Active clinical trials for "Wounds and Injuries"

A phase I/II clinical trial (first in human) to assess the effectiveness and safety of the treatment of cartilage injury with a tissue engineering construct composed of stromal vascular fraction collected from the synovial membrane and infrapatellar fat of the injured knee, submitted to enzymatic processing in a single surgical time, associated with a collagen scaffold. The primary outcomes will be assessed by 3T magnetic resonance imaging, quality of life and knee function questionnaires, in addition to perioperative and post-operative complications. Secondary outcomes will be evaluated by measuring the health resources used to ensure compatibility, reproducibility and generalizability of the technique. The authors believe that adverse events will be similar to current surgical procedures and that there will be an improvement in knee function scores and quality of life of patients undergoing the procedure.

The goal of this observational study is to gain insight in the natural course of pro-inflammatory factors and hemarthrosis in patients older than 18 with a recent knee trauma. The main question[s] it aims to answer are: What is the natural course of pro-inflammatory factors and hemarthrosis in knee trauma? What are the effects of inflammation and hemarthrosis on the anti-inflammatory potential of ASC's in order to better determine eligible patients and circumstances for ASC's therapy? Participants will: undergo blood withdrawal undergo knee arthrocentesis for synovial fluid sample collection physical examination fill out a questionnaire on knee complaints

The aim of this post market clinical follow up (PMCF) study is to confirm the performance of Suprasorb® A + Ag wound dressing and rope, to collect safety data regarding expected adverse events and to detect potential unexpected adverse events associated with use of Suprasorb® A + Ag wound dressing and rope within the certified indications and under the conditions of routine use.

The goal of this observational study is to explore the impact of a resiliency and trauma informed care educational intervention for Psychiatric Mental Health Nurse Practitioner (PMHNP) students at the University of Arizona College of Nursing during the final, clinical year of the program. Specifically, the investigators will examine if the educational intervention is feasible, acceptable and helpful to students, and can decrease burnout and increase resiliency.

The purpose of this study is to improve the ability of the investigators to monitor brain health in newborn babies at risk of brain injuries. The researchers will be using an investigational system of devices to non-invasively (that, is, without penetrating the skin), measure the amount of oxygen going to and being used by the brain. They will be taking some bedside research measurements during the babies' stay at the hospital. With these measurements, the intention is to study the role of oxygen in brain injury and test the efficacy of the research device and its potential as a permanent bedside diagnostic device.

Extremely low birth weight (ELBW), birth weight less than or equal to 1000 g, infants are at high risk for developing brain injury in the first week of life. Intraventricular hemorrhage (IVH) and periventricular leukomalacia (PVL) are the most common injuries in this group of infants. Their incidence is inversely proportional to gestational age (GA) and birth weight (BW). These lesions are associated with neurodevelopmental delay, poor cognitive performance, visual and hearing impairment, epilepsy, and cerebral palsy; and instability of systemic hemodynamics during transition from intra- to extra-uterine life and during the early neonatal period is believed to be at their genesis. While the incidence of ultrasound- diagnosed cystic PVL has decreased dramatically over the last 2 decades, diffuse PVL detected by magnetic resonance imaging (MRI) is still prevalent in survivors of neonatal intensive care. Moreover, PVL, even when non-cystic, is associated with decreased cortical complexity and brain volume and eventual neurocognitive impairment. Currently, clinicians lack the tools to detect changes in cerebral perfusion prior to irreversible injury. Unfortunately, the incidence of brain injury in ELBW infants has remained relatively stable. Once translated to the bedside, the goal of this research is to develop a monitoring system that will allow researchers to identify infants most at risk for IVH and PVL and in the future, intervention studies will be initiated to use the changes in cerebral perfusion to direct hemodynamic management. The purpose of this study is to first understand the physiology of brain injury and then to eventually impact the outcomes in this high-risk group of infants by assessing the ability of the diastolic closing margin (DCM), a non-invasive estimate of brain perfusion pressure, to predict hemorrhagic and ischemic brain injury in ELBW infants. The information collected for this study will help develop algorithms or monitoring plans that will maintain the appropriate brain perfusion pressure and thereby, prevent severe brain injury.

The purpose of this study is to evaluate a clinically and economically most effective diagnostic algorithm for prediction of post-traumatic complications in a multicenter sample of severe trauma patients.

This research is being done to determine if investigators can change skin from one type to another. Specifically, investigators are interested in making normal skin into the thicker skin found on our palms and soles.

The goal of this clinical trial is to test CRIS100 treatment in participants with acute thoracic spinal cord injury. The main questions it aims to answer are: safety of CRIS100 efficacy of CRIS100 Participants will receive 75 mcg CRIS100 in the epicenter of the spinal injury, within 72 hours of the trauma.

The investigators hope to develop a treatment for suicidal ideation (SI), impulsivity and functional impairments (such as difficulties in social and work settings) that occur after a mild traumatic brain injury (mTBI). These conditions have been shown to be linked. The investigators are using a high-powered magnetic pulse, called intermittent theta burst stimulation (iTBS) applied to the head to see if it can improve these symptoms. The high-powered magnetic pulse causes certain cells in the brain to activate, which seems to strengthen connections between parts of the brain. The purpose of this research is to gather early information on the safety and effectiveness of iTBS provided to the front of the head for impulsivity, SI and functional deficits after mTBI. The investigators plan to use the data collected in this study to develop larger studies in the future. iTBS is FDA approved, but not for these specific symptoms, or in the specific location the investigators are placing it. The investigators are testing to see if its effective for the above conditions when applied to the front of the head.