View clinical trials related to Traumatic Brain Injury.
Filter by:The main goal of this clinical trial is to check if the treatment is safe and well-tolerated. Researchers will compare the MR-301 active drug group with the placebo group to evaluate the safety and tolerability of the drug. Other measurements include assessing the patient's overall outcome, neurological responses, time spent in the intensive care unit, time in the hospital, and mortality. Participants will receive either MR-301 BID IV dosing or a matching placebo for a total of 3 weeks.
This was a multicenter randomized controlled study of 98 severe Traumatic Brain Injury patients with tracheostomy. Patients enrolled were divided randomly into the observation group with Intermittent Oro-esophageal Tube Feeding or the control group with Nasogastric tube feeding for enteral nutrition support, respectively. Nutritional status, complications, decannulation of tracheostomy tubes and level of consciousness on day 1 and day 28 were recorded and compared.
This was a multicenter randomized controlled study of 98 severe Traumatic Brain Injury patients with tracheostomy. Patients enrolled were divided randomly into the observation group with Intermittent Oro-esophageal Tube Feeding (n=50) or the control group with Nasogastric tube feeding (n=48) for enteral nutrition support, respectively. Nutritional status, complications, decannulation of tracheostomy tubes and level of consciousness on day 1 and day 28 were recorded and compared.
Enhanced recovery after surgery (ERAS) is a strategy of perioperative management aimed to accelerate the rehabilitation of patients through various optimized perioperative managements as well as ongoing adherence to a patient-focused, multidisciplinary, and multimodal approach. Alleviating the injury and stress caused by surgery or disease is the core principle of ERAS, which has been shown to reduce complication rates after surgery, promote patient recovery, decrease hospital length of stay and reduce costs. ERAS has been widely applied in many surgical perioperative fields, and it has achieved remarkable effects. However, there are few applications of ERAS in neurosurgery, especially in clinical trials of neurocritical care patients. Therefore, the investigators attempt to conduct the study of ERAS in neurosurgical intensive patients using a series of optimized perioperative managements that have been verified to be effective by evidence-based medicine, and to evaluate the safety and effectiveness of ERAS in neurocritical care. The aim of this study is to explore the most suitable ERAS protocols to accelerate the postoperative rehabilitation process of neurocritical care patients, and to provide more evidence-based medicine for the effectiveness and safety of ERAS in neurosurgery.
The goal of this clinical trial is to investigate the impact of daily self-administered transcranial direct current stimulation (tDCS) therapy on the cognitive function of individuals with moderate to severe cognitive impairment resulting from a traumatic brain injury (TBI). The study aims to answer the following questions: Does daily self-administered tDCS therapy, when combined with computerized cognitive training (CCT), improve cognitive function in TBI patients? Is CCT+tDCS with anodic stimulation more effective than CCT+tDCS with simulated stimulation in enhancing immediate and one-month post-treatment cognitive function? Does CCT+tDCS with anodic stimulation lead to better functionality immediately and one month after treatment compared to CCT+tDCS with simulated stimulation? Does CCT+tDCS with anodic stimulation have a positive impact on mood improvement immediately and one month after treatment compared to CCT+tDCS with simulated stimulation? Participants in the study will engage in CCT through a smartphone or tablet application and self-administer tDCS therapy for 20 minutes each day for a duration of one month. The tDCS therapy will involve applying a 2 mA anodic current to the prefrontal dorsolateral cortex (PFDL). Prior to the intervention, patients or their caregivers will receive training on the proper and safe usage of the tDCS device. Cognitive function, mood, and functionality will be evaluated before and after the intervention using appropriate measurement scales. The outcomes of this clinical trial have the potential to identify an effective and accessible therapeutic approach to enhance cognitive function in individuals with moderate to severe TBI. The combination of tDCS therapy with CCT offers an appealing and feasible treatment strategy for these patients, particularly when conducted in a home setting. The findings from this study will guide future clinical trials in the field of cognitive rehabilitation for TBI patients. Researchers will compare active tDCS with sham tDCS to determine if there are differences in the primary outcomes mentioned.
The goal of this clinical trial is to examine the use of sedative ketamine to treat depression and post-traumatic stress disorder (PTSD) in Veterans with mild to moderate traumatic brain injury (TBI). The main questions it aims to answer are: - Efficacy of ketamine to reduce symptoms of depression and/or PTSD - Safety of ketamine to treat depression and/or PTSD in TBI Participants will be randomly assigned to receive either ketamine or midazolam (active placebo) twice a week for 3 weeks. During participation, subjects will be interviewed, have lab tests, and complete rating scales, and questionnaires.
The goal of this or clinical trial is to explore efficacy of stellate ganglion block on dysphagia and activities of daily living in Traumatic Brain Injury Patients. The main question it aims to answer are: Can stellate ganglion block improve the dysphagia and activities of daily living in Traumatic Brain Injury Patients. Traumatic Brain Injury Patients will be divided into the the control group and observation group evenly. All the patients were provided with routine therapy, while the patients in the observation group were given stellate ganglion block. The swallowing function, and activities of daily living of the two groups of patients before and after treatment were evaluated.
The goal of this study is to test the effect of a planning, reminders, and micro-incentives intervention verses regular health education facts on physical activity participation over 12-weeks, in older adults who have previously suffered a non-penetrating mild or moderate TBI. Participants will provide information and be screened for eligibility via phone screening call (verification of age, confirmation that the participant is not currently on any medication that affects the central nervous system, and verification that the subject can participate in exercise, brief TBI history). Baseline testing will take place at the Center for Cognitive and Brain Health and Northeastern University Biomedical Imaging Center, for the baseline magnetic resonance imaging, in the interdisciplinary science and engineering complex on Northeastern University's campus. In person testing will take place over one session. The study period lasts 12 weeks, during which all participants will 1. Receive a weekly phone call with study staff, 2. Wear a wrist-worn Fit Bit tracker and 3. Record their weekly walking activities.
Older veterans with a history of mild brain trauma exhibit early cognitive challenges, especially in driving-related tasks. This is attributed to alterations in the brain's excitatory/inhibitory (E/I) balance. This pilot project investigates this phenomenon by leveraging electroencephalography (EEG) to measure parietal lobe alpha rhythms during visual attention tasks. The hypothesis is that targeted visual attention training can modulate these alpha rhythms, improving instrumental activities in daily life. However, outcomes from such training vary, possibly due to individual differences in cortical inhibitory functions. This study will assess the relationship between EEG measures of E/I balance pre- and post-visual attention training and its effects on processing speeds in aging veterans. Our findings aim to provide a foundation for customized therapies and interventions for veterans with and without a history of brain trauma.
The goal of this clinical trial is to demonstrate communication through a brain implant in people in locked-in state, i.e. people with severe paralysis and communication problems. The main questions it aims to answer are efficient and stable control of Brain-Computer interface (BCI) functions for communication with attempted hand movements and operation of a keyword-based speech BCI. Participants will be implanted with four electrode grids, with in total 128 electrodes, on the surface of the brain and a connector on the skull. Participation includes visits of researchers for recording and training at home, 2-3 times per week for one year. Extension of participation after one year is possible. If successful, the participant will be able to use the BCI at home independently, without the presence of a researcher.