Active clinical trials for "Wounds and Injuries"

The primary purpose of the clinical study is to evaluate the clinical efficacy of intracranial administration of SB623 cells on patients with chronic motor deficit from Traumatic Brain Injury. A secondary purpose of the study is 1) to evaluate the effect of intracranial administration of SB623 cells on disability parameters and 2) to evaluate the safety and tolerability of intracranial administration of SB623 cells. Patients with stable, chronic motor deficits secondary to focal traumatic brain injury must be 12 months post TBI.

The conventional treatment of spinal cord injury (SCI) includes physical therapy and rehabilitation and in some cases may require surgical intervention. Although improved emergency care and aggressive treatment can help in preventing further damage and even restore minimal sensory functions, still a large proportion of patients suffer with prolonged disabilities. It led neurologists to search out for new treatment options for this otherwise debilitating disorder. Recent advances in research have developed a better understanding of stem cell biology especially their role in tissue repair and regeneration. Encouraging results in pre-clinical phase and limited human trials have proved that stem cells can be safely and effectively delivered to the injured site for regeneration of damaged tissue. Although a variety of cell types have been tried for their role in repair of spinal cord injury, majority of clinical trials employed stem cells taken from bone marrow especially mesenchymal stromal cells (MSC). Bone marrow MSCs are a good choice for regenerative therapies owing to advantages like ease of collection and ex-vivo culturing, immune tolerance and their ability to differentiate into a variety of cell types including neuronal lineage cells. Intravenous application or direct injection of MSCs into cerebrospinal fluid (CSF) via lumber puncture in animal models of SCI and brain trauma had shown that MSCs can migrate towards and integrate into injured spinal tissue and reduce cyst size and increase functional recovery. The literature indicates that acute, sub-acute and chronic injury can be a therapeutic target for MSC grafting. The mechanism of action may however vary among these conditions. In acute phase, MSC administration play anti-inflammatory role, while in sub-acute/chronic setting it may be used as neurostimulator and for cell bridging effect and possibly glial or neuronal cell replacement. The investigators propose a non-randomized, single group, open label, phase-I, interventional study to evaluate the safety and efficacy of intrathecal delivery of patient's own (autologous) bone marrow mesenchymal stem cells for treatment of spinal cord injury. This will include determination of functional recovery (neuro-muscular control and sensation) in the affected area and overall improvement in quality of life of the patients and also take into account any side effects, if observed.

Prospective study to evaluate the additive value of codeine on ibuprofen in the management of pediatric patient with a trauma of a limb.

The primary purpose of this study is to assess the effectiveness of once daily application of a diclofenac sodium topical patch in reducing mild to moderate soft tissue injuries when applied to the painful area.

The purpose of this study is to compare how well two methods (VAC and G-SUC) of securing skin grafts using negative pressure wound therapy work. Negative pressure wound therapy is a commonly used method of applying suction on wounds to remove fluid from wound and to promote healing. The VAC system is widely used and consists of a foam dressing and a portable computerized suction pump. The G-SUC method uses commonly available dressing supplies attached to vacuum (suction) pump located on the wall above a hospital bed. The investigators have frequently used both methods over the past 10 years and have not observed any specific negative side effects of either.

Traumatic brain injury (TBI) is a major cause of death and disability, with an estimated cost of 45 billion dollars a year in the United States alone. Every year, approximately 1.4 million sustain a TBI, of which 50,000 people die, and another 235,000 are hospitalized and survive the injury. As a result, 80,000-90,000 people experience permanent disability associated with TBI. This project is designed to determine whether a device designed to measure brain tissue oxygenation and thus detect brain ischemia while it is still potentially treatable shows promise in reducing the duration of brain ischemia, and to obtain information required to conduct a definitive clinical trial of efficacy. A recently approved device makes it feasible to directly and continuously monitor the partial pressure of oxygen in brain tissue (pBrO2). Several observational studies indicate that episodes of low pBrO2 are common and are associated with a poor outcome, and that medical interventions are effective in improving pBrO2 in clinical practice. However, as there have been no randomized controlled trials carried out to determine whether pBrO2 monitoring results in improved outcome after severe TBI, use of this technology has not so far been widely adopted in neurosurgical intensive care units (ICUs). This study is the first randomized, controlled clinical trial of pBrO2 monitoring, and is designed to obtain data required for a definitive phase III study, such as efficacy of physiologic maneuvers aimed at treating pBrO2, and feasibility of standardizing a complex intensive care unit management protocol across multiple clinical sites. Patients with severe TBI will be monitored with Intracranial pressure monitoring (ICP) and pBrO2 monitoring, and will be randomized to therapy based on ICP along (control group) or therapy based on ICP in addition to pBrO2 values (treatment group). 182 participants will be enrolled at four clinical sites, the University of Texas Southwestern Medical Center/Parkland Memorial Hospital, the University of Washington/Harborview Medical Center, the University of Miami/Jackson Memorial Hospital, and the University of Pennsylvania/Hospital of the University of Pennsylvania. Functional outcome will be assessed at 6-months after injury.

Intradialytic hypotension (IH) is a major complication during acute hemodialysis. The aim of this study was to evaluate the effects of dialysate temperature (DT) reduction with Na and ultrafiltration (UF) profiling on hemodynamics of critically ill acute kidney injury (AKI) patients submitted to sustained low-efficiency dialysis (SLED).

The purpose of this study is to determine whether a bioelectric wound dressing, a silver-coated dressing, or a silver-foam dressing are effective in the treatment of wounds resulting from curettage and electrodesiccation of skin lesions.

Traumatic brain injury (TBI) is a leading cause of death and long term disability, particularly in young adults. Studies from Australia have shown that approximately half of those with severe traumatic brain injury will be severely disabled or dead 6 months post injury. Given the young age of many patients with severe TBI and the long term prevalence of major disability, the economic and more importantly the social cost to the community is very high. Pre-hospital and hospital management of patients with severe brain injury focuses on prevention of additional injury due primarily to lack of oxygen and insufficient blood pressure. This includes optimising sedation and ventilation, maintaining the fluid balance and draining Cerebrospinal Fluid (CSF) and performing surgery where appropriate. In recent years there has been a research focus on specific pharmacologic interventions, however, to date, there has been no treatment that has been associated with improvement of neurological outcomes. One treatment that shows promise is the application of hypothermia (cooling). This treatment is commonly used in Australia to decrease brain injury in patients with brain injury following out-of-hospital cardiac arrest. Cooling is thought to protect the brain using a number of mechanisms. There have been a number of animal studies that have looked at how cooling is protective and also some clinical research that suggests some benefit. However at the current time there is insufficient evidence to provide enough proof that cooling should be used routinely for patients with brain injury and like all treatments there can be some risks and side effects. The POLAR trial has been developed to investigate whether early cooling of patients with severe traumatic brain injury is associated with better outcomes. It is a randomised controlled trial, which is a type of trial that provides the highest quality of evidence. The null hypothesis is that there is no difference in the proportion of favourable neurological outcomes six months after severe traumatic brain injury in patients treated with early and sustained hypothermia, compared to standard normothermic management.

The purpose of the study is to assess and compare the safety and efficacy of the allogeneic-unrelated umbilical cord blood-derived mesenchymal stem cell product (Cartistem®) to that of a microfracture treatment in patients with articular cartilage defect or injury.