Active clinical trials for "Brain Injuries"

EEG signals have been collected and studied since the early 1990's as a way of assessing brain function at a gross level. As early as the 1930's a derivative of the raw EEG signal - event-related potentials (ERPs) - have been computed. The current research is primarily focused on three ERP components: the N100, P300 and N400. Each of the three ERPs have been studied in the academic laboratory for multiple decades. Through this research, a strong understanding has been developed regarding what can affect these components (e.g. task set, emotional state, etc.). However, these signals within various pediatric populations (e.g., those with persistent mTBI symptoms or multiple concussions) are not well characterized. Being able to safely and effectively employ the NeuroCatch™ Platform in a post-concussive pediatric cohort could provide researchers with the potential to elucidate the persistence of objective measures of impairment, patterns of recovery, and chronicity of problems due to mTBI in children. Secondly, understanding the degree to which these neurophysiological components fluctuate over time is crucial to the understanding of brain functioning. However, for this type of technology to be useful in quantifying brain health in this population,the degree to which a post-concussive pediatric brain naturally fluctuates in its processing capability must be quantified. NeuroCatch™ Platform has the ability to measure changes in several domains of brain function. These cognitive processes are foundational blocks for some of the highest cognitive processes: information integration and executive functioning.

Madonna's Rehabilitation Engineering Center of Excellence (REC) is continually developing custom devices for persons with disabilities. These devices are created to improve the independence of individuals living with disabilities at Madonna Rehabilitation Hospitals and in the community. The purpose of this study is to investigate the impact custom assistive and adaptive devices have on patient independence, quality of life, and experience at Madonna Rehabilitation Hospitals.

Utilization of diagnostic imaging in the Emergency Department has increased dramatically over the past two decades, driven by an increased availability of advanced imaging, legal pressures to exclude serious diagnoses in low-risk patients, patient expectations, and the tendency to associate more testing with a higher quality of care. However, this rise in the use of diagnostic imaging, particularly in low-risk patients, may not be taking into account the risk of radiation exposure to patients, or the impact on finite health system resources. The objective of this project is to improve the appropriateness of CT imaging in Alberta Emergency Departments by advancing awareness of, and adherence to, evidence-based guidelines for CT imaging of patients with mild traumatic brain injury (MTBI) and suspected pulmonary embolism (PE). These two clinical scenarios have been selected because of evidence of significant variation in imaging practices across Alberta, and the robust evidence base that exists to guide CT imaging decisions such as the Canadian CT Head Rule and the Pulmonary Embolism Rule Out Criteria.

Family caregivers of persons with traumatic brain injury (TBI) have long-term demands that tax their coping abilities and adversely affect their health and well-being. This project will test the effectiveness of a problem-solving training program tailored to the unique needs of family caregivers of persons with TBI. Over a 3-year period, family caregivers and their care recipients will be recruited and randomly assigned to a problem-solving intervention group (n=40 dyads) or a control group (n=40 dyads). Participants in the problem-solving intervention group will receive four face-to-face problem-solving training sessions and monthly telephone problem-solving sessions over the course of 1 year. Control group participants will receive a handbook of educational materials and a staff member will contact each control group participant monthly by telephone to review these materials and other informational needs. No problem-solving training will be provided to control participants throughout the year. Caregivers and care recipients will be assessed at four points during their participation: at the initial assessment, at 4 months, at 8 months, and at the completion of the 1-year participation period. All evaluations will be conducted in the participants' homes. Measures of problem-solving ability, caregiver burden, and adjustment (depression, health, satisfaction with life) will be collected. Structural equation modeling and other regression/inferential analyses will be used to determine the effects of problem solving on caregiver adjustment over time after taking into account care recipient adjustment and caregiver ethnicity. This project will: (1) demonstrate how specified physical and emotional outcomes of caregivers and care recipients are related to caregiver problem-solving abilities and how these relationships vary as a function of time; (2) evaluate the effectiveness of a community-based, problem-solving intervention that will be delivered to caregivers; and (3) identify caregivers and care recipients with TBI who are at risk for adverse emotional and health outcomes.

After an acquired brain injury (ABI), children often require extensive physiotherapy (PT) to help them relearn to walk. There is promising evidence in pediatric neuro-motor conditions of the possibility for brain activation pattern changes in response to repetitive, task-oriented functional gait training. Robotic-assisted gait training devices such as the Lokomat (LOK) allow this type of intensive walking retraining. The aim of this study is to assess the safety, feasibility and outcome possibilities linked to a LOK intervention given as 2 of the child's 4 PT weekly sessions over 8-weeks in the early stages of rehabilitation after an ABI.

To observe the effect of PEEP on CVP among patients with different respiratory compliance

There is a pressing need to develop more effective interventions to remediate cognitive deficits in highly prevalent disabling conditions such as stroke, head injury and other forms of acquired brain injury (ABI). Neuropsychological rehabilitation interventions developed in a clinical setting have shown some beneficial effects, but the effectiveness of clinical interventions have potential to be enhanced if informed by findings from cognitive neuroscience. Research into cognitive training using methods such as functional magnetic resonance imaging (fMRI) has contributed to an understanding of factors that promote changes in brain function, but this approach seldom includes individuals with brain damage or cognitive deficits. Its potential for application with clinical populations is therefore uncertain, meaning that people who may benefit do not have access to interventions that may improve their health and wellbeing. The proposed research brings together methods from neuropsychological rehabilitation and cognitive neuroscience to investigate 1) the feasibility of, and effect sizes arising from, combining an existing clinical intervention targeting mental strategies with an adaptive training programme targeting core cognitive processes, and 2) whether the novel treatment combination promotes changes in brain function that are detectable using fMRI. This project will develop and evaluate a training intervention that aims to improve outcomes from a strategy-based rehabilitation intervention, Goal Management Training (GMT), by adding process-based cognitive training with adaptive difficulty to enhance the executive function of working memory updating (WMU). People with ABI (n=32) will complete 9 sessions of GMT, a recommended treatment for deficits in frontal-lobe executive functions, with the addition of 8 WMU training sessions with or without adaptive training. Measures of feasibility, acceptability, and fidelity will be taken, and effect sizes of differences in pre- to post-training changes on neural, cognitive, and functional measurements will be determined by comparing two experimental groups in which difficulty of the WMU training tasks either adaptively increases in response to performance or is fixed.

Performance Validity Tests (PVTs) are widely used for the detection of sub-optimal effort and malingering in neuropsychological assessments. Threats to their validity however likely to intensify with time (e.g., information available on the web or from legal representatives) and may lead to a decline in their ability to differentiate between malingerers and non-malingerers. Eye movements and response time (RT) are less obvious outcome measures and under less conscious control than more conventional PVT indices (e.g., accuracy). They are therefore promising measures that can aid in detecting malingering when used in conjunction with more conventional PVT indices. The Word Memory Test (WMT) is a widely used PVT in neuropsychological evaluations. As part of the proposed study, TBI patients, chronic pain patients and healthy adults (60 in each group) will be randomly divided to one of two conditions; optimal effort or sub-optimal effort (participants will be asked to play a TBI patient who wishes to present himself as having cognitive deficits or exaggerate existing cognitive deficits). The proposed study will improve the WMT's efficacy in detection of sub-optimal effort in neuropsychological evaluations and therefore protect its validity from future threats. In addition, the proposed study will provide us with better understanding of the effect of TBI on eye movements and RTs in general.

Traumatic brain injury (TBI) is a leading cause of death following injury in civilian populations and is a major cause of death and disability in combat casualties. While primary brain injury cannot be reversed, the management of severe TBI focuses on the mitigation of secondary injury mechanisms which occur as part of the downstream effects of the primary damage to the brain. Many secondary injury mechanisms are manifested clinically as elevated intracranial pressure (ICP) and cerebral perfusion pressure (CCP). This level and duration of elevated ICP is strongly associated with poor long term patient outcome. Currently, there are two invasive techniques that are used at our facility for monitoring ICP and CPP. The first method requires the placement of an intra-parenchymal fiberoptic pressure monitor (IPM), also known as a camino, into the brain tissue that measures and displays ICP continuously. The second method requires placement of an extracranial ventricular drain (EVD) which both measures ICP when it is closed or clamped and also allows for therapeutic drainage of cerebral spinal fluid (CFS) to reduce pressure within the skull when it is open. While clinical practices vary greatly across institutions, current clinical practice at our institution when using the EVD for ICP management is to allow continuous therapeutic CSF drainage and to manually close the drain for ICP assessment on an hourly basis. However, in a retrospective of study of TBI patients at our institution with simultaneous IPM and EVD placement, a spike in ICP was noted to correspond with the clamping of the EVD which often remained elevated for 15-30 minutes before returning to baseline. Due to the strong association between poor patient outcome and elevated ICP, this finding is alarming. These findings have important implications for procedures to not only treat elevated ICP, but also prevent potentially harmful intermittent elevations in ICP. Therefore, this study seeks to prospectively investigate the association between EVD clamping and elevated ICP. Specifically, this study has 2 main objectives: Evaluate the need for an optimized device that can simultaneously measure intracranial pressure and drain CSF without requiring potentially harmful clamping. Provide data in support of retaining or modifying current clinical practices regarding intermittent versus continuous monitoring during periods of therapeutic drainage of CSF.

The study will provide information on cognitive impairment and Health related quality of life in patients surviving 12 months after acute brain injury, generate a hypothesis of useful variables to predict cognitive impairment or low levels of HRQoL, and potentially inform interventions for the prevention and treatment of cognitive impairment following neuro-ICU stay.