View clinical trials related to Traumatic Brain Injury.
Filter by:Neurogenic dysphagia occurs with disruption of neurological systems or processes involved in the execution of coordinated and safe swallowing. It is common in patients with neurological diseases, in particular in patients treated in Intensive Care Units (ICU) who are intubated (up to 62%) and / or tracheotomised (up to 83%). Dysphagia is one of the most common and most dangerous symptoms of many neurological diseases. In addition, neurogenic dysphagia can have a significant impact on quality of life, medication efficacy, and malnutrition. Dysphagia is currently treated conservatively on evidence-based exercises, individually adapted to each patient. In the recent years pharyngeal electrostimulation has been established and shown a positive impact on outcome. In fact, this type of therapy has not only become an addition to the existing therapy, but an important alternative for patients difficult to treat by other means. The Phagenyx® is a medical device, which has lately been used more frequently in multiple hospitals for treatment of neurogenic dysphagia. For nearly two decades pharyngeal electrostimulation has been further developed and optimised. This therapy initiates changes in the swallowing motor cortex through neuroplasticity as well as local changes in peripheral sensory architecture associated with swallowing. Bath and colleagues (2020) recently reported the efficacy of pharyngeal electrostimulation (Phagenyx®) in various neurological conditions. As a result, of current published studies, the use of pharyngeal electrostimulation probe, in selected patients, with neurological diseases with moderate to severe neurogenic dysphagia will be evaluated. This trial will initially start as quality assurance project with the aim to extent it into a monocentric based register study. The Investigators aim to validate the effectiveness of pharyngeal electrostimulation for the treatment of moderate to severe neurogenic dysphagia by systematically recording specific dysphagia-relevant parameters. At present, it is still uncertain to what extent patients with neurogenic dysphagia in the context of a non-acute neurological disease could benefit from this method. The research questions: Does the use of the pharyngeal electrostimulation probe have an influence on the outcome of dysphagia in patients with moderate to severe neurogenic dysphagia? How long after therapy, can the use of the pharyngeal electrostimulation probe lead to oral food intake and/or removal of a tracheal cannula?
Injuries affecting the central nervous system may disrupt the cortical pathways to muscles causing loss of motor control. Nevertheless, the brain still exhibits sensorimotor rhythms (SMRs) during movement intents or motor imagery (MI), which is the mental rehearsal of the kinesthetics of a movement without actually performing it. Brain-computer interfaces (BCIs) can decode SMRs to control assistive devices and promote functional recovery. Despite rapid advancements in non-invasive BCI systems based on EEG, two persistent challenges remain: First, the instability of SMR patterns due to the non-stationarity of neural signals, which may significantly degrade BCI performance over days and hamper the effectiveness of BCI-based rehabilitation. Second, differentiating MI patterns corresponding to fine hand movements of the same limb is still difficult due to the low spatial resolution of EEG. To address the first challenge, subjects usually learn to elicit reliable SMR and improve BCI control through longitudinal training, so a fundamental question is how to accelerate subject training building upon the SMR neurophysiology. In this study, the investigators hypothesize that conditioning the brain with transcutaneous electrical spinal stimulation, which reportedly induces cortical inhibition, would constrain the neural dynamics and promote focal and strong SMR modulations in subsequent MI-based BCI training sessions - leading to accelerated BCI training. To address the second challenge, the investigators hypothesize that neuromuscular electrical stimulation (NMES) applied contingent to the voluntary activation of the primary motor cortex through MI can help differentiate patterns of activity associated with different hand movements of the same limb by consistently recruiting the separate neural pathways associated with each of the movements within a closed-loop BCI setup. The investigators study the neuroplastic changes associated with training with the two stimulation modalities.
Severe traumatic brain injury (TCI), defined by an initial GCS of ≤ 8 and/or admitted to a neurosurgical intensive care unit, are responsible for diffuse brain lesions that can lead to multiple deficits, including impairment of sphincter functions: bladder, rectal and sexual. Bladder-sphincter disorders are very common after a TBI. Urinary incontinence predominates, with a prevalence varying from 50 to 100% in the acute period following a TBI. The variability of the clinical data is explained by the heterogeneity of the populations studied (severity of TBI, duration of coma, time to care) and the tools used to objectify sphincter disorders. The interest of this study is to make an evaluation and a prospective follow-up of sphincter disorders in this population during one year.
Brain edema is one of the main mechanisms of secondary brain injury and one factor in the prognosis of traumatic brain injury . The clinical study of glibenclamide in the treatment of brain edema after traumatic brain injury is designed to evaluate whether glibenclamide treatment can improve the blood NSE and S100β levels of severe traumatic brain injury , so order to explore the efficacy and adverse effects of this drug in the treatment of traumatic brain injury .
The purpose of this research study is to test the effectiveness of virtual reality (VR) based treadmill training on walking ability. The study will also help to understand the changes in cognitive ability and brain activity as a result of VR-based treadmill training after a brain injury. The study will include 3 groups: C-MILL training group (CTG), Treadmill training group (TTG), and healthy control group (HCG). Individuals with brain injury will be randomly assigned to C-MILL training group, or Treadmill training group. The CTG and TTG will participate in up to 13 sessions. The participants will be screened for the inclusion/exclusion criteria and consented during the first session. They will participate in two data collection sessions, one before the training and one after the training. The participants will undergo 10 training sessions. Individuals in the CTG will receive gait and balance training sessions with the virtual reality and auditory cues using C-MILL (such as walking on a pathway, obstacle avoidance, lateral balance etc.) to provide task specific training. C-Mill (Motekforce Link, Amsterdam, The Netherlands) is an instrumented treadmill that uses visual (on the screen as well on the treadmill) and acoustic cues for gait and balance training. The C-Mill allows for gait and balance adaptability strategy as it can provide obstacle avoidance environments, change in speed and various walking pathways in a safe and controlled environment. Individuals in TTG group will walk on the treadmill (C-MILL) or stand on the treadmill (C-MILL) with no visual or auditory cues. HCG will participate in up to four sessions. The participants will be screened for the inclusion/exclusion criteria and consented during the first session. They will participate in two data collection sessions and one C-MILLsession. Each training session will last for 45 minutes. During the 45 minutes, the participants will perform the task for approximately 1 minute. Participants will be allowed as much rest as needed by them. During the training all participants will wear the safety harness to protect from falling. In addition spotter will be present with the participants to prevent falls. Data Collection: Each participant's baseline and follow up data will be collected for a) functional b) neuromechanical c) cortical and d) cognitive outcomes. During walking on treadmill data will also be collected with instrumented C- MILL. C-MILL can provide gait parameters such as step length, width, frequency, speed and symmetry in addition to center of pressure for evaluation of gait and balance. During Training Sessions: The instrumented treadmill will collect force data during training.
Traumatic brain injury (TBI) patients face notable impairments which lead to reduced performance and regulation of daily and overall functioning. There are a number of interventions made to combat these qualms; however, such interventions have historically been therapeutically demanding, which limits their practical benefit. An online therapeutic intervention can provide a cost-effective approach that can be particularly well-suited to the needs and limitations of TBI. It focuses both on developing awareness and attention, which are often impaired, and are critical to improving emotional and behavioral regulation and everyday function. This project is aimed at assessing the effectiveness and underlying mechanism of modified mindfulness based stress reduction (MBSR) using a rigorous randomized controlled trial. Poised to provide a rigorous approach to efficacy development and analysis, Results of the study will provide valuable information that will ultimately support the refinement of an intervention that can have a real impact on patients' ability to resume a fully functional and satisfying life, and the design of an adequate therapeutic intervention for TBI patients.
Cortical spreading depolarisations are pathological depolarisation waves that occur frequently after severe acute brain injury and has been associated with poor outcome. S-ketamine has been shown to inhibit cortical spreading depolarisations. The aim of the present study is to examine the efficacy and safety of using S-ketamine for treatment of patients with severe acute brain injury, as well as the feasibility of the trial design.
This study will look to validate predictive algorithms developed in a previous study where we collected relevant data from trauma registry and after using advanced signal-processing and machine-learning, determined prediction scores regarding neuroworsening and other outcomes following traumatic brain injury.
The objective is to understand how amygdala activation affects other medial temporal lobe structures to prioritize long-term memories. The project is relevant to disorders of memory and to disorders involving affect and memory, including traumatic brain injury and post-traumatic stress disorder.
The purpose of this study is to evaluate the effectiveness of nebulized lidocaine before Endotracheal suctioning (ETS) compared to instilled lidocaine and the effectiveness of aerosolized lidocaine versus instilled normal saline before ETS in attenuating the increase of intracranial pressure (ICP) in severe head injured children and to evaluate the feasibility of a trial involving instilled lidocaine and aerosolized lidocaine for the management of ETS and to evaluate the safety of nebulized lidocaine in traumatic brain injury (TBI) compared to instilled lidocaine and instilled sodium chloride (NS).