Active clinical trials for "Brain Injuries"

The purpose of this study is to evaluate a multi-disciplinary, multi-setting intervention with the goal of improving outcomes for children who have experienced a mild traumatic brain injury (mTBI). The project aims to improve and support mTBI diagnosis and management, and improve critical decision making by clinicians during their interaction with the injured child, their family, and their school.

The EPO-TRAUMA study is a prospective, multi-centre, double-blind, phase III, randomised controlled trial evaluating the efficacy of epoetin alfa compared to placebo in reducing mortality and severe disability at six months in critically ill trauma patients. 2500 mechanically ventilated ICU patients admitted with a primary trauma diagnosis presenting to the ICU will be recruited into the study from participating study centres in Australia, New Zealand, Europe, and Saudi Arabia.

The most persistent and disabling postconcussive symptoms following mild traumatic brain injury (mTBI) are sleep disturbances and cognitive dysfunction, with few tractable interventions currently available. Here, a novel therapy will be tested consisting of dietary supplementation with branched chain amino acids (BCAA), based on the study team's previous preclinical work showing restoration of glutamate neurotransmitter balance in sleep and memory circuits. Supplementation with Amino acid Rehabilitative Therapy in TBI (SmART-TBI) is a randomized, placebo-controlled, double-blinded, exploratory clinical trial of BCAA intended to establish the feasibility, acceptability, and limited efficacy of long-term BCAA to improve sleep and cognition in Veterans with mTBI. These results will inform the optimal study design of a future, full-scale randomized controlled trial, including the identification of the proper dose and duration of BCAA to improve sleep and the potential subpopulations of Veterans with mTBI that may benefit the most.

With an average of 21,000 diagnosed brain injuries each year among military personnel, traumatic brain injury (TBI) remains a major health concern for the United States Military Health System. Mild traumatic brain injury (mTBI) is the most common type of brain injury sustained by military personnel and may result in chronic cognitive impairment.Unfortunately, many service members (SMs) have a history of multiple head injuries as well as psychological co-morbidities that negatively influence recovery. Advances in treatment options for cognitive rehabilitation following mTBI have been of increasing interest to the medical community and may increase treatment efficacy for injured SMs to ensure force readiness. Cognitive Rehabilitation (CR) for severe brain injury focuses on compensatory strategies for activities of daily living such as using lists to remember grocery items or reminders to take medications and attend medical appointments. Research has shown CR interventions to have considerable effectiveness in the acute and sub-acute phase of recovery after severe TBI. But there is insufficient evidence that they improve rates of individuals returning to work, independence in activities of daily living (ADL), community re-integration, or quality of life.

Patients with a history of traumatic brain injury (TBI) are at elevated risk for Alzheimer's disease and related dementias (ADRD). Improvements in TBI treatment may mitigate this risk. Complex motor activities, which combine physical and cognitive demands, have been shown to have well established neurocognitive benefits. This study seeks to address the need for novel TBI interventions optimized for adults with history of TBI by determining the effectiveness of an immersive computer game designed to integrating complex cognitive-motor interventions.

This study will use technology to deliver effective treatment for cognitive problems associated with TBI to Veterans at home, which may result in improved daily functioning and increased access to health care for the growing population of aging Veterans with history of TBI. The successful completion of this project may also increase older Veterans' ability to participate in research through increased understanding of the effect of in-home research opportunities on recruitment and retention. Additionally, the evidence gathered from this study may be used in future research studying home-based cognitive rehabilitation treatments for Veterans using telehealth technology.

In severe brain-injured patients, it is recommended to strictly control the fever in order to limit brain damage (objective of neuroprotection) via the targeted temperature management (TTM). In the guidelines, the target temperature is the systemic temperature, just for practical reasons (brain temperature not being monitored in most polyvalent ICU). However, in NICU, the brain temperature is monitored routinely via the Intra-Cerebral Pressure (ICP) sensor. Since in the febrile brain-injured patients the objective of the TTM is neuroprotection, it would be more appropriate to target temperature control over the cerebral temperature. The objective of this study is to evaluate the efficacy of TTM directly coupled to the brain temperature. Adult patients with brain injury requiring ICP monitoring (Pressio 2, Sophysa France) and fever requiring TTM (cerebral greater than or equal to 38.5 °C) will be enrolled. The TTM will be carried out according to the usual methods of the investigator's service: external cooling devices coupled with cerebral temperature (Artic Sun, Bard France), including two phases: the cooling phase (H0 to H3) and the maintenance phase (from H3 to the end of the cooling). Two groups will be formed. In the interventional group, coupling of the TTM will be carried out to the cerebral temperature. In the control group, coupling of the TTM will be carried out to the systemic temperature measured at the bladder site. The primary outcome will be the percentage of time during which the cerebral temperature will be measured within recommended target temperature range (i.e. 36 to 37 °C) during the maintenance phase (H3 to H12): comparison of averages. Cerebral hemodynamic parameters (ICP, transcranial doppler, and brain tissue oxygen partial pressure if available) will also be collected, in order to be correlated with the delta temperature (cerebral temperature minor systemic temperature). No medical device will be put in place specifically for the need of the study.

Traumatic Brain Injury is a major health concern in United States. There is a un-met need to develop new therapeutic options for faster neuron recovery without causing significant side effects. The role of ketones in neuronal recovery has been studied and has been found to be useful in decreasing size of contusion. The present study aims to study the safety and feasibility profile of ketogenic diet.

Individuals will be recruited from the VA Portland Health Care System and the community affiliated with Oregon Health & Science University. Traumatic brain injury status will be assessed as a contributing factor. Subjects will be randomized to one of 3 groups (BCAA or one of 2 placebo conditions) and instructed to consume study product twice daily for 21 days. Self-report questionnaires, wrist actigraphy, pressure pain testing, and cognitive function will be assessed pre and post the experimental period.

Stroke is the leading cause of long-term disability with an increasing incidence, especially in young adults. Among the cognitive difficulties following brain damage, deficits in attention are frequent and pervasive, affecting between 46% and 92% of stroke survivors. The current project targets patients with acquired brain injury, including stroke, traumatic brain injury, and brain tumor. The main objective of this study is to evaluate the use and the efficacy of a training program targeting attention and executive function difficulties, using gamified and digitized versions in virtual reality of standard cognitive exercises for patients with brain lesions.