View clinical trials related to Brain Injuries.
Filter by:This study examines the effect of an intervention consisting of dynamic circadian light and sound therapy, as well as systematic information on sleep pattern, agitated behavior and functioning level.
The mechanical ventilation strategy has changed over years worldwide. Several international researches have been conducted to study the association of the use of mechanical ventilation with clinical outcomes. In this prospective, multicenter, cross-sectional survey, the practice of mechanical ventilation among patients with severe brain injury will be investigated in 70 intensive care units in China.
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.
The current study was designed to investigate the change of serum ficolin-3 levels and assess the prognostic predictive effect of serum ficolin-3 levels in the patients with severe 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.
Hypothesis: Cortical spreading depolarizations are inhibited by the NMDA receptor antagonist Ketamine Aim 1: To demonstrate, in a group of patients with acute severe brain injury requiring surgery including traumatic brain injury and aneurysmal subarachnoid hemorrhage, whether use of continuous infusion of ketamine decreases frequency of occurrence of cortical spreading depolarizations.
This study will assess the effectiveness of a portable goggle system in the diagnosis of mild traumatic brain injury (mTBI) in athletes.
This study (Part 1) is designed to build a database including EEG, neurocognitive performance, clinical symptoms, history and other relevant data, which will be used to derive a multimodal EEG based algorithm for the identification of concussion and tracking of recovery. In addition, neuroimaging will be conducted at time of injury and following Return to Play (RTP).
Cases of traumatic and nontraumatic brain damage have high rates of morbidity and mortality. In this study of cases being treated in the ICU for a diagnosis of brain damage, it was aimed to evaluate the relationship between mortality and the distribution of reason for and resulting type of brain damage and to determine other factors affecting mortality.