Active clinical trials for "Brain Injuries, Traumatic"

The purpose of this study is to determine the feasibility of combining PoNS therapy with standard vestibular and balance therapy with the proposed double-blind design; evaluate preliminary indications of efficacy. This study is also evaluating recruitment rate, completion rate, device usability, and outcome measures feasibility. Goal for recruitment: 100% of 30 subjects meeting all inclusion criteria can be recruited over the 36 week pilot recruitment phase. Completion and compliance: 90% of subjects will complete the study, 90% of sessions within each subject will be completed, and for completing subjects, 100% of measures will be completed. Useability: all therapists and subjects must rate useability as good or better. Success of blind: subject accuracy at guessing group membership must be at or near 50%.

The study will explore the neurocognitive effect of four weeks of treatment with amantadine versus placebo in patients with traumatic brain injury using the Interval Bisection Timing Task. Approximately 16 individuals with traumatic brain injury are expected to participate in this study. Subject participation is expected to last up to 8 weeks with 16 study visits.

This randomized trial will compare the clinical efficacy of adding oral magnesium oxide to acetaminophen and ondansetron in the treatment of adolescents presenting within 48 hours of a mild traumatic brain injury using the Post-Concussion Symptom Severity Score Index.

Traumatic brain injury (TBI) is a leading cause of death and disability in young people. It has been called the "signature wound" of the Iraq war because of its frequency among troops. TBI is associated with many chronic disabilities. Physical alterations include reduced exercise tolerance and profound muscle weakness, whereas psychological alterations include diminished sense of well-being, depression, fatigue and anxiety. Muscle and brain tissues rely upon circulating blood amino acids as precursors for metabolic functions. The investigators have shown that even one year after injury, plasma valine, an essential amino acid (EAA), was markedly reduced in patients with TBI compared to healthy controls. The investigators speculate that low plasma valine concentration contributes to chronic fatigue after TBI, since valine and tryptophan compete for the same transporter into the brain, and a low plasma valine concentration will allow more tryptophan to be transported. As a consequence, increased brain tryptophan will increase serotonin production, which may significantly contribute to the development of fatigue. Thus, the investigators will test if restoring valine concentration in persons with TBI may reduce fatigue perception and improve physical and neuropsychological function. Further, the investigators have previously shown that EAA intake has an anabolic effect in healthy young and elderly individuals. However, no data are currently available in persons recovering from TBI. Thus,the investigators will also test if EAA and/or valine can improve muscle mass in patients with TBI.

The aim of this study is to assess the safety and feasibility of dexmedetomidine as an adjunct to conventional sedative therapy compared to conventional sedative therapy alone in patients with severe traumatic brain injury.

The aim of the study is to measure the effect of Finnish physician-staffed EMS unit treatment methods on traumatic brain injury (TBI) patient prognosis. In the second part of the study the gathered data will be combined with the data from an earlier study (NCT01454648) for regression analysis. The aim of the second study is to identify prehospital factors influencing the prognosis of prehospital TBI patients.

Traumatic brain injury (TBI) is a leading cause of death and disability worldwide (Ghajar, 2000). With an estimated annual incidence of up to 500 per 100,000 population and more than 200 hospital admissions per 100,000 admissions in Europe each year, TBI is a major challenge to public health (Lingsma, 2010). Mortality and morbidity after TBI depend on several factors, either associated with patients characteristics, the cause of TBI, the neurological and general severity and secondary brain insults, the structural brain alterations as diagnosed at brain computed tomography (CT) (Rosenfeld, 2012). The prognostic value of brain CT characteristics is well documented, including the status of basal cisterns, midline shift, the presence and type of intracranial lesions, and traumatic subarachnoid hemorrhage (Maas, 2008). Postraumatic cerebral ischemia, which includes functionally impaired yet still viable tissue, so-called ischemic penumbra, and irreversible cerebral infarction (PTCI), is frequent in patients who die after moderate or severe head trauma (Stocchetti, 2014). Evidence of antemortem occurrence of PTCI is limited to three single-center retrospective studies, reporting a varying prevalence of 1.9%, 8% and 19.1% (Mirvis, 1990; Marino, 2006; Tawil, 2008). Increased intracranial pressure (ICP), blunt cerebral vascular injury, need for craniotomy and treatment with recombinant activated factor VII, have been demonstrated to be risk factors for PTCI. In one study, PTCI was an independent risk factor for poor outcome after moderate or severe head trauma with a two-fold increase in mortality and severe disability (Marino, 2006). PTCI can be an important diagnosis in patients with significant TBI for various reasons. First, it might influence long-term outcome. Second, as an outcome that is measurable, and relevant to survival and lifestyle, PTCI could be used as an outcome measure in randomized controlled trials. Third, diagnosis of PTCI could be used as a standard diagnostic reference to validate early surrogate indicators of cerebral ischemia. The investigators therefore planned a multi-center prospective study to investigate the impact of PTCI on disability at hospital discharge, and on 6-month morbidity and mortality in a population of moderate and severe adult TBI patients. The investigators also evaluated the role of intracranial hypertension, decreased cerebral perfusion pressure, hypotension and other secondary ischemic insults in determining the appearance of PTCI.

Brain injury is a frequent purpose for consultation in emergency services. Management of brain injury is time and resource consuming, combining clinical monitoring and imaging. The stage prior to the management of the victims of brain injury is stratification of the severity, potential or proven. Severe brain injury requires emergent brain CT-scan, ideally within one hour of the first medical contact. Patients requiring this strategy present with focused neurological deficit, Glasgow score <15 to 2 hours after the trauma, suspicion of open fracture of the skull or dish pan fracture, any signs of fracture of the skull base (hemotympanum, bilateral peri-orbital ecchymosis), otorrhea or rhinorrhea of cerebrospinal fluid, more than one episode of vomiting in adults, and posttraumatic convulsion. Patients benefiting from anticoagulant therapy are included in this category. Victims of brain injury that do not fall into this category are considered less critical. By definition, mild traumatic brain injury : a trauma of the cephalic extremity : whose Glasgow score (30 min after the trauma or during the consultation) is 13-15, associated with one or more of the following: confusion; disorientation; loss of consciousness of 30 min or less; post-traumatic amnesia of less than 24 hours; other transient neurological abnormalities (focal signs, epileptic seizures, non-surgical intracranial lesion). Among these patients, some are considered at risk of developing intracerebral lesions. Nevertheless, it should be noted that the prevalence of hemorrhagic complications is radically different between patients with a Glasgow score of 13 and those with a score of 15. Thus, the recommendations suggest a brain scan without injection of contrast media within 4 to 8 hours for patients with the following characteristics : a retrograde amnesia of more than 30 minutes, a loss of consciousness or amnesia associated with: either a risk mechanism (pedestrian overturned by a motor vehicle, ejection of a vehicle, falling by more than one meter), or an age> 65 years, or coagulation disorders, including the use of platelet aggregation therapy. Patients who fall outside this definition are considered low risk of complication and should not benefit of imaging. Data from the scientific literature show that an early brain CT-scan allows identification of post-traumatic lesions in this population. Nevertheless, organizational problems, including the availability of the imaging, radiation, and disruption of surveillance related to patient displacement, are limitations to this strategy. In contrast, the low cost-effectiveness of CT scan is often advocated in patients with mild traumatic brain injury. For example, in the Octopus study, 52 of 1316 patients who received CT scan after mild head trauma had an intracerebral lesion. Among these patients, 39 (3%) had intracerebral lesion related to trauma; for 13 (1%) patients, the link with the trauma was uncertain. In fact, the search of alternatives for a safer, more conservative, more efficient practice, one of the objectives of which is to limit the undue use of cerebral scanning. Thus, many teams have been interested in the use of biological variables to guide the decision to use imagery. Among candidate biomarkers, the S100B protein has been the subject of many evaluations which allow it to be used in current practice. Indeed, the increase of the S100B protein carried out within 3 hours following a mild head trauma makes it possible to identify the patients at risk of intracerebral lesion and to target the indications of imaging. The purpose of the registry is to describe the use, interpretation and performance of the S100B protein in its use at bedside in emergency medicine.

The purpose of the study is to assess the usability and tolerability of this jugular vein compression device in a population of helmeted and non-helmeted competitive high school, collegiate and professional athletes in the sports of football and rugby. This study differs from previous work in that it is designed to capture additional data related to the athlete experience wearing the jugular vein compression device in older and more elite playing levels.

Traumatic brain injury is catastrophic event that commonly require treatment in an intensive care unit. Management is mainly supportive aiming at avoiding hypoxia, hypotension, hypoglycaemia and increased intracerebral pressure. Thus far efforts to find a specific pharmacologic therapies have been disappointing. Recently it was demonstrated that recombinant erythropoietin has been found to decrease mortality at six months from injury but without significantly improving functional neurological outcome (GOSe). Whether this survival benefit of EPO is sustained beyond 6 months is unknown. In the current study survival data will be collected centrally and patients alive or person responsible will be invited to participate in an evaluation of neurological function and quality of life. Factors associated with time to death as well as factors associated with long term quality of life will be determined with statistical methods.