View clinical trials related to Traumatic Brain Injury.
Filter by: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.
Evaluate the effect of tranexamic acid on mortality in pediatric patients with traumatic brain injury. This could potentially lead to improved treatment protocols and better outcomes for this vulnerable population.
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.
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.
Intensive care management of patient with severe traumatic brain injury (TBI) includes deep and prolonged sedation with intravenous hypnotics (propofol, midazolam, ketamine) in combination with opioids to prevent and/or treat episodes of intracranial hypertension. However, some patients may develop tachyphylaxis with a gradual increase of administered intravenous hypnotics and opioids to maintain the same level of sedation. This situation leads to a failure in controlling intracranial pressure (ICP) and/or to the risk of adverse effects due to high-dose sedatives: haemodynamic instability, prolonged mechanical ventilation, neuromyopathy, delirium, withdrawal syndrome. Halogenated agents (Isoflurane, Sevoflurane) are a class of hypnotics routinely used in the operating room. However, doses used in surgical patients (> 1 Minimal Alveolar Concentration, MAC) are not suitable in neuro-intensive care unit (ICU) patients at risk of intracranial hypertension because of the cerebral vasodilator effects of halogenated agents at this dosage, hence the risk of high ICP and compromised cerebral perfusion pressure. The use of halogenated agents has been recently possible in the ICU through dedicated medical devices (Sedaconda ACD, Mirus). Recommended dosage are lower in the ICU, i.e. 0.3-0.7 MAC, because of their association with intravenous hypnotics and the absence of surgical stimuli. Several clinical studies in general ICUs showed improved sedation quality, reduced duration of mechanical ventilation, faster arousal and shorter extubation time, and lower costs in halogenated group compared with control group receiving midazolam or propofol. At low doses, the effects on ICP and intracerebral haemodynamics of halogenated agents are minor according to the available literature. In addition, beneficial effects were found on cerebral ischaemic volume in animal models treated with halogenated agents. However, there is a need to explore the benefit-risk ratio of the use of halogenated agents in the severe TBI population. The investigator hypothesise that 0.7 MAC Isoflurane can be administered in this population without deleterious effect on ICP.
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 purpose of this research is to understand and treat Traumatic Brain Injury (TBI) associated photophobia (light sensitivity) and its impact on visual function.
A prospective, multicenter, randomized controlled, open-label, blinded endpoint evaluation study.
The goal of this clinical trial is to test the safety of the drug Angiotensin (1-7) and learn whether it works well as a treatment in people who have suffered a moderate to severe traumatic brain injury (TBI). The main questions this trial aims to answer are: - Is Angiotensin (1-7) safe? - Does Angiotensin (1-7) improve mental functioning and reduce physical signs of brain damage in people who have suffered a moderate to severe TBI? Participants will: - Complete 21 days of study treatment consisting of a once-daily injection. - Provide blood samples. - Undergo two magnetic resonance imaging (MRI) scans of the brain. - Complete specific tasks and questionnaires that allow researchers to evaluate the participant's brain and psychological functioning. Researchers will compare three groups: two groups that receive different doses of Angiotensin (1-7) and one group that receives a look-alike treatment with no active drug. This will allow researchers to see if the drug has any negative effects and whether it improves mental functioning and physical signs of brain damage after a TBI.