Active clinical trials for "Wounds and Injuries"

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.

Traumatic injuries of peripheral arteries are often associated with multiple injuries, massive hemorrhage, state of shock, and loss of blood supply, as well as with high mortality. Traditionally, an open surgical approach is suggested for the management of artery injury. With the advancement of endovascular techniques, the traditional open vascular exposure and vessel repair are no longer the only option available. The purpose of this study is to compare the effectiveness, long-term safety and explore the safety and efficacy factors between open and endovascular surgical techniques.

Spinal cord injuries are anatomically mostly incomplete, showing tissue bridges of the spinal cord at the injury site. Of the 60% functionally incomplete patients, about half face a life in the wheelchair. Besides conventional rehabilitation, no prominsing further treatment options exist. One of the most plastic systems involved in locomotion is the pontomedullary reticulospinal tract, which is the oldest locomotor command system existing in most vertebrates, including primates. Muscle activation patterns for limb movements are programmed in the spinal cord and have to be activated and coordinated through commands from the so called mesencephalic locomotor region (MLR). The MLR consists of nerve cells in the lower mesencephalic tegmentum sending uni- and bilateral signals through the medullary reticulospinal tracts. Classical physiological studies showed that electrical stimulation of the MLR induce locomotion. For the first time this approach was transferred and recently published in a model of induced incomplete spinal cord injury by the Schwab group. Rats severly impaired in motor hindlimb control with only 10-20% spared white matter, recovered with fully functional weight bearing locomotion under MLR deep brain stimulation (DBS). Even rats with only 2-10% spared white matter regained weight supporting stepping. DBS is a clinical standard treatment option in patients with movement disorders but does not relieve all symptoms. Therefore, small studies of MLR stimulations have been safely used in Parkinsonian patients showing freezing of gait and frequent falls with variable results. In a translational approach, we aim at performing a multidisciplinary phase one clinical trial with 5 patients and incomplete spinal cord injury. With the means of our established universitary setup for DBS treatments the operations will be performed unilaterally under local anaesthesia in the Division of Neurosurgery, USZ, with perioperative electrophysiological recordings, clinical assessments and gait analysis under test stimulation in the Spinal Cord Injury Center Balgrist.

This study aims to improve continence and voiding of patients with spinal cord injury using electrical stimulation. The Finetech Vocare Bladder System is an implantable sacral nerve stimulator for improving bladder and bowel function in patients with spinal cord injury (SCI). It has been commercially available in Britain and other countries since 1982, and has been used in thousands of patients with SCI to improve bladder, bowel and sexual function. It received FDA approval in 1998 under Humanitarian Device Exemption H980005 and H980008 for providing urination on demand and to aid in bowel evacuation. Electrical stimulation to produce bladder contraction and improve bladder voiding after spinal cord injury has usually been combined with cutting of sensory nerves to reduce reflex contraction of the bladder, which improves continence. However, cutting these nerves has undesirable side effects. This study will not cut any sensory nerve. This study is testing the use of the stimulator for inhibiting bladder contraction by stimulating sensory nerves to improve continence after spinal cord injury, and for blocking sphincter contraction to improve voiding.

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

The aim of this clinical trial is to assess the efficacy of tesamorelin as a therapy for peripheral nerve injuries. The investigators hypothesize that treatment with tesamorelin will allow for faster and greater recovery of motor and sensory function following surgical repair of injured peripheral nerves. Patients with upper extremity nerve injuries will be randomly assigned to receive either the drug or a placebo (inactive drug). A number of tests for nerve regeneration, muscle function and sensation will be performed every month for a total of 12 months. Outcomes in the patients treated with tesamorelin will be compared to outcomes in patients who received the placebo to determine the effectiveness of tesamorelin as a therapy for nerve injuries.

Most trauma deaths are related to traumatic brain injury (TBI). Although the management of patients has improved, mortality remains unacceptably high, and half of survivors of moderate and severe TBI are left with major functional impairment. Current management guidelines are based on limited evidence and practice is highly variable. Most acutely ill patients with TBI will develop anemia, which may decrease oxygen delivery to a fragile brain. While clinical practice is moving towards transfusing at low hemoglobin (Hb) levels, experts have expressed concerns regarding restrictive strategies, which may adversely affect clinical outcomes in TBI. Our primary objective is to evaluate the effect of red blood cell (RBC) transfusion thresholds on neurological functional outcome. We hypothesize that a liberal transfusion strategy improves outcomes compared to a restrictive strategy.

The overall objective of this project is to investigate the effectiveness of daily acute intermittent hypoxia therapy (dAIH), coupled with massed practice training, to improve upper-extremity function in individuals with chronic incomplete cervical SCI.

The main objective of this project is to analyze whether EMDR therapy, as an adjuvant to usual treatment, is effective in reducing post-traumatic stress and psychotic/affective symptoms in patients with a FEP and comorbid psychological trauma associated with first hospital admission and / or previous stressful life event.

Anterior cruciate ligament (ACL) injuries are extremely common. On average, 50% of individuals suffering an ACL injury will develop radiographic osteoarthritis (OA) 10 to 20 years after injury. Unfortunately, ACL reconstruction does not prevent risk of future OA. Interleukin-1 (IL-1) levels in the human knee joint increase transiently after an ACL injury. In animal experiments, if interleukin-1 levels are increased in the joint, this alone causes arthritis to occur. Interleukin-1 receptor antagonist (IL-1Ra) is a naturally occurring inhibitor of IL-1. However, in ACL injuries the balance of these two proteins is disturbed transiently after injury, with the effects of IL-1 dominating this balance. In a large animal model of ACL injury, injection of IL-1Ra into the knee joint after ACL injury significantly decreased the amount of arthritis that was later observed. Thus, the investigators hypothesize that early injection of IL-1 inhibitor (IL-1Ra) into the knee joint of patients suffering recent ACL injury will decrease the incidence of cartilage damage later in life. After appropriate IRB approval, a total of 32 active patients will be randomized into one of two treatment groups. Group 1 will receive removal of the knee joint fluid (aspiration of hemarthrosis) using a needle and syringe within 1 to 2 weeks of injury. Following aspiration of the knee joint, an injection of 5 milliliters (mls) of sterile saline (as a placebo control) will be administered. In addition, a second knee aspiration procedure and an injection of 5mls of sterile saline into the injured knee joint will be performed at 3 to 5 days after the initial injection. Group 2 will receive aspiration of the knee hemarthrosis as described in group 1 as well as intra-articular administration of 150mg (~5mls) of anakinra (rhIL-1Ra) within 1 to 2 weeks of ACL injury. In addition, a second knee aspiration and intra-articular administration of 150mg (~5mls) of anakinra (rhIL-1Ra) will be performed at 3 to 5 days after the initial injection. Thus, all patients in this randomized placebo-controlled trial will undergo two injection procedures prior to surgery. Investigators will analyze subjects self-reported function and pain scores as well as urinary levels of cartilage breakdown products over time. Additionally, MRI studies will be used to compare MRI findings among patients in these 2 treatment groups. Urine samples will be obtain prior to surgery, at the time of surgery and at multiple time points after surgery (3, 6, 9, 12 and 24 months after surgery). Subjective outcome measure assessments (surveys) will be completed by participants prior to surgery and then again at 6, 9, 12 and 24 months post-operatively. MRI studies will be obtained at 1 year and 2 years following surgery. Additional, MRI studies at time points are optional and highly encouraged. These additional MRIs are at no cost to the patient.