View clinical trials related to Traumatic Brain Injury.
Filter by:This project will develop a wearable rehabilitation robot suitable for in-bed acute stage rehabilitation. It involves robot-guided motor relearning, passive and active motor-sensory rehabilitation early in the acute stage post-TBI including patients who are paralyzed with no motor output. The early acute TBI rehabilitation device will be evaluated in this clinical trial.
Our project aims to develop a rapidly acquired and communicated MRI assessment and report that incorporates functional and structural imaging to convey information about functional neurological insults following traumatic brain injury (TBI) that are not typically visible on clinical imaging. Within this framework, there are two sub-studies. The first is a prospective study of patients with TBI who will have an MRI in the sub-acute period after their injury, followed by clinical assessments up to 90 days post-injury. A model will be developed to link MRI biomarkers to persistent symptoms of TBI. The second sub-study will use a focus group methodology to develop the report content and format with input from several groups of stakeholders.
The clinical investigation aims to advance the Crainio device, designed for non-invasive intracranial pressure (ICP) monitoring. This feasibility study involves 54 participants over a 12-month period and seeks to collect cerebral photoplethysmogram signals alongside concurrent invasive ICP measurements in patients with traumatic brain injury. The primary objective is to establish the diagnostic accuracy of the Crainio device, aiming for at least 90% sensitivity and specificity in detecting raised ICP (above 20 mmHg). Secondary objectives include evaluating patient-related factors such as skin tone, skull thickness, and skull density, as well as the tolerability and acceptance of the device by both patients and healthcare professionals.
The relationship between obesity and the development of chronic headache after traumatic brain injury will be investigated.
The aim of this randomised multicentre clinical feasibility and pilot trial is to test if a sit-to-stand trial protocol is feasible regarding the increased intensity, trial recruitment, and completion of outcome data in patients with moderate to severe traumatic brain injury during the rehabilitation phase. For the trial to be feasible, all outcomes must be achieved. The primary hypothesis is that it is feasible to progressively increase the number of repetitions of sit-to-stand exercises in patients with moderate to severe traumatic brain injury admitted to a rehabilitation department during the intervention period. Furthermore, the investigators hypothesize that the increased number of repetitions will increase the participant's functional capabilities regarding sit-to-stand and walking, decrease resting heart rate, blood pressure, and metabolism, reduce inflammatory and brain injury biomarkers, and improve the cognitive performance.
A prospective, multicenter, observational cohort study is designed to compare the effectiveness of intervention in multi-grade hospitals for acute traumatic brain injury and to optimize clinical outcomes.
Drilling or puncture drainage is commonly used in TBI patients with subdural effusion following decompressive craniectomy who fail to respond to conservative treatment, but there is no exact regulation or guideline recommendation for the drainage time. The investigators aimed to conduct a randomized controlled trial to evaluate the efficacy and safety of long-term versus short-term drainage in the treatment of subdural effusion after decompressive craniectomy in patients with traumatic brain injury.
The purpose of this research, which has been determined as non-significant risk by the central IRB overseeing the study, is to obtain information to help further develop a machine (a medical device) to measure the pressure around the brain from the outside (this pressure is called intracranial pressure or ICP). Monitoring and managing ICP is an important part of care for patients with conditions such as Traumatic Brain Injury (TBI). However, the current way of measuring ICP requires surgery to drill a hole into the skull, and therefore can introduce additional risks such as infections and pain. Recent research has shown it may be possible to measure ICP without needing surgery. This technology is in development, but large amounts of data is required to build these new devices. Through collecting a large database of information from patients who have both the routine surgical device and the research device applied to their head, the research team will work to develop and test an effective and potentially safer way of monitoring patient ICP.
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.
The goal of this clinical trial is to explore Clinical Effect of Myofascial Release Therapy in Dysphagic Traumatic Brain injured Survivors. The main question it aims to answer is: • Can Myofascial Release Therapy improve swallowing function in Traumatic Brain injured Survivors? Patients will be randomly allocated into the control group or the experimental group, all under rehabilitation treatment, the experimental group will be given Myofascial Release Therapy. The study lasts 21 days for each patient. Researchers will compare the Functional Oral Intake Scale, Penetration-Aspiration Scale, Swallowing Quality of Life to see if the Myofascial Release Therapy can help improve the situation.