View clinical trials related to Brain Injuries, Traumatic.
Filter by:The primary objective of this study is to evaluate the feasibility and safety of using the ketogenic diet (KD) in children who sustained moderate to severe traumatic brain injury (TBI). The secondary objective is a preliminary evaluation of the outcomes of children who have had the standard of care plus the KD, compared to those with standard of care alone. Outcome measures for the secondary objective will include: need for ventriculoperitoneal shunt, duration of unconsciousness, need for any type of craniotomy, duration of post-traumatic amnesia, acute hospitalization length of stay, and cognitive and motor function at 12 months after injury. If this study demonstrates feasibility and safety, the information related to outcomes will be used to inform the planning of a future, larger, randomized study of the efficacy of the KD in children and adolescents with TBI. Specifically, this information will be used to assist with sample size calculations for this future study.
Sleep wake disturbances compound recovery in over half of pediatric traumatic brain injury survivors, leading to impaired quality of life, and few effective interventions exist to treat this important morbidity. Therefore, this study will conduct a randomized controlled trial evaluating a melatonin intervention started during hospitalization and continued after discharge compared to placebo. The trial will investigate if this intervention is feasible, acceptable, and effective at reducing sleep wake disturbances as measured on the Sleep Disturbances Scale for Children 1-month after hospital discharge. Participants will be randomly assigned to receive the intervention (melatonin) or to the control group (placebo) with a goal of equal numbers of participants in each group and all will receive sleep education. Participants will be followed closely after consent and outcomes will be assessed at hospital discharge, and 1-month. Outcomes will focus on feasibility (ability to recruit patients into the trial) and acceptability (patient safety and satisfaction), but will also assess the effectiveness of the intervention to reduce sleep disturbances after discharge. The investigators will assess sleep using questionnaires and actigraphy (watch-like activity monitors). Exploratory outcomes will include global health outcomes.
The Bioness Integrated Therapy System (BITS) (Bioness Inc. Valencia, CA) Touch Screen is an FDA approved device comprised of an interactive touchscreen and diverse program options to challenge patients through the use of visual motor activities, visual and auditory processing, cognitive skills, and endurance training. The purpose of this study is to enroll a small group of adults currently undergoing inpatient rehabilitation, who were admitted for an acute neurological event and present with an acute neurological visual field impairment. The primary objective is to compare any increase in visual field awareness using a prescribed regimen consisting of conventional vision exercises compared with a regimen using BITS touch screen technology. Participants will be alternately assigned into "A" and "B" groups upon enrollment. The control group "A" will be prescribed conventional (table top, pen and paper) vision interventions provided by an occupational therapist and will receive pre- and post- assessment of visual field awareness. Treatment group "B" will include a prescribed regimen with use of BITS touch screen technology. Group B participants will receive the same pre- and post- assessment of visual field awareness as Group A participants. The hypothesis is that incorporation of the BITS touch screen technology, being more interactive, will result in better outcomes for visual field awareness. This is an unblinded quasi-randomized control trial that will determine best treatment intervention for visual field impairment. Safety will be measured by the number of reported adverse events. The study period will include 6 sessions per participant, conducted at one site, with the objective of enrolling at least 30 participants to have 15 participants in each study group.
Traumatic brain injury (Traumatic brain injury, TBI) can be derived from various forms of injury, including blunt trauma, penetrating or acceleration/deceleration force caused by head injury.There are some study data show that acupuncture treatment has a superficial effect on the prognosis of traumatic brain injury and can limit the progression of secondary brain injury, but the effect of early bloodletting at the Jing-points on TBI patients still unknown. In our study, the investigators have proposed a randomized, controlled study design and plan to evaluate the efficacy and safety of Jing-point puncture to improve consciousness and neurological function in patients with TBI. In addition, an objective meridian instrument analysis was added to analyze the energy distribution in the meridian of TBI patients.
In this study, high-throughput screening and multi-omics (transcriptomics and proteomics) joint analysis technology will be employed to explore potential CTE/TES biomarkers (RNA and protein) in blood and its exosomes. Thereafter, these biomarkers will be combined with the reported TBI biomarkers to create a novel set of CTE/TES molecular diagnostic signatures. The findings may open a new avenue for the clinical diagnosis of the disease and the future research on its therapeutic strategy.
In this study, the single-cell transcriptome sequencing technology was used to study the transcriptome differences at the single-cell level in normal human brain, aging human brain, and epileptic brain.
The proposed study will evaluate a new approach to cognitive rehabilitation of mild traumatic brain injury (mTBI) using a brain stimulation technique called transcranial direct current stimulation (tDCS). Specifically, we will investigate how tDCS combined with cognitive training improves deficits to attention and working memory in Active Duty Service Members with a history of mild traumatic brain injury (TBI). Measures of attention-related brain activity, neurocognitive assessments, and self-reported clinical outcomes will be used to determine effects of tDCS vs. sham tDCS when paired with a cognitive training intervention. By doing this study, we hope to find a reliable, noninvasive, and efficient method of treating mild TBI cognitive symptoms.
When patients survive a severe brain injury but fail to fully recover, they often enter a Disorder of Consciousness (DoC) --that is, a set of related conditions of decreased awareness and arousal including the Vegetative State (VS) and the Minimally Conscious State (MCS). When these conditions become chronic, there are no approved treatments to help bolster any further recovery. In prior work, we have shown the clinical feasibility and potential of Low Intensity Focused Ultrasound Pulsation (LIFUP) as a remarkably safe form of non-invasive brain stimulation in these conditions.
Nepal is a low-income country with over 3 million individuals with physical disabilities and currently no government-run specialist rehabilitation services. The aim of this research proposal is to work in partnership with a Nepal Non-Governmental Organisation (NGO), the Spinal Injury Rehabilitation Centre (SIRC, Nepal) to achieve the following: 1. estimate the rehabilitation needs in individuals after stroke, brain injury and spinal cord injury in rural communities after discharge from SIRC 2. hold user and stakeholder workshops to explore the role of multidisciplinary teleconferencing methods for remote assessment and management and agree systems for piloting 3. deploy and pilot a novel telerehabilitation system to improve the lives of these individuals, and evaluate it in terms of feasibility and acceptability
The purpose of this study is to evaluate if theta burst stimulation (TBS) can reduce chronic headaches caused by a traumatic brain injury (TBI). TBS is a safe, drug-free brain stimulation technique that uses magnets to create electricity and stimulate nerve cells in the brain. After repeated TBS sessions, the increased stimulation of nerve cells can alter the way the brain communicates with itself (by creating new neural pathways) which, in turn, can reduce pain symptoms. Participants in this study will complete a baseline assessment followed by four weeks of daily home headache assessment. Participants will then receive four weeks of TBS administered three times per day and three days per week. After TBS is completed, participants will complete an additional four weeks of daily home headache assessment and return for a one-month follow-up assessment. Participation is expected to last three months.