View clinical trials related to Brain Diseases.
Filter by:Hepatic encephalopathy is a brain dysfunction caused by liver insufficiency and/or porto-systemic shunt. It manifests as a wide spectrum of neurological or psychiatric abnormalities ranging from subclinical alterations to coma. According to the symptoms, it is classified as covert HE (CHE) and overt HE (OHE). CHE can progress to OHE and is associated with reduced driving ability, increased risk of accidents and hospitalization and weakened health-related quality of life, resulting in poor prognosis and socio-economic status. However, due to the absence of readily identifiable clinical symptoms and signs, CHE is often neglected in clinical practice. Presently, the diagnosis of CHE depends on psychometric and neurophysiological tests, including the psychometric hepatic encephalopathy score (PHES), critical flicker frequency (CFF) test, continuous reaction time (CRT) test, inhibitory control test, the SCAN test, and electroencephalography. Among them, PHES is most widely used and recommended by several guidelines. However, it is difficult to screen CHE among all cirrhotic patients in the clinic using PHES because of the time required and a dependence on trained experts. Moving beans from one container to another with tweezers involves dexterity, agility and coordination.The hypothesis was that the utility of the Clamping Bean Test (CBT) will enable early screening patients with CHE.
The project is focused on the detailed study of structural genomic variants (SVs). Such genetic mutations are in fact alterations in the DNA molecule structure and include copy number variants, inversions and translocations. A single event may affect many genes as well as regulatory regions and the specific phenotypic consequences will depend on the location, genetic content and type of SV. Many times, the specific disease-causing mechanism is not known. Here, we plan to study the molecular genetic behavior of structural variants as well as the underlying mutational mechanisms involved. First, we will use genome sequencing to pinpoint the chromosomal breakpoints at the nucleotide level, characterize the genomic architecture at the breakpoints and study the relationship between structural variants and SNVs. Second, we will study how structural variants impact gene expression. Finally, we will functionally explore the disease mechanisms in vivo using zebrafish and in vitro using primary patient cells and induced pluripotent stem cells. Our studies will focus on the origin, structure and impact of structural variation on human disease. The results will directly lead to a higher mutation detection rate in genetic diagnostics. Through a better understanding of disease mechanisms our findings will also assist in the development of novel biomarkers and therapeutic strategies for patients with rare genetic disorders.
Our purpose is to 1. Examine the correlation between MDF in a resting EEG, recorded just before the CRT test, and the variance in reaction times indicated by the CRT index 2. At simultaneous CRT and EEG recording, examine whether a change in EEG is seen immediately before an extended reaction time occurs (defined by the 75th percentile). This will shed light on a direct pathophysiological association between what is measured with EEG and CRT. 3. Investigate whether cyclicity can be detected in the continuous reaction times and if so, whether amplitude and wavelength in this cyclic activity are correlated to EEG parameters. 4. Examine whether a response to standard HE treatment can be detected with EEG in patients who are thought to suffer from it. As well as if baseline outcome predict future hepatic encephalopathy. 5. With a view to further validating our findings, investigators want to correlate results from EEG and CRT with the most internationally widespread psychometric test, the Portosystemic Encephalopathy test (PSE), which necessitates the establishment of Danish normal values. A secondary purpose of this study is therefore 6. To establish Danish normal values for the PSE test and the Animal Naming test in Danes
The primary objective for this study is to evaluate the long-term safety and tolerability of NBI-827104 in pediatric participants with epileptic encephalopathy with continuous spike-and-wave during sleep (EECSWS).
Extension study to evaluate how safe and tolerable the drug NBI-921352 is when used as adjunctive therapy in participants with SCN8A developmental and epileptic encephalopathy syndrome (SCN8A-DEE).
This study is to evaluate the use of glycerol phenylbutyrate for monogenetic developmental epileptic encephalopathies (DEEs). DEEs are characterized by epilepsy and developmental delay in early life. Two examples of DEEs are STXBP1 and SLC6A1, though there are dozens of others. STXBP1 Encephalopathy is a severe disease that can cause seizures and developmental delays in infants and children. SLC6A1 neurodevelopmental disorder is characterized by developmental delay and often epilepsy. Both STXBP1 encephalopathy and SLC6A1 neurodevelopmental disorder cause symptoms because there are not enough working proteins made by these genes. It is possible that a medication called phenylbutyrate may help the the remaining proteins work better for STXBP1, SLC6A1, and/or other similar DEEs caused by single genes (i.e. "monogenetic"). This study is to test if glycerol phenylbutyrate is safe and well tolerated in children with monogenetic DEE.
Babies who have brain injury also frequently have involvement of their kidneys, lung and heart. Although clinical care in the neonatal period is well defined there are few guidelines and evidence for developmental, heart and kidney followup in childhood. The investigators aim to develop and implement guidelines for health care workers and families on Followup after Neonatal Brain Injury. Inflammation is an important factor in brain injury of newborns and also affects their heart lungs and other parts of their body. The investigators will use tests from the newborn period to predict outcome and help parents with planning health needs for their baby rather than waiting until any issues arise later on. By understanding inflammation the investigators can find methods to decrease the negative effects and improve outcomes in the future for babies and families.
The goal of this study is to verify whether electrical stimulation of the cervical spinal cord can activate muscles of the arm and hand in people with hemiplegia following stroke. Participants will undergo a surgical procedure to implant a system which provides epidural electrical stimulation (EES) of the cervical spinal cord. Researchers will quantify the ability of EES to recruit arm and hand muscles and produce distinct kinematic movements. The implant will be removed after less than 30 days. Results of this study will provide the foundation for future studies evaluating the efficacy of a minimally-invasive neuro-technology that can be used in clinical neurorehabilitation programs to restore upper limb motor function in people with subcortical strokes, thereby increasing independence and quality of life.
The study will evaluate the safety and feasibility of near infrared therapy as an intervention for patients with refractory depression, anxiety, neurodegenerative disease, and traumatic brain injury.
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.