View clinical trials related to Severe Traumatic Brain Injury.
Filter by:Tertiary lesions responsible of the neurological decline after severe traumatic brain injury (TBI) are partially due to a persistent neuro-inflammation directly modulated by inflammatory mediators during the acute phase and detectable by using both multimodal MRI imaging and biological biomarkers during the acute phase after traumatic brain injury. The main objective is to identify if the level of IL-1beta in cerebrospinal fluid predict in a reliable and reproducible way, the neuro-radiological evolution evaluated by the comparison of a quantitative MRI performed in post-resuscitation and at one year (quantitative ΔIRM) in traumatic brain injuried patients. The secondary objectives are: - To understand the links between the acute and chronic neuro-inflammatory phase in a population of TBI, - To explore the contribution of the adaptive immune response in the persistent activation of the immune response, - To Examine the links between persistent neuroinflammation, clinical deterioration and neuroimaging, - To establish a correlation between the pathology and the physio-pathology of TBI.
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.
The investigators plan to utilize conivaptan (Vaprisol) to promote isolated water loss, in combination with normal (physiologic) fluid replacement to maintain a normal blood volume status, in patients with severe TBI. The goal of this therapy is to raise blood sodium in a controlled fashion in subjects with severe TBI, and reduce the use of hypertonic saline infusion. We hypothesize that this therapy will maintain a stable state of high blood sodium, while decreasing the overall sodium load needed to achieve these goals.
When fever is present in patients with stroke, traumatic brain injury (TBI), or brain hemorrhage, it has been associated with worse outcomes including larger areas of tissue death, increased length of stay, worse degree of coma, lower ability to function, and higher mortality. Both adult and pediatric TBI national guidelines state that maintenance of normal body temperature should be a standard of care. However, no further standards or options are presented to specifically guide practice. The current ischemic stroke guidelines state that fever should be treated with fever-reducing agents and offer "cooling devices" as an option but do not provide specifics to guide practice. Over 50% of patients in the Neurosurgical Intensive Care Unit (ICU) at Harborview Medical Center develop fever during the course of their stay. With elevated temperatures the body consumes more oxygen than if the temperature was normal, causing less oxygen to be available to the brain. This may lead to injury of the brain cells and a diminished capacity for healing. Thus, temperature management in neurologically vulnerable patients is both a prevalent and problematic challenge. Based on this information the goal of the present proposal is to evaluate if 1) A standardized, step-wise approach to temperature management using a Normothermia Protocol is successful in achieving and maintaining normal temperature in Neurosurgical ICU patients; and 2) If maintenance of normal temperature will be associated with fewer episodes of diminished responsiveness in their neurological exams as evidenced by a measure of depth of coma, as measured by the Glasgow Coma Score (GCS) compared to a control group treated according to usual care.
The aim of the study is to evaluate the cortical excitability in the severe brain injured patients. We hypothesize that: 1. There is a continuous decrease in intracortical inhibition from healthy subjects to awake patients with severe brain injury, and to patients with impaired consciousness. 2. Decreased intracortical inhibition correlate with the degree of impairment assessed with the clinical scores in patients with severe brain injury.
The primary goal of this project is to demonstrate the feasibility and clinical benefits of a new rapid treatment for secondary treatment for secondary brain injury called Discrete Cerebral Hypothermia System by CoolSystems, Inc., Berkley, CA. This device induced hypothermia in the adult brain without significant whole body hypothermia. Discrete Cerebral Hypothermia System holds a great potential for protecting the brain from the devastating secondary complications of trauma without the associated deleterious system effects.
This study is designed to examine the effects of a wake-promoting agent (Modafinil) on working memory (WM) in persons with moderate to severe TBI utilizing a double blinded placebo controlled methodology. Our approach is to evaluate participants with BOLD fMRI and a limited neuropsychological battery to examine WM performance before and after pharmacological intervention. Hypotheses 1. Because increased cognitive effort (as a function of decreased efficiency after TBI) is presumed to underlie fMRI activation dispersion that is seen during central executive WM tasks, we anticipate an attenuation of cerebral activation in prefrontal cortex during pharmacological intervention with Modafinil when compared to placebo administration on the mPASAT and vigilance testing. 2. There will be a correlation between the decreased dispersion of the fMRI signal on scans and improvement in neuropsychological measures when individuals are on Modafinil that is not seen when they are taking placebo.