outcomes, including pain interference, will be assessed at baseline, mid-treatment, post-treatment, and 6-month follow up.

The purpose of this small, research study is to examine effectiveness of an at-home application of an experimental intervention, on thinking and memory in mild-moderate, closed-head, traumatic brain injury cases. The experimental intervention is light-emitting diode (LED) therapy, which is applied to the scalp and through the nose using a head frame device. Participants are expected to complete two, 5-week series of LED treatments, at home, 3 times a week. There will be a 1-month period between the two series. Each home treatment is 20 minutes. Participants will be trained to use the head frame device, in-office. The head frame device falls within the FDA category General Wellness, low-risk devices, and no medical claims are made. A two-hour paper and pencil testing (4 visits) and a one-hour MRI (3 visits) will be administered before and after each treatment series. Participants may be in the study for about 4 months. This study is supported by Vielight, Inc., Hayward, CA/ Toronto, Canada

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.

The aim of this study is to determine the effects of rehabilitation on dexterous hand movements and cortical motor map changes in tetraplegic patients following nerve transfer surgery. The working hypothesis is that robot-assisted, intensive rehabilitation will support the return of hand and arm function and strengthen the cortical representations of targeted muscles. The investigators will assess this through TMS mapping and clinical measures of hand and arm function.

This was a prospective, multicentric, randomized, double blind, parallel, saline controlled Phase II clinical study to compare the safety and efficacy of PMZ-1620 (INN: Sovateltide) therapy along with standard supportive care in patients of acute spinal cord injury.

Neuropathic pain is a common complication following spinal cord injury (SCI) that significantly decreases quality of life. Treatment options are limited, and current treatments can have significant side effects. Those with SCI have identified a need for additional treatment options, particularly those that are not medications. Nabilone and an anti-inflammatory diet are two treatments that may provide pain relief while being better tolerated. This study will evaluate the benefits of these treatments for neuropathic pain after SCI. Study participants will receive either an anti-inflammatory diet or a placebo diet, and nabilone or a placebo for 4 weeks. It is expected that an anti-inflammatory diet and nabilone will significantly decrease pain intensity and improve function. The combination of both treatments together is expected to have a greater effect than each alone.

Acquired Brain Injury (TBI) is a serious medical and health problem in the US. Individuals with an acquired brain injury due to stroke and Traumatic Brain Injury (TBI) commonly suffer from upper extremity physical impairments that persist even after years of injury; these deficits are attributed to the damage to brain structure and changes in structural and functional connectivity. Although the conventional rehabilitation approaches are helpful in assisting motor recovery often there is a complaint of fatigue due to the repetitive tasks and also, nearly half of the ABI survivors do not regain their ability to use their arms for daily activities. To address this issue, Dr. Shenoy's proposed study will investigate the combined use of individually targeted non-invasive brain stimulation and music-assisted video game-based hand exercises to achieve functional recovery. Further, the project will also investigate how the intervention modulates brain activity (recorded using EEG) in terms of brain connectivity before- and after the -intervention. In the end, this study will allow us to understand the cortical dynamics of ABI rehabilitation upon brain stimulation. Extending further, this could pave the way to advance the knowledge of behavioral and neural aspects of motor control in patients with different types of neuromuscular disorders.

Blood flow through the brain is reduced after brain damage. Secondary brain ischemia caused by hypoxia and hypotension, further increase the susceptibility of the ischemically compromised brain to secondary impairment during this period. In order to determine whether and to what extent blockage of the stellate ganglion (BSG) affects the blood flow to the injured brain, the investigators will measure the variables of brain blood flow before and after BSG using computed tomography angiography (CTA), trans-cranial Doppler ultrasound (TCD), intracranial pressure (ICP) and perfusion computed tomography (PCT) of the brain. At the same time, the investigators would like to evaluate whether and to what extent BSG affects the aseptic inflammatory brain injury response and the biochemical indicators of brain damage in patients with moderate and severe brain injury.

Locomotor training is an established rehabilitation approach that is beneficial for improving walking function in individuals with spinal cord injuries (SCIs). This approach focuses on repetitive practice and appropriate stepping movements to activate spinal neural networks and promote rhythmic motor output associated with walking. Assistance with stepping movements is often provided by physical therapists and trainers, but this can be costly and difficult to deliver in the cost-constrained U.S. healthcare market. Robotic devices have been used as an alternate method to deliver locomotor training, but current robotic approaches often lack the natural movement variations that characterize normal human stepping. Furthermore, studies to compare locomotor training approaches have not shown any specific benefits of using robotic devices. A new type of robotic device has emerged that uses an individual's muscle activation and stepping movements to control the robot during walking. This adaptive robotic device adjusts to the user's intentions and can assist with stepping during locomotor training in a manner that matches natural human stepping. While this type of adaptive robot has been preliminarily tested, the safety and efficacy of locomotor training using adaptive robotics are not well-established in patients with SCI. This is a critical step to determine if individuals with SCI may benefit from use of this device and for preliminary adoption of this technology. Recent studies have used the Cyberdyne Hybrid Assistive Limb (HAL) to deliver locomotor training and have reported outcomes suggesting that the HAL adaptive robot is safe and efficacious for walking rehabilitation in European SCI patients. Therefore this study will use the HAL adaptive robot to deliver locomotor training. This research is necessary to determine if use of the HAL is potentially beneficial and warranted for use with locomotor training and SCI patients receiving care in the U.S. Results of this study may contribute to the development and implementation of effective walking rehabilitation approaches for people with SCIs.