View clinical trials related to Traumatic Brain Injury.
Filter by:The investigators have assembled an integrated knowledge/technology/client team to develop a novel motion capture-based home therapy program for children with hemiparesis (cerebral palsy, acquired brain injury (ABI)) and older persons post-stroke. The investigators society needs new approaches to improve the quality of life for millions of Canadians. The method proposaed here is to combine low-cost motion capture devices, a bimanual training program, social media frameworks such as Facebook Games, and on-line performance sharing between therapy clients and with their therapists. The investigators believe that together these approaches will yield interventions for people with stroke and children with hemiplegia that significantly improve their motivation to continue their exercise programs and thus improve their functional ability which will lead to improved quality of life.
This study is designed to expand the database of flortaucipir F 18 safety and tau binding as measured by PET imaging and to provide standardized conditions for flortaucipir PET use, data collection and analysis to facilitate companion studies including, but not limited to, longitudinal studies of aging, depression, and traumatic brain injury.
The objective of this study is to investigate the efficacy and safety of NT 201 compared with placebo for the treatment of chronic troublesome sialorrhea associated with neurological disorders (e.g. cerebral palsy, traumatic brain injury) and/or intellectual disability in children and adolescents naïve to Botulinum neurotoxin treatment and aged 2-17 years.
The study will monitor outcomes of two interventions to develop a best practice in the treatment of mild Traumatic Brain Injury (mTBI).
The potential long-term effects of Traumatic Brain Injury (TBI) are poorly understood. Repeated concussions have been associated with an elevated incidence of Alzheimer's disease (AD) along with a reduced age of onset. As repetitive TBI has been studied, a syndrome has now been identified: chronic traumatic encephalopathy (CTE). There are growing concerns about the long-term neurologic consequences of head impact exposure from routine participation in contact sports (e.g., boxing, football). Brain autopsies of athletes with confirmed CTE have demonstrated tau-immunoreactive neurofibrillary tangles and neuropil threads (known as tauopathy). The relationship between exposure to repetitive head impact and the subsequent development of chronic neurodegenerative disease has not been established. Further, as the diagnosis of CTE (defined by the presence of tauopathy) is presently made after death at autopsy, clinical tools and biomarkers for detecting it remain to be defined. With the advent of FDA-approved PET amyloid imaging, clinicians and researchers are now able to estimate plaque density in the brains of living patients. However, there are critical limitations to amyloid imaging. Current evidence suggests that markers of the presence and severity of tauopathy may be able to address these limitations. The study will utilize both [18F] Florbetapir and [18F]-T807 PET imaging to investigate amyloid and tau accumulation in subjects with a history of concussions. In order to determine whether problems with cognition and memory are seen within the populations defined for the study, the researchers will administer a core battery of neurocognitive testing. This battery will assess cognitive abilities commonly affected by TBI, including processing speed, reaction time, new problem-solving, executive functions, attention and concentration, and learning and memory. These tests, in conjunction with the imaging, will be able to determine whether regional brain activity is associated with specific cognitive problems. The researchers will obtain PET and neurocognitive data in 3 cohorts: subjects with a history of TBIs, subjects with mild cognitive impairment (MCI) and no TBI history, and healthy controls. The investigators aim to determine whether individuals with TBI are on the same trajectory of neurodegenerative disease seen in AD or in CTE. Because of the overlap in clinical/cognitive and some behavioral symptoms in AD and CTE, an additional biomarker tool is needed to prevent misdiagnosis. Accurate diagnosis is crucial in order to provide patients with appropriate treatment.
Significant morbidity, mortality, and related costs are caused by traumatic brain injury (TBI). A simple, effective, and lightweight device worn by athletes or war fighters in the field, designed to mitigate TBI resulting from blast trauma or concussive events, would save lives, and the huge costs currently being experienced for life-treatment of surviving victims. An externally-worn medical device that applies mild jugular compression according to the principle of the Queckenstedt Maneuver (the Device) is being developed by Q30 Labs, LLC (Q30). Initial research suggests that the Device has the potential to reduce the likelihood of TBI. The rationale for testing wideband absorbance and Oto-acoustics emissions (OAE) is that the investigators need a physiologic, non-invasive method to evaluate the brain responses to mild jugular compression across multiple age groups. To determine this with MR imaging is currently cost prohibitive. The investigators pilot data from the parent IRB indicates a consistent response measured via wideband absorbance in young adults. Therefore, a preliminary step to evaluate the safety and efficacy of the neck collar device is to employ this technology across a wide range of ages.
The purpose of this study is to determine if memantine can improve cognitive and neuropsychiatric outcomes after severe traumatic brain injury.
Up to half of military veterans with traumatic brain injury (TBI) also suffer from co-occurring posttraumatic stress disorder (PTSD). Both are linked to higher risk of chronic pain, one of the most common health complaints among U.S. veterans who served in Operation Enduring Freedom (Afghanistan), Operation Iraqi Freedom (Iraq), and Operation New Dawn (OEF/OIF/OND). However, pain medications elevate risk of opioid abuse, and studies indicate that veterans perceive barriers to traditional mental health treatments. Little research exists regarding non-pharmacological, technology-based interventions designed to reduce pain in veterans with PTSD and TBI. Mobile technology used to implement neurofeedback (EEG biofeedback) shows promise in providing a portable, low-cost intervention for reducing pain in veterans with co-occurring disorders. We aim to test the feasibility and effectiveness of using mobile neurofeedback devices for reducing pain symptoms in veterans with PTSD and TBI. Veterans with PTSD, TBI, and chronic pain will receive a NeuroSky headset (which reads EEG brain waves) and an iPod Touch with an app called Mobile Neurofeedback (which provides neurofeedback to induce relaxation). Veterans are taught how to use these together to do neurofeedback themselves at home for 12 weeks. Guided by existing research and preliminary data, we hypothesize that participants will show high levels of adherence to the NeuroSky + Mobile Neurofeedback intervention for the 3-month study duration and that participants will show statistically significant reduction in pain symptoms at 3 months compared to baseline. Given links between pain and other outcomes in veterans, we will also explore effects on drug abuse, violence, and suicidality. When the research is complete, the field will be changed because we will know whether new technology reading EEG brainwaves can be used to treat symptoms among individuals suffering from chronic pain. We will also know whether neurofeedback shows promise as an effective intervention for veterans with PTSD and TBI to reduce pain and related outcomes. If this program of research is successful, its impact will be to shift approaches to managing pain in clinical practice, for both veterans and civilians
Neuroglobin has been described as a marker of traumatic brain injury. Nogo-A plays an important role in mediating neuroanatomical plasticity and functional recovery following traumatic brain injury. The investigators sought to examine the changes in serum neuroglobin and Nogo-A concentrations in patients with traumatic brain injury during the initial 96-h posttraumatic period and assessed the relation of neuroglobin and Nogo-A to Glasgow Coma Score and prognosis of such patients with traumatic brain injury.
Deficits in memory, attention, cognitive, and executive functions are the most common disabilities after traumatic brain injury (TBI). Dopamine (DA) neurotransmission is implicated in these neural functions and dopaminergic pathways are recognized to be frequently disrupted after TBI. Methylphenidate increases synaptic DA levels by binding to presynaptic dopamine transporters (DAT) and blocking re-uptake. The objectives of this study are to use PET imaging with [11C]-raclopride, a D2/D3 receptor ligand, before and after administering methylphenidate, to measure endogenous DA release in patients who are experiencing problems with cognition, attention and executive function in the chronic stage after TBI. In addition, we will use TMS to test short intracortical inhibition, a gamma-aminobutyric acid receptor A (GABAA) - mediated phenomenon, which is under partial DA control, as a measure of dopaminergic activity on and off