View clinical trials related to Traumatic Brain Injury.
Filter by:Traumatic brain injury (TBI) continues to be a major cause of death and disability throughout the world. The reduced cerebral blood flow secondary to the direct trauma-induced damage deregulates cerebral metabolism and depletes energy stores within the brain. Diffusion barriers to the cellular delivery of oxygen develop and persist. Besides, TBI often leads to intracranial hypertension, which in turn exacerbates diffusion disorders, further reducing cerebral oxygenation, and deteriorates the injury. By increasing the partial pressure of oxygen in blood, reducing intracranial pressure and cerebral edema, Hyperbaric oxygen therapy (HBO2) has been used in early treatment of TBI. However, due to the different severity of TBI, the clinical situation of early insult is complex and unpredictable, ordinarily there was a time delay between TBI and onset of HBO2 treatment averaging more than 2 weeks, especially in patients with severe TBI. Whether the delayed intervention is still effective is controversial.
The goal is to derive and a clinical decision rule for safe exclusion of traumatic brain injury without neuroimaging in head-injured ED patients who take anticoagulant medications. The objectives are to: 1. Derive and externally validate a new highly sensitive and maximally specific clinical decision rule for the exclusion of traumatic brain injury in head-injured ED patients who take anticoagulant medications; and, 2. Estimate the sensitivity and specificity of existing head injury clinical decision rules in head-injured ED patients who take anticoagulant medications.
Traumatic Brain Injury (TBI) is the leading cause of death and disability across the globe. Time from injury to treatment is the most critical factor that determines the patient's recovery. Mild TBI with no apparent symptoms are often left undiagnosed, thus delaying the treatment and hence recovery. CEREBO® is a non-invasive, rapid, near-infrared based, point-of-care device that can detect an intracranial bleed at an early stage.
This study is a randomized Phase 2 trial to determine the feasibility of real-time electrocorticographic monitoring of spreading depolarizations (SD) to guide implementation of a tier-based protocol of intensive care therapies, aimed at SD suppression, for the management of patients who have undergone acute operative treatment of severe traumatic brain injury.
Traumatic brain injury (TBI) is an important global health concern. Recently, advances in neurocritical care have led to an increase in the number of recovering TBI patients, and concomittantly in the incidence of complications of TBI. One of the most important sequalae of TBI is cognitive deficit, for which multimodal rehabilitation approach is indicated. Transcranial direct current stimulation (tDCS) is a promising treatment strategy for post-TBI cognitive deficits. However, a standardized tailored tDCS protocol is yet to be established for TBI patients. Therefore, this trial aims to 1) the efficacy of tDCS on post-TBI cognitive deficits, and 2) and optimized protocol of tDCS on post-TBI cognitive deficits via a three-arm double-blind, randomized controlled trial.
Hyponatremia (HN) is the most common electrolytic disorder in the traumatic brain injury (TBI) population, found in 17 to 51% of patients according to the series. Two etiologies predominate in the literature, the Syndrome of Inappropriate Anti Diuretic Hormone (SIADH) and the Cerebral Salt Waste Syndrome (CSW), but none has been precisely described in terms of epidemiology, risk factors or severity. Moreover, SIADH and CSH were often confused in previous works. The main goal of our study is to assess retrospectively prevalence, severity, time to onset, length, risk factors of HN in a large population of TBI patients, as well as treatment modalities and prognosis. A specific distinction was performed between SIADH or CSW.
The purpose of this study was to observe the relationship between the changes of circulating extracellular vesicles and disease development and outcome in patients with traumatic brain injury, and to find early serum markers and potential intervention targets for disease monitoring in patients with traumatic brain injury. In addition, explore the source of extracellular vesicles as much as possible to prepare for subsequent basic experiments.
Sequences of muscle tendon vibrations allow to reproduce the sensory feedback during movement like locomotion and kinaesthesia. It is known that such a treatment promotes motor recovery after stroke assuming that it enhances neuroplasticity. The aim of the research is to study the activity in cerebrospinal circuitry to evaluate the neuroplastic changes during and after instrumented proprioceptive rehabilitation relying on sequences of muscle vibration in subacute stroke stages.
The purpose of this study is to assess a balance training program to see if it can be helpful to avoid falls in people who have had traumatic brain injuries (TBIs). The study will include 3 groups: TBI Intervention group , TBI Control Group, and healthy control group. TBI Intervention group - These individuals will participate in 16 anticipatory postural adjustments (APA) and compensatory postural adjustments (CPA) training sessions using the Neurocom Balance Platform. Each session will last for 1 hour. During the APA portion, participants will be provided with a visual cue on the front screen in the form of a countdown timer showing the remaining seconds to the onset of the upcoming perturbation. This information will allow an opportunity for the participant to adjust their posture to handle the upcoming perturbation in the best possible way and also train them to anticipate upcoming disturbances and execute corrective motor outputs. In CPA, after a 5 second pause, the platform will oscillate at 1 Hz, with a constant amplitude, in the anterior-posterior direction for 50 seconds, followed by an additional 5 second quiet period. The participant will wear a safety harness at all times and a spotter will be present at all times. TBI Control Group- They do not receive any intervention. healthy control group- They do not receive any intervention. All three groups will participate in two data collection sessions: Baseline and follow-up. At baseline and follow-up, we will collect functional, clinical, biomechanical, and physiological metrics. During training and data collection, a spotter will be present at all times to prevent falls and participants will be allowed as much rest as needed by them..
The CONNECT-TBI Trial aims to develop safe, effective treatments for complex mTBI that improve cognitive functioning. Based on the compelling preliminary data generated by our study team, the objective of this study is to conduct a randomized, double-blinded, sham-controlled Phase II clinical trial of APT-3 combined with rTMS, HD-tDCS, or sham to treat cognitive control deficits in Veterans with complex mTBI and PPCS. At the Baseline Visit, participants will undergo demographic, neuropsychological, behavioral, and quality of life testing. They will also undergo structural MRI to permit modeling of their brain, resting/task-related fMRI to identify the CCN, and pseudocontinuous arterial spin labeling (pCASL) and diffusion tensor imaging (DTI) to assess for other pathologies. They will then be randomized to 16 sessions of APT-3 with concurrent rTMS, HD-tDCS, or sham stimulation delivered to the unique functional left dorsolateral prefrontal cortex (DLPFC), a primary node of the CCN. Lastly, they will repeat all baseline tests, and report on 3- and 6-month recovery levels to establish longevity and stability of subjective benefit. Given that this individualization protocol has never been attempted for cognitive rehabilitation in military mTBI, we expect this trial will generate useful effect sizes for HD-tDCS and rTMS to be used for powering the next step, a Phase III multi-center trial.