Active clinical trials for "Brain Injuries"

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.

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.

Traumatic brain injury (TBI) is frequently complicated by depression and other problems such as post traumatic stress disorder (PTSD), sleep disturbance, cognitive deficits and behavioral problems. Untreated depression can lead to reduced productivity and poor global outcome. There is no Food and Drug Administration (FDA) approved drug for the treatment of TBI-related depression. The overarching goal of this small study is to determine the effectiveness of low frequency right (LFR) rTMS for the treatment of post-TBI depression and co-occurring psychiatric symptoms. Repetitive transcranial magnetic stimulation (rTMS) is a brain stimulation technique. It involves generating a brief magnetic field in a coil that is placed on the scalp. The magnetic field passes through the skull and induces a weak electrical current in the brain that briefly activates neural circuits at the stimulation site. Adults aged 18 and older, with a history of head injury of mild or moderate severity , who are currently experiencing symptoms of clinical depression may join the study.

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

Within a prospective, randomised, controlled study 60, selected patients with chronic (> 6 months) stroke or traumatic brain injury will be randomised to 30 1-hour sessions of competitive versus non-competitive attentional training. Competitive training will include fifteen 1-hour sessions of standard (paper and pencil) training under competitive situations and fifteen 1-hour sessions of competitive attentional games designed for this purpose using a new virtual reality system (conventional liquid-crystal-display screen with an infrared LED array to facilitate multi-touch experience embedded in a conventional table). Progress will be evaluated by pre and post measurement of attentional neuropsychological tests, subjective reports of global attention, usability and motivational scales. Our hypothesis is that competitive training is more effective in improving attention than conventional training in the chronic phase after acquired brain injury.

This open label trial is conducted to investigate the efficacy and safety of the combination therapy of allogeneic umbilical cord blood (UCB) and granulocyte-colony stimulating factor (G-CSF) for patients with brain injury or neurodegenerative disorders.

Driving is a portal into general life functioning, and impaired driving skill can pose a serious threat to the combat veterans (CV), passengers and others; and involves increased risk of subsequent injuries, medical expenses and legal sequelae. Motor vehicle crashes (MVC) among post deployed CV are one of the top four causes of injury and disability, hospitalization, and outpatient visits across the military, and are a leading cause of death among Army service members. The risk of motor vehicle (MV) death is significantly increased in years immediately following return from the battlefield. In sum, the effects of Traumatic Brain Injury (TBI)/ Post Traumatic Stress Disorder (PTSD) and other blast related injuries, combined with the "battlefield" mindset and lack of community reintegration programs place CV at risk for MVC and fatalities. On-road assessments, the gold standard, presents a risk for crash or adverse advents in this population of CV. Alternately, simulated driving evaluation measures driving performance in a safe, accurate and objective manner with evidence of absolute and relative validity when compared to real world (on-road) driving. Knowing participants can or cannot safely resume driving, and providing rehabilitation for those with a potential for resuming safe driving could result in: increased safe driving behaviors; avoidance of injuries, collisions, citations and participants residua; and resuming safe driving with its attendant benefits in the realms of family functioning, participation in society and satisfaction with life. The overarching objective of this proposal is to discern, after clinical and simulated driving performance testing , if Occupational Therapy Driving Intervention (OT-DI) can improve the safe driving performance (less errors) over the short term (immediately following intervention) and intermediate term (3 months).

Post-traumatic brain hypoxia/ischemia develops hours after traumatic brain injury (TBI), and its intensity is directly related to the neurological outcome. The thresholds for irreversible tissue damage following TBI indicate a particular vulnerability of injured brain. Improving brain oxygenation after severe TBI is the focus of modern TBI management in the intensive care unit (ICU). The calculation of cerebral perfusion pressure (CPP), with CPP = mean arterial pressure (MAP) - intracranial pressure (ICP), has become the most used estimator of cerebral blow flow. To prevent ischemia due to elevated ICP, current international guidelines recommend maintaining CPP at 60-70 mmHg and ICP below 20 mmHg. However, episodes of brain hypoxia/ischemia, as assessed with brain tissue oxygen pressure (PbtO2) measurements, might occur despite optimization of CPP and ICP, and have been independently associated with poorer patient outcome. PbtO2 values lower than 15 mmHg for more than 30 minutes were shown to be an independent predictor of unfavorable outcome and death. The aggressive treatment of low PbtO2 was associated with improved outcome compared to standard ICP/CPP-directed therapy in cohort studies of severely head-injured patients. On the basis of these findings, it is hypothesized that an early optimization of brain oxygenation, together with keeping ICP and CPP within recommended values, could reduce the volume of vulnerable lesions following severe TBI and possibly improve neurological outcome.

This study examines the effect of inhaled xenon gas in the treatment of newborn infants with hypoxic-ischemic encephalopathy (HIE) in combination with cooling, which is the standard treatment for this condition. The hypothesis is that the xenon + cooling combination will produce better neuroprotection than the standard treatment of cooling alone.

New 2010 neonatal resuscitation guidelines state that offering therapeutic hypothermia (TH) should be a standard of care in managing neonates with perinatal hypoxic - ischemic insult and present with signs of moderate and/or severe hypoxic - ischemic encephalopathy (HIE) . Despite the evidence from several randomized control trial (RCT) proving its effectiveness, its effect is perceived insufficient or only modest. Thus today's research efforts are directed toward finding the new possibilities of enhancing the effects of hypothermia. List of agents with potential neuroprotective properties includes: erythropoetin, melatonin, topiramate, morphine, xenon, MgSO4. Given investigators previous experiences with preterm neonates exposed to MgSO4 prenatally or administered this drug after birth because of perinatal asphyxia, the investigators designed the trial which would evaluate the possibility of increasing the TH effect by combining this method with MgSO4. Until now there are several published studies evaluating the effectiveness of MgSO4 in the group of asphyxiated neonates, including one RCT. However, all of these studies were conducted before the era of TH Furthermore, irrespective of the potential benefits, safety of using MgSO4 during TH in the group of term neonates was not studied. It is particularly important in the light of the results presented by Mittendorf et.al. They studied the effects of prenatal aggressive treatment with MgSO4 on the outcome of preterm neonates showed that patients exposed to high doses of MgSO4 were at higher risk of severe intracranial bleeding. Other side effects of high serum magnesium levels are: vasodilatation, hypotension, cardiac arrhythmias, coagulopathy, and gastrointestinal disturbances. MgSO4 is a very attractive neuroprotective option,also because of its easy availability. Drug can be administered in the birth hospital while neonate is being prepared for the transport to TH center. Timing of the intervention is very important for neonates suffering from perinatal asphyxia. Both TH and administration of potentially neuroprotective drug should be started during "therapeutic window". It is the initial potentially reversible phase of hypoxic insult lasting about 6 hours. If the long-term follow up shows that MgSO4 has an additive neuroprotective effect and no significant side effects in the group of asphyxiated neonates treated with TH this relatively simple and not expensive intervention may be introduced into clinical practice