Active clinical trials for "Brain Injuries, Traumatic"

Traumatic Brain Injury (TBI) is the most common cause of death and long-term disability in children. Much of the long-term disability stems from neurocognitive impairments that are not greatly helped by current cognitive training and pharmacological treatments for TBI related cognitive impairments. This study tests the hypothesis that a drug, D-cycloserine (DCS), will significantly enhance the effect of cognitive training in correcting cognitive impairments in children with moderate/severe TBIs. In order to do so, study subjects who fit inclusion criteria, including those with moderate to severe TBI who show persistent working memory weaknesses based on a screening, will be recruited. They will have three visits to UCLA. During the first visit, subjects will undergo an MRI protocol before and after taking a pill (drug or placebo, blinded). They will also participate in a number of paper and pencil cognitive tests. Then subjects will be enrolled in a 6 week computerized cognitive training program (CogMed). They will also be prescribed a drug/placebo pill (depending on which group they are randomized into), which they'll have to take at regular intervals during the 6 weeks. They will have weekly check in phone calls or visits by a coach trained in the program to make sure they are following the study protocol accurately, to have their questions answered, and for motivation. At the end of the training period, subjects will return to UCLA to again complete the MRI protocol and cognitive testing. After three months of enrollment, they will have a final visit to UCLA, including only cognitive testing. A total of 30 subjects will be entered into the study.

This feasibility study is being conducted to determine potential associations between a broad range of clinical neurological symptoms and magnetic resonance images (MRI), data, and clinical findings involved in mild traumatic brain injury (mTBI). These associations will be examined over the acute and sub-acute period (approximately 3 months) following injury to provide information useful for optimization of MR pulse sequences for mTBI applications. Correlations exist over the sub-acute period in clinical neurological and MR data (images, image reads, and RAW data), which may indicate temporal evolution patterns. The intent of this study is to broadly generate potential biomarkers of temporal evolution of mTBI detectable in MR images and data ("MR mTBI biomarkers").

After a mild traumatic brain injury (mTBI) people often report balance problems. At Parkwood hospital we have noticed that balance is improved when patients with mTBI wear a weighted compression vest. This follow up pilot study looks at the immediate effects of weighted compression vests on participants with altered balance after mTBI. Participants will be recruited from the Ministry of Health Outpatient Acquired Brain Injury (ABI) Program wait list. Then each participant will perform a series of balance and walking tests under 2 conditions : 1) wearing a weighted compression vest , 2) not wearing a weighted compression vest. It will be randomized whether participants wear the vest on the first or second testing day. Participants will also be asked how confident they are about their balance and how anxious they felt performing the assessments after each testing session. We hypothesize that the weighted compression vest will improve fatigue and anxiety immediately and 24 hours after performing a complex task, and will improve static and dynamic balance, gait variability, and walking speed in patients with mTBI, during the tasks.

The aim of this study is to determine the effects of an acute session of physical exercise on cognitive functioning and humor of traumatic brain injury patients and to investigate whether different cognitive responses can be achieved with different intensities of exercise (moderate and vigorous). The investigators hypothesize that while moderate intensity physical exercise may be beneficial to cognitive functioning, vigorous intensity may be detrimental to TBI patients, as physical fatigue may impair alertness and other higher cognitive functions.

The purpose of this investigation is to conduct a series of case studies on the impact of LearningRx cognitive training on cognitive skills, brain structure, and daily functioning for participants with Traumatic Brain Injury (TBI).

The goal of this project is to develop a low-cost, user-friendly, portable telerehabilitation system for physical therapy of the upper limb after stroke or traumatic brain injury. The system is based on the use of a commercially available force feedback joystick and will work with an ordinary home PC and a standard high-speed internet connection. Using the joystick, the patient will perform exercises designed to aid in recovering motor function of the hand and arm. The joystick will be programmed to either assist or resist the patient's movements. The system will include sophisticated analysis of patient status and progress to provide the therapist and physician with detailed information. In the first phase of the study, we will develop the system in cooperation with the physical therapy staff and other rehabilitation specialists. The investigators will examine the usability, comfort, safety and therapeutic benefit of the system. In the second phase of the study, the investigators will employ the system in patients' homes, using the internet to connect to rehabilitation specialists in the clinic. The study hypothesis is that it is possible to adapt commercially available, low cost gaming equipment such as force feedback joysticks to provide therapy for patients in their own homes, and that patients will be able to work with this system and will find it enjoyable and helpful for recovering motor function.

It is anticipated that the use of tissue oxygen monitoring to measure brain tissue oxygen and deltoid muscle oxygen will provide more precise information about focal brain ischemia and systemic hypoperfusion than current techniques and measures such as blood pressure, heart rate and intracranial pressure. Understanding the relationship between tissue oxygen tension collected from the brain and deltoid muscle in critically injured patients could lead to a broader understanding of the important metabolic and cellular events that occur following severe injury and the changes induced by therapeutic interventions. Furthermore, the use of interventions designed to improve tissue hypoxia, as measured by low brain or muscle tissue oxygen, may improve mortality or neurological recovery after systemic trauma or head trauma compared to current approaches that do not involve tissue metabolic monitoring.

The purpose of the study is to explore to what extent continuing the antidepressant medication citalopram (Celexa), after depression has responded to treatment, helps prevent the return of depressive symptoms in patients with recent traumatic brain injury (TBI).

This is a clinical study comparing the physiologic effects of two hypertonic solutions (mannitol, hypertonic saline) with a particular emphasis on changes in cerebral blood flow in patients with intracranial hypertension following serious traumatic brain injury (TBI).

The current project will examine the effect of a brief psychological intervention on post-concussion symptoms, neurocognitive function, cerebral blood flow (CBF), and psychophysiological and salivary cortisol markers of autonomic nervous system (ANS) in a sample of 20 participants between 13-25 years of age who experience long-term post-concussive (PC) symptoms 2-9 months post-injury as well as 20 age- and sex-matched controls (non-injured) participants to provide normative data on all the above measures except for concussive symptoms.