View clinical trials related to Traumatic Brain Injury.
Filter by:Researchers have developed a probe that contains infrared light sources that can illuminate the deep brain tissue of the frontal lobe. Photodetectors in the probe detect the backscattered light, which is modulated by pulsation of the cerebral arteries. Changes in the extramural arterial pressure affect the morphology of the recorded optical pulse, so analysis of the acquired signal using an appropriate algorithm could enable the calculation of the intracranial pressure noninvasively (nICP), which would be displayed to clinicians continuously. This pilot study is the first evaluation of the device in patients in who the gold standard comparator of invasive ICP was available. The acquisition of pulsatile optical signals was performed for up to 48 hours in each of the 40 patients who were undergoing invasive ICP monitoring as part of their normal medical treatment. Features of the optical signals would be analysed offline. A machine vector support algorithm would be implemented, with the aim of estimating ICP noninvasively and compared to the gold standard of synchronously acquired invasive ICP data.
This is an exploratory observational study. Broadcasted video footage is used to review all head impacts during all 64 matches in the football tournament. All head impacts are registered, and simple descriptive statistics are used to create overviews of the head impact characteristics, including video signs of potential concussion, observed contact, location of the head impact, presence and timing of medical assessment, whether there was foul play and sanction, and if the player was substituted.
This project will adapt a currently deployed Clinical Decision Support (CDS) system to deliver a VTE prevention guideline for adult patients with traumatic brain injury (TBI). We believe this is an ideal PCOR use case given PCORI's continued effort to combat VTE in trauma and our experience previously implementing this guideline. The Our overall goal is to successfully scale, evaluate, and maintain an interoperable TBI CDS across 7 total institutions.
The project will consist of subjects who have suffered Traumatic Brain Injury (TBI) and who are able to ambulate on treadmill with or without a harness system. This will be a 4-week controlled study consisting of two groups of TBI patients, high-intensity intervention group and low-intensity control group. Both groups will receive physical therapy treatment 3 times per week for 1 hour. The intervention group will undergo 30-minute sessions of high-intensity walking on a treadmill with an overhead harness attached for safety. In addition, they will also get up to 30-minutes of low-intensity physical therapy in order to receive 1 hour of treatment time. The control group will undergo only low-intensity physical therapy activities for 1-hour. Low-intensity physical therapy will include strength exercises, stretches, balance, and low-intensity gait training. All participants in both groups will complete these outcome measures on the first day of the study, after 2 weeks of participation, and again at the end of 4 weeks or on their last day before discharge from Carilion's services. Later on, all participants in both groups will be followed up to complete the same set of outcome measures at the end of 1 month since completion of the protocol. This follow up session will take up to 45 minutes to complete.
This study has two main goals: 1) to refine and enhance the R2R-TBI intervention; and 2) to examine the efficacy of the R2R-TBI intervention in a randomized control trial. To achieve the second goal, we will employ a between-groups randomized treatment design with repeated measures at baseline, one-month post-randomization, and at a six-month follow-up. The two conditions will be: a) usual medical care plus access to internet resources regarding pediatric brain injury (Internet Resources Comparison group, IRC), and b) usual medical care plus the R2R-TBI intervention (Road-to-Recovery group, R2R-TBI).
Traumatic brain injury (TBI) causes acute deficits in cerebral perfusion which may lead to secondary injury and worse outcomes. Inhaled nitric oxide (iNO) is a vasodilator that increases cerebral blood flow and is clinically used for hypoxic respiratory failure in neonates and adults. The investigators will perform a randomized controlled trial of iNO treatment in TBI patients acutely after injury. The investigators will then assess perfusion changes with optic neuromonitoring, blood biomarkers, and 6 month clinical outcomes.
Abstract Purpose Patients with anticoagulation therapy has a higher risk of developing traumatic Intracranial Hemorrhage (tICH). Delayed Intracranial Hemorrhage (d-ICH) is a rarer clinical manifestation; however, the incidence varies from 0-9,6 % in other studies. Some studies have also questioned the clinical relevance of d-ICH, since the mortality and the need of neurosurgical intervention is reported to be very low. The aim of this study is to determine the incidence of d-ICH at Sundsvall Regional Hospital. Methods A retrospective observational study of patients with mTBI and oral anticoagulation therapy. Data from medical records and radiology registry in Sundsvall hospital for 29 months during 2018-2020 in Sundsvall identified 249 patients with an initial negative CT scan who performed a follow-up CT scan. Outcome measure was incidence of d-ICH.
Traumatic brain injury (TBI) is a common cause of long-term neurological morbidity, with devastating personal and societal consequences. At present, no pharmacological intervention clearly improves outcomes, and therefore a compelling unmet clinical need remains. 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors, or "statins," offer a potential novel therapeutic strategy for TBI. In this study the investigators will study primarily the effect of statins on 30-day mortality rate which is defined as death within 30 days of TBI presentation where the occurrence of TBI is hour 0 or day 0 and secondarily evaluation of duration of ICU stay associated with or without complications.
Demonstrating that diagnostics of the state of consciousness and cognitive functions of patients with consciousness disorders performed using C-Eye X (based on eye-tracking technology) allows a more objective assessment of state of patients who were wrongly diagnosed based on popular methods using in a clinical practice (like behavioural scales on paper forms).
Clinical evaluation is crucial in the clinical diagnosis, treatment, and prognosis prediction in patients with traumatic brain injury (TBI). However, the existing evaluation systems are not perfect, because many factors are not taken into account, for example, there is a lack of molecular diagnostic criteria for evaluating patients with TBI. We attempt to collect the patient's clinical data and combine it with neuroimaging, as well as molecular biomarkers generated by single-cell sequencing to assess their neurological status and outcome. The clinical and molecular data collection and analysis will be helpful to evaluate the patient's neurological condition and predict the patient's outcome more accurately.