View clinical trials related to Brain Injuries.
Filter by: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.
This is an observational study in patients who require clinical anesthesia. The main purpose of this study is to understand whether there are differences in the cerebral blood flow, and oxygen metabolism affected by different types of anesthesia. Subjects who require clinical anesthesia for a clinical MRI and for whom the use of anesthetics for the exam are in clinical equipoise are asked to join the study. All eligible subjects will be asked to provide informed consent before participating in the study.
The main objective is to assess the feasibility of collecting and implementing a multidimensional evaluation in a sample of patients with a mild to severe traumatic brain injury (TBI) and their relatives, evaluated at 6 months (primary outcome), and at 12 then 18 months post-injury (secondary outcomes).
The goal of this observational study is to test the association between baseline ventilatory parameters (in particular mechanical power (MP), mechanical power normalized to predicted body weight (MP/PBW) and driving pressure (DP) with the baseline neurological status (assessed through the Glasgow coma score) in adults patients under mechanical ventilation with acute neurological injury secondary to stroke, brain trauma or subarachnoid hemorrhage. The main question[s]it aims to answer are: 1. In patients with acute neurological injury under mechanical ventilation, is there a correlation between the acute neurological injury, assessed using the Glasgow scale on admission, and baseline ventilatory parameters? 2. In patients with acute neurological injury under mechanical ventilation, are the baseline ventilatory parameters altered at baseline?
TBI rehabilitation care transitions refer to the processes of preparing patients, families, and community-based healthcare providers for the patient's passage from inpatient rehabilitation to the home and community or to another level of care. Persons with TBI have heterogenous neurological impairment (cognitive and behavioral foremost, along with motor, sensory, and balance), that limits their functional independence and participation, and increases their risk for secondary medical conditions, injuries, rehospitalizations and early mortality
The study aims to inform the subsequent large-scale clinical trial focused on using telerehabilitation techniques and technologies to improve upper limb function and quality of life.
There is a paucity of knowledge about mechanisms behind mild traumatic brain injury (mTBI) subgroup's sustained problems, and effective interventions that can alleviate this disabling condition. Persistent Post-concussive Symptoms (PCS) affect between 20% and 30% of individuals after mTBI. This Randomized Controlled Trial (RCT) will investigate whether graded aerobic exercise has a positive effect on symptom burden (including exercise intolerance) and Autonomic Nervous System (ANS) dysfunction in patients with PCS. This study will expand upon previous work on adolescents with sport-related concussion in the acute phase. It will cover a wider age group and will include patients with persisting symptoms, thus providing knowledge on whether a sub-symptom threshold aerobic exercise program will alleviate symptom burden in adult patients with PCS. Furthermore - looking into the relationship between mTBI and ANS function, this study is expected to contribute to a better understanding of the neurobiological factors involved in PCS. The results may also help developing targeted interventions to specific characteristics in persistent symptoms after mTBI.
The goal of this clinical trial is to analyze the usability and safety of the robotic gait device EXPLORER in children with cerebral palsy, acquired brain injury and spinal muscular atrophy. Participants will use the exoskeletons in their home and the community and variables regarding safety and usability will be measured and recorded.
Traumatic Brain Injury (TBI) is an alteration of brain function caused by an external force. Long-term mortality in TBI is substantial, TBI survivors can develop chronic progressive disabilities and have a life expectancy shortened by 6 years. Treatment consists in supportive therapy directed at prevention of second insults, but no neuroprotective therapy is available. Given the multifaceted nature of TBI, mesenchymal stromal cells (MSCs) are an ideal candidate: they release multiple soluble factors shown to ameliorate the injury microenvironment through immunomodulatory, protective, reparative and regenerative processes. Preclinical data across a range of different TBI models and injury severities show that human MSCs improve outcome through pleiotropic mechanisms of protection and repair. Thus, data indicate MSCs as strong therapeutic candidate and support a clinical study in TBI. Aim: the study is designed to assess the safety and the efficacy of the MSCs, intravenously administered in severe TBI patients within 48h from injury. The study will be conducted in a stepwise manner. Step 1 will enroll 36 patients (randomized 1:1:1 in arms 80 x 10^6 MSCs vs 160 x 10^6 MSCs vs placebo) to define safety, and will allow to select the most promising dose. Step 2 will enroll 30 patients (1:1 in arms MSCs selected dose vs placebo) to define the MSC activity based on the quantification of the plasmatic levels of the neurofilament light (NFL) at 14 days, as biomarker of neuronal damage. Secondary objectives are aimed to assess: 1. brain injury evolution and white matter damage by longitudinal neuroimaging (at 4 days and 14 days post-TBI and at 6 months) 2. brain immunomodulatory changes by temporal profiling of circulating biomarkers of brain damage and neuroinflammation (daily for 3 days after TBI, at day 7 and 14, and at 1, 6 and 12 months) 3. clinical outcome by a structured clinical and neuropsychological assessment at both 6 and 12 months Methods: a multicenter, double blind, randomized, placebo-controlled, adaptive phase II dose finding study. Duration of the study: 36 months (24 of enrolment and 12 of follow up). Funding: Fondazione Regionale per la ricerca Biomedica, FRRB (Call "Unmet medical needs", proposal number 3440227) and Italian Ministry of health (Ministero della Salute, Bando di Ricerca Finalizzata 2021; proposal number RF-2021-12372642).
Acquired brain injury (ABI) is the leading cause of death and disability worldwide. The degree of severity varies according to a combination of numerous demographics, etiological, clinical, cognitive, behavioral, psychosocial and environmental factors, which can interfere with the effectiveness of rehabilitation interventions and, therefore, with the final outcome. The most important goal of the modern clinic is to predict in time the progression of possible recovery after the brain injury event in order to provide more effective treatment, but the high heterogeneity and clinical variability and the unpredictability of the onset of comorbidities makes this a hard target to reach. In recent years, artificial intelligence algorithms have been applied to more precisely define the role of critical variables that can help clinical practice to predict the final outcome. The classical approach of these algorithms provides only probabilistic values on the final outcome, without considering the typology of clinical interventions and overall complications that may appear throughout the hospitalization period. The objective of this multicentric study is to define a new statistical approach that can describe the dynamics of individual clinical changes occuring during the inpatient intensive rehabilitation care period. The proposed approach combines a principal component analysis (PCA) for dimension reduction (capturing the maximum amount of information and reducing the dimensionality problem) and a nonlinear mathematical modeling for describing the evolution of the clinical course in terms of the resulting new PCA dimensions. By using this approach, we may determine the individual patient's temporal trajectories while examining particular clinical factors. The secondary objective of this study is to validate a new version of the Early Rehabilitation Barthel Index (ERBI), a well-known clinical scale used to measure functional changes in patients with severe acquired brain injury.