View clinical trials related to Traumatic Brain Injury.
Filter by:Prospective study of diagnostic accuracy of optic nerve sheath diameter measurement (index study) in traumatic brain injury with simultaneous invasive intracranial pressure monitoring as the reference standard.
Spaulding Rehabilitation Hospital is conducting a research study evaluating the effectiveness of the brain-training product, MUSE, an EEG-guided neurofeedback device designed to assist in cultivating a relaxed, attentive state of mind during meditation. The investigators study aims to evaluate whether such a tool could be useful in treating persistent traumatic brain injury symptoms such as inattention, impulsivity, irritability, or dysregulated mood.
Patients with mild-moderate traumatic brain injury (TBI) sustained between 3 months and 5 years ago with prolonged postconcussive symptoms will be recruited. On Day 1 of the study they will undergo neuropsychological (NP) testing. They will then undergo 10 days of Left dorsolateral prefrontal (DLPFC) anodal transcranial direct current stimulation (TDCS) (active or sham) combined with cognitive training. On day 10 NP testing will be obtained again. On Day 30, NP testing will be repeated a 3rd time. At 6 months and 1 year, quality of life, depression, and post concussive symptoms will be assessed.
By studying individual biomarkers in body fluids such as saliva, there is a potential for detecting injury to the brain resulting from an acute traumatic even that may not be detectable by conventional neuroimaging like CT scans.
The aim of the study is to investigate the reliability of the Melbourne Assessment.
This is an open-label, non-randomized, prospective, multi-site, parallel group (segment), hypothesis-generating study designed to collect data that will aid in future scientific and engineering exploration of correlations between clinical neuropsychological assessments and GE Research Pack II advanced MR imaging in mTBI patients. The results are primarily intended for scientific inquiry and engineering development purposes, and may be used in future regulatory submissions.
The primary objective of the clinical trial is to evaluate the effect of time on levels of Ubiquitin C-terminal Hydrolase-L1 (UCH-L1) and Glial Fibrillary Acidic Protein (GFAP) biomarker levels in a population of head injured subjects over the age of 18 presenting acutely with a Glasgow Coma Scale score 13-15 as well as in a group of uninjured control subjects.
In the search for a novel marker of stroke that could be rapidly assessed in blood, the investigators developed a point-of-care (POC) lateral flow device (LFD) that rapidly (< 15 min) detects levels of a biomarker that is released into blood following neuronal injury associated with stroke and traumatic brain injury. The protein's expression in human brain should serve as a useful biomarker of neuronal injury in stroke and traumatic brain injury.
A new technology called Global Z-Score Neurofeedback Technology (GZNT) has been identified that can overcome an existing barrier to the use of neurofeedback as a treatment technique in a military setting. Neurofeedback, or EEG Biofeedback, is a form of biofeedback that uses the brain's own electrical activity as the training parameter. With sufficient practice, the brain can learn to change its own activity through finely tuned feedback using computerized sounds, graphs and animations. Previous attempts at using neurofeedback as a treatment modality have been subject to a lack of standardization and have required significant expertise on the part of the provider. This new GZNT technology allows neurofeedback to be administered in a standardized and semi-automated fashion, which, if effective, will represent a significant advance toward providing this promising treatment modality to Service Members in a military or VA setting. This study will determine feasibility and preliminary evidence of efficacy for this neurofeedback technology in a pilot study of soldiers with medical issues associated with Traumatic Brain Injury (TBI). GZNT technology has the potential to provide a cost-efficient, non-invasive/non-pharmacological approach to recovery from impact and/or blast-induced brain injury, and holds promise to simultaneously address emotional symptoms that are often a part of the post-concussion symptom picture.
The purpose of this project is to test the hypothesis that Speed of Information Processing (SIP) deficits in acquired brain injury (ABI) can be remediated. The majority of individuals with acquired brain injuries have speed of information processing deficits as part of the cognitive sequelae of the brain injury. Empirical research is expected to demonstrate the efficacy of computerized cognitive Speed of Information Processing (SIP) training in individuals with ABI. Study participants will be asked to attend two study visits over the course of approximately 13 weeks. Participants will be randomly assigned to either the experimental or control group.