Active clinical trials for "Brain Injuries"

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?

Postural and balance disorders are common in neurological disorders. They are often associated with reduced mobility and fear of falling, which strongly limit independent activities of daily living (ADL), compromise the quality of life and reduce social participation. Here the investigators apply an existing software solution to: 1) obtain biomarkers of gait deficits in 5 neurological conditions, 2) develop an automatic procedure supporting clinicians in the early identification of patients at high risk of falling as to tailor rehabilitation treatment; 3) longitudinally assess these patients to test the efficacy of rehabilitation. High-density electroencephalography (EEG), and inertial sensors located at lower limbs and at upper body levels will be used to extract the most appropriate indexes during motor tasks. The ultimate goal is to develop cost-effective treatment procedures to prevent recurrent falls and fall-related injuries and favour the reintegration of the patient into everyday activities. The first hypothesis of this study is that clinical professionals (e.g., medical doctors and rehabilitative staff) would strongly benefit from the possibility to rely on quantitative, reliable and reproducible information about patients motor deficits. This piece of information can be nowadays readily available through miniaturized wearable technology and its information content can be effectively conveyed thanks to ad hoc software solution, like the A.r.i.s.e. software. The second hypothesis of the present study is that early identification of patients at high risk of dependence and the subsequent application of personalized treatment would allow for cost-effective treatment procedures to favor the autonomy into everyday activities. The results of this project could represent a valuable support in the clinical reasoning and decision-making process.

Brain injury remains the leading cause of death in comatose patients resuscitated from OHCA. One of the most challenging aspects in the treatment of a post-cardiac arrest patient is the assessment of the extent of brain damage. Reliable, clinical measures of ongoing brain injury have potential to guide individualized treatment and potentially improve outcomes. Persistent candidate measures to fill this role is combined cerebral metabolism monitoring assessed by jugular bulb microdialysis (JBM) and positron emission tomography (PET) of 18-Fluor deoxyglucose ([F-18]-FDG). This multimodal neuromonitoring is cutting-edge technology used in a clinical setting

Trauma is the leading cause of death and disability in children in the United States. The objective of this study is to evaluate the benefits and harms of tranexamic acid (TXA; a drug that stops bleeding) in severely injured children with hemorrhagic brain and/or torso injuries. Using thromboelastography, we will measure baseline fibrinolysis to assess for treatment effects of TXA at different levels of fibrinolysis.

Children suffer proportionally more head injuries than any other age group and children with head injuries have the highest mortality of all children admitted with traumatic injuries. The investigators aim to investigate the factors that contribute to poor outcomes after paediatric acute brain injury by collecting observational and outcome data. Much of the brain damage that results in poor outcomes actually happens in the hours and days after the injury. This is due to several factors such as brain swelling and poor oxygen delivery to the brain. Treatment is directed to try and protect the brain against these factors. Current management of the head injured child focuses on monitoring pressure within the head. However, this does not detect all the factors that cause continuing brain damage. Special monitors that follow oxygen levels and chemical changes in the brain are used safely in adult patients but have not been widely employed in children despite their potential benefit. There is therefore the opportunity to evaluate extra monitoring of the child brain, and in doing so, help refine the management of these patients.

The goal of this observational study is to learn about changes in the brain of patients over the first 3 years following a traumatic brain injury (TBI). The main question it aims to answer are: - How TBI effect the rate of brain tissue loss compare to healthy brain Participants will give blood samples, complete MRI scans, and neuropsychological assessment measures. Researchers will compare results between healthy control group and TBI group to determine changes in injured brains.

Aim: Investigate whether patients undergoing specialist rehabilitation after complex neurological injury show different functional outcomes if music therapy is included in their rehabilitation program compared to usual care. Background: Patients with complex needs following a brain, spinal cord, and/or peripheral nerve injury often require a period of specialist neurorehabilitation. This involves multiple therapy disciplines, led by a Consultant in Rehabilitation Medicine, Neurology, or Neuropsychiatry. Although music therapy is suggested to enhance neuroplasticity and recovery in patients with brain injury, it is not routinely commissioned in clinical care due to a lack of supportive evidence. Hypothesis: Patients undergoing music therapy in addition to complex specialist rehabilitation show better functional outcomes compared to usual care. Number of participants: 75, aged 16-80 years. Methods: Patients undergo baseline assessments and are randomised to MUSIC or CONTROL Therapy. Both arms receive 1-3 additional therapy sessions per week, matched for duration and number, total 15 hours. After approximately 10-weeks intervention, assessments are repeated. All participants then have access to music therapy until they are discharged from Neurorehabilitation Unit (NRU), with additional qualitative data collection using semi-structured interviews, field notes, staff reports, staff stress surveys, and broader ecological observations. Duration for Participants: From consent to discharge from NRU. Primary Outcome: Change in Functional Independence Measure+Functional Assessment Measure (FIM+FAM), Northwick Park Dependency Scale (NWPDS), and Barthel Activities of Daily Living pre and post 15 hours intervention. Secondary Outcome: Change in quality of life (Flourishing Scale), psychological distress (Hospital Anxiety and Depression Scale, Depression Intensity Scale Circles), social interaction (Sickness Impact Profile Social Interaction Subscale), well-being (WHO Well-Being Index), and communication (Communication Outcomes After Stroke Scale), pre and post 15 hours intervention. Mean difference in well-being (WHO Well-Being Index) throughout the intervention period between music therapy and control therapy groups. Mean difference in post-intervention pain and mood visual analogue scores between music therapy and control therapy groups.

Feasibility study of a new medical device that will evaluate the usability and effectiveness of a cycle ergometer device associated with neuromuscular electrical stimulation (FES cycling). The study's objective is to evaluate the effect of the application of functional electrical stimulation of the new device on participants' quadriceps muscle strength in comparison to a medical device with similar characteristics and to a control group. Secondarily, the study will compare the usability of the two medical devices as evaluated by the participants and the therapists who apply the treatment, as well as the participants' satisfaction with the treatment, identifying possible adverse effects.

This is a single-center, observational study. Patients after successful cardiopulmonary resuscitation (CPR) will be transferred to the emergency intensive care unit for further standardized management. After successful return of spontaneous circulation (ROSC) for 72h and hemodynamics remained stable for 24h, the post-resuscitated patients underwent functional magnetic resonance imaging (fMRI) examination. During the examination, the supervising physician accompanied the patient and monitored the patient's vital signs using a magnetic resonance monitoring system (Siemens Healthcare Prism, Germany). Patients who are on ventilators are mechanically ventilated using a magnetic ventilator (HAMILTON-MRI, USA). In additional to conventional sequences, fMRI is performed for diffusion-prepared pseudo-continuous arterial spin labeling (DP-pCASL) and blood oxygenation level dependent functional magnetic resonance imaging (BOLD-fMRI). These MRI sequences allow quantitative assessment of the patients' cerebral microcirculation, blood-brain barrier, and cerebral oxygenation status. Patients will be followed up for neurologic prognosis according to the Modified Rankin Scale (mRS) at 6 months after disease onset.

Around the time of birth, some babies experience a condition called asphyxia, which means that their brain and other organs do not receive enough blood and/or oxygen to work properly. This life-threatening condition accounts for nearly 1 out of 4 deaths of all babies around the world, and often leads to severe brain damage, cerebral palsy, epilepsy, and trouble with learning and functioning in everyday life. At this time, no treatment is available to repair the brain damage caused by asphyxia. Excitingly, a drug called sildenafil (Viagra®) is already given safely to babies who suffer from increased blood pressure in their lungs' vessels. Recent studies using a laboratory model of asphyxia at birth suggest that sildenafil may also repair the brain damage caused by asphyxia. Similarly, recent small studies have shown that it is both feasible and safe to give sildenafil to human babies, who suffered from asphyxia at birth. These studies also highlight the first promising signs that sildenafil may improve how the brains of these babies work, which is consistent with the abovementioned laboratory studies. On the basis of these previous researches, the investigators predict that sildenafil can repair the damage to a baby's brain. The investigators will test whether sildenafil can be safely given to a large group of human babies who suffer from asphyxia at birth, and will confirm whether sildenafil improves or not how their brains and hearts/lungs work. This project will enable to determine whether sildenafil is a promising treatment for repairing brain damage in babies who suffer from asphyxia at birth. This project may also provide new solutions for these babies to improve their future life.