Active clinical trials for "Wounds and Injuries"

The objective of this study is to evaluate the efficacy and safety of MaxioCel vs Aquacel Extra in the management of exuding ulcers/wounds over a period of 4 weeks

This study will examine the relationship between circulating irisin and bone health individuals with spinal cord injury. Additionally, this study seeks to examine the influence of muscle fiber type on circulating irisin and identify an exercise-based means to increase irisin concentrations.

Hand motor and sensory impairments resulting from neurological disorders or injuries affect more than 50 million individuals worldwide. Conditions such as stroke, spinal cord injury (SCI), and traumatic brain injury (TBI) can cause long-term hand impairments, greatly impacting daily activities and social integration. Since traditional physiotherapy has limited effectiveness in rehabilitation, assistive devices helping in performing in daily activities have emerged as a necessary solution. Soft exoskeletons offer advantages as they are more comfortable and adaptable for the user, but they often struggle to generate sufficient force. On the other hand, electrical stimulation garments, like e-sleeves, show promise by stimulating nerves and muscles in the forearm. However, achieving precise and stable movement control remains challenging due to difficulties in electrode placement for targeted stimulation. Furthermore, none of the currently available devices are capable of artificially restoring lost sensation in users' hands, limiting their ability to manipulate with fragile objects. Recognizing these limitations, our study proposes a solution that combines a standard hand soft exoskeleton with: (i) electrical stimulation to the fingers' flexor and extensor muscles to generate artificial muscle contractions synchronized with the exoskeleton motion, compensating for the lack of gripping force, and (ii) electrical stimulation to the nerves to artificially restore the lost sensation of touch, enabling users to receive feedback on the force they are applying when interacting with the environment. The investigators refer to this proposed combination as Sensible-Exo. To achieve this goal, our project aims to evaluate the functional improvements in assistive and rehabilitative scenarios using SensoExo in comparison to use only the exoskeleton or having no support at all. The exoskeleton will be coupled with an electrical stimulating sleeve capable of delivering non-invasive electrical stimulation in the form of Functional Electrical Stimulation (FES) and Transcutaneous Electrical Nerve Stimulation (TENS). A glove with embedded force and bending sensors will be used to modulate the electrical stimulation. Additionally, apart from studying the enhancement of functional tasks, the investigators will explore improvements in body perception, representation, and multi-sensory integration. Indeed, the investigators also aim at identifying the way patients perceive their body by means of ad-hoc virtual reality assessments that has been developed. Before each assessment patient will perform some predefined movement in virtual reality to familiarize with it and increase embodiment. During the study, participants will perform a range of tasks based on their residual abilities, including motor tasks (e.g., grab and release, Toronto Rehabilitation Institute Hand Function Test, grip force regulation test, virtual egg test), cognitive tasks (dual tasks), and assessments of body representation and perception. Some of these tasks will be conducted in Virtual Reality environments, both with and without active stimulation.

The aim of this study is to eliminate the malodorous of chronic wound and increase the chance of the healing of recalcitrant wounds by using the repairing gel (supraz gel) which has the approved components in wound healing and platelet-rich plasma-fibrin glue.

Investigators plan to offer two evidence based interventions - Trauma Focused Cognitive Behavioral Therapy (CBT) (TF-CBT) and Trauma Systems therapy (TST) to traumatized children and their families. The investigators are looking to evaluate the effectiveness of these interventions in the context of additional stress related to racialized trauma and acculturation stress

A Single site (Shirley Ryan AbilityLab) Randomized, Double-Blind, Placebo-Controlled Phase 1b/2a Study of NVG-291 in Spinal Cord Injury Subjects

The purpose of this innovative adaptive phase II trial design is to determine the optimal combination of hyperbaric oxygen treatment parameters that is most likely to demonstrate improvement in the outcome of severe TBI patients in a subsequent phase III trial.

This study is to evaluate the use of a fully implanted device for providing hand function, reach, and trunk function to individuals with cervical spinal cord injury. Funding Sources: FDA OOPD NIH NINDS

The recent introduction of robotics for locomotor training in paraplegic patients, and in particular the use of anthropomorphic exoskeletons, has opened new frontiers in rehabilitation. Existing literature, though encouraging, is still scarce and studies demonstrating efficacy are highly heterogeneous and have a small sample size. Evidence is also needed about cortical plasticity after SCI, in conjunction with the use of innovative rehabilitation devices, through indicators like neurophysiological and neuroradiological markers, as the knowledge of such mechanisms is crucial to improve clinical outcomes. Cortical circuits controlling prosthetic devices are different from those controlling normal parts of the body and remodeling mechanisms following prosthetic use have been documented, but in conditions other than SCI. The aims of this randomized controlled trial, with a 2-arm parallel-group design, are: to evaluate and quantify the efficacy of locomotor rehabilitation with a robotic anthropomorphic exoskeleton (EKSO-GT) in terms of clinical and functional outcomes, and the persistence of such efficacy; to investigate the presence and persistence of brain neuronal plasticity and cortical remodeling mechanisms underlying the robotic rehabilitation approach. Fifty patients will be recruited and randomly assigned to 2 treatment arms. Both groups will follow a program of standard locomotor rehabilitation for 8 weeks. One group will also undergo an overground locomotor training with the EKSO-GT during the first 4 weeks.

This study will evaluate the safety and efficacy of PEG 3350 for use in nerve repair.