View clinical trials related to Brain Injuries, Traumatic.
Filter by:Spasticity - a variety of motor over-activity and part of the upper motor neuron syndrome - is a common cause of impaired motor function after brain injuries of different etiologies. In addition, it may cause pain and impaired hygiene, contractures, deformities etc. Spasticity has been reported in 30 to 90% of patients with stroke, traumatic brain injury (TBI), incomplete spinal cord injury (SCI) and cerebral palsy (CP). Spasticity therapy has emerged as an important approach to alleviate related symptoms. Positive effects on spasticity are well recognized following systemic and intra-thecal pharmacological treatment, as well as after intra-muscularly injected substances; the effect of the latter is, however, of limited duration. While pharmacological spasticity therapy has been applied for decades, surgical procedures remain fairly uncommon in adults with spasticity, but not in pediatric patients with CP, and outcomes after surgical treatment are scarcely described in the literature. The study center is a specialized unit initially focused on reconstructive as well as spasticity reducing surgery in the upper extremities for SCI patients. Subsequently, patients with spasticity also due to various other Central nervous system diseases have been referred to the center for surgical treatment. Studies describing the effect of spasticity-reducing surgery in the upper extremities are rare and the group is heterogeneous. The aim of the study is therefore to evaluate the results and compare against todays golden standard treatment (boutuliniumtoxin injections).
Head injuries are responsible for 1.4 million visits to hospital each year in the United Kingdom (UK). Most patients are allowed home the same day and make a full recovery, but some will have persistent symptoms. The investigators aim to use the latest generation of imaging technology to investigate those with mild traumatic brain injury (mTBI) to better assess them. The investigators will invite patients presenting following trauma to the Emergency Department at Queen's Medical Centre, Nottingham, UK to participate. The investigators will compare those who have a suffered an mTBI to those who have non-head traumatic injuries. The investigators will use two magnetoencephalogram (MEG) systems and ultra-high field magnetic resonance imaging (MRI) to record the functioning and structure of the brain within days of participants' injury. The investigators will test memory and thinking skills, then follow participants for six months, record the severity of participants' symptoms, and find out who does not make a full recovery. Multimodal imaging will consist of a standard MEG device using Superconducting Quantum Interference Device (SQUID) sensors, a novel MEG device using Optically Pumped Magnetometer (OPM) sensors and seven Tesla MRI. The investigators will test whether these innovative imaging techniques are more sensitive to the acute damage that mTBI causes than routine imaging. The investigators will also test whether early imaging can reveal who is most seriously affected, identifying those who will not recover without additional support. It is currently not clear what the predominant mechanism of damage that causes these long-term problems is and the investigators hope this study will address this. The Medical Research Council is funding this work
The purpose of the study is to evaluate the use of autologous Bone Marrow Derived Stem Cells (BMSC) as a means to improve cognitive impairment as occurs in Alzheimer's Disease and other dementias and to improve behavior and socialization issues which occur in adult Autism Spectrum Disorder. The use of Near Infrared Light, in conjunction with the use of BMSC, will also be assessed.
Alzheimer's disease, stroke and TBI are frequently observed brain disorders, causing significant morbidity. For none of these disorders, there are in vivo diagnostic biomarkers available that allow determination of disease burden, patient-specific prognosis and therapy follow-up. However, they all share a similar mechanism that may cause accumulation of tau oligomers in the brain, synaptic dysfunction and cognitive and/or behavioral impairment. Until recently, the only way to quantify synaptic density and tau deposition was using post-mortem immunohistochemistry. Now, in vivo Positron Emission Tomography (PET) imaging of synaptic density has become possible trough development of 11C-UCB-J, a levetiracetam-based radioligand, expressing high affinity and specificity for SV2A. Furthermore, the novel radioligand 18F-MK-6240, specifically targeting tau deposits, was clinically implemented in our center. Through PET-MR, we can visualize the cascade of tau deposition, synaptic loss and degeneration of grey and white matter and relate these pathologic features to cognitive and behavioral deterioration. The goal of the study is to: 1) measure tau deposition and loss of synaptic density in these conditions as a potential measure for disease load 2) determination of the mid-term (2 years) monitoring capacity of combined functional-structural PET-MR imaging 3) relate progression of the imaging markers to cognitive and/or behavioral decline and 4) determination of the optimal combination of PET-MR metrics for early identification and risk-stratification of cognitive and/or behavioral dysfunction in de novo patients.
This project is to evaluate sensitivity and specificity of hyperpolarized 13C-pyruvate as imaging agents of altered cerebral glycolysis and mitochondrial dysfunction and assess pyruvate utilization in mitochondria in Traumatic Brain Injury (TBI) patients.
Chronic Traumatic Brain Injury (cTBI) symptoms exist in individuals who experienced previous traumatic brain injuries. There are 80-90 thousand individuals who are clinically diagnosed with cTBI, with estimated costs at greater than 60 billion dollars. However, there is a lack of studies using comprehensive diagnostic imaging tools to better understand physiological ramifications of the injury that may help guide therapy. This study uses integrative medicine approaches for persons with cTBI. Another aim of this study will be a continuation of this protocol in an effort to address the ongoing distressing physiological and psychological (anxiety and depression) symptoms associated with cTBI. After completion of the initial 3 study arms, the investigators have amended the protocol to evaluate the physiological and psychological effects and potential symptom improvement of integrative medicine approaches in cTBI patients using the Neuro Emotive Technique (NET). Participants may be re-enrolled in the NET group after completion of participation in the initial study arms. The participants in the NET substudy will be interviewed about Subjective Units of Distress (SUDS) associated with the cTBI event initially and after completion of the NET sessions.
The NCTT is a prospective, multicenter, observational research network for subjects with chronic spinal cord and/or chronic traumatic brain injury.
The experimental design is an open-label two-week trial of tolcapone to evaluate which clinical domains are affected by tolcapone treatment and to identify "responders" to tolcapone treatment in the two subject groups (BI and NCD)
The objective of the protocol is to pursue the long-term follow-up of a large cohort of severe traumatic brain injury patients. This outcome is to be described in terms of activity, participation, quality of life, socio-professional outcome, economical consequences and impact on caregivers, and in relation to health care provision. Secondary objectives are to measure the impact on outcome of several predictive factors; to evaluate evolution of patients since the last (four-year) evaluation.