View clinical trials related to Encephalitis.
Filter by:Background and objective From this April, there was a COVID-19 outbreak in Taiwan. The first fatal case of pediatric COVID-19 encephalitis was reported on April 19, 2022 and fatal fulminant cerebral edema in other 4 children with COVID-19 encephalitis was reported within 1 month from Taiwan CDC registry. To date, around 700,000 children got COVID-19 recently. Several children developed MIS-C (multi-system inflammatory syndrome in children)-related shock about 2-6 weeks after COVID-19. Since both COVID-19 associated encephalopathy/ encephalitis and MIS-C are life-threatening, it is urgent to delineate its prognostic biomarker, host genetic factors, immunopathogenesis and viral pathogenesis. Methods Pediatricians will enroll cases of both COVID-19 associated encephalopathy/ encephalitis and MIS-C from several hospitals and medical centers. Their clinical manifestations, lab findings, severity and outcomes will be collected. Clinical assessment of all the systems will be performed. Blood, nasopharyngeal swab and stool will be collected at acute, subacute and convalescent stages for whole exome sequencing, immunopathogenesis including chemokine/cytokine, T/B lymphocyte subset, SARS-CoV2 specific Ab/T/B cell, T and B cell repertoire, viral pathogenesis including multiple viral detection, persistence of fecal SARS-COVID-2 as well as respiratory and gut microbiota. We will establish the animal models for COVID-19 associated encephalopathy/encephalitis and MIS-C, based on the K18-hACE2 or R26R-AGP mouse models established in NTU animal center. Moreover, specific viral or host factors involved in regulating the pathogenesis and immune responses can be investigated, to optimize the protocol for further improvement of the animal models and also to help identify the putative therapeutic targets. Expected results We will delineate the clinical and laboratory characteristics of COVID-19 associated encephalopathy and encephalitis, the role of immune, virology, genetics mechanism in pathophysiology, and will optimize the treatment algorithm based on the result of this study. We also expect that the important biomarkers and risk factors associated with clinical outcome and severity, the immunopathogenesis of MIS-C, host genetic factors and the viral pathogenesis and microbiota associated with MIS-C will be found.
We hypothesize that a high CD4+ and CD8+ T cell count will reduce viremia upon challenge with a structurally heterologous virus, and correspondingly result in reduced magnitude of host response to challenge infection. Primary Objective: To compare, after challenge with a structurally heterologous vaccine, the differences in levels of viremia between healthy adults who received primary vaccination with either YF17D vaccine, chimeric JE-YF17D vaccine, or inactivated JE vaccine. 58 subjects will be randomised into 1 of 2 arms (Arm B1 and Arm B2) in a 1:1 ratio, in a double-blind fashion. Subjects in Arm B1 will receive JE-YF17D vaccine (Imojev, Sanofi Pasteur) on Day 0 followed by YF17D vaccine (Stamaril, Sanofi Pasteur) on Day 28. Subjects in Arm B2 will receive Stamaril on Day 0 followed by Imojev on Day 28. Arm B3 will be conducted as a separate single-arm open label design in 14 subjects. Subjects in Arm B3 will receive inactivated JE vaccine (Ixiaro, Valneva) on Day 0 followed by Stamaril on Day 28. The rationale for these three study arms is as follows: Arm B1 will show the impact low levels of viremia, and the resultant low levels of virus-specific CD4+ and CD8+ T cells, would have on YF17D infection. In contrast, YF17D vaccination in Arm B2 would produce high levels of viremia, and in turn high levels virus-specific T cells, thus likely ameliorating JE-YF17D infection. Arm B3 will serve as the control arm, as vaccination with inactivated JE vaccine would not produce any YF17D-specific T cell response. Notably, the first vaccination in Arms B1 and B2 would also provide the viremia response in the absence of virus-specific T cells, which would serve as a reference point to interpret the outcome of the second vaccination.
We enroll pediatric patients who were diagnosed COVID-19 for main observation target. We will perform brain MRI and neuropsychiatric evaluation 4-6 months after COVID-19 diagnosed. We also enroll healthy age- and gender-matched participant for cross-over comparison. We will perform same evaluation process one year later for longitudinal evaluation
The purpose of this study is to assess the efficacy, safety, pharmacokinetics, and pharmacodynamics of satralizumab in participants with anti-N-methyl-D-aspartic acid receptor (NMDAR) and anti-leucine-rich glioma-inactivated 1 (LGI1) encephalitis.
Determination of autoantibodies against fragments derived from neurons, glia, and myelin sheath is instrumental in aiding diagnosis, differential diagnosis, as well as determining disease status of neuromyelitis optica spectrum disorders (NMOSD), myelin oligodendrocyte glycoprotein antibody-associated disease (MOGAD), autoimmune encephalitis (AE). Cell based assay (CBA) has been frequently recommended to detect autoantibodies of neuroantigens in the aforementioned neurological disorders. However, antibodies with low abundance or low affinity often fall beyond the threshold of CBA and pose significant challenges in practice. To this end, the investigators adopted a tyramide signal amplification (TSA) technology with the basis of CBA to improve sensitivity. The preliminary results suggest that this TSA-CBA platform is superior to conventional CBA in registered signals of the titer autoantibodies. In elevating the sensitivity, TSA-CBA also preserves antigen confirmation. This prospective study is launched to compare the sensitivity, specificity, clinical correlation between CBA and CBA-TSA, in determining autoantibodies against aquaporin 4 (AQP4-IgG), myelin oligodendrocyte glycoprotein (MOG-IgG), N-methyl-D-aspartate receptor (NMDAR-IgG) in a multicenter, double-blind setting.
Helsinki University Hospital (HUS) has decided on a strategy to provide digital health care services for several medical specialties - a project called the Health Village (HealthVillage.fi). Within Health Village a specific digital My Path program, iRENE Digital Pathway, has been developed for web-based neuropsychological rehabilitation. iRENE Digital Pathway is a structured program for adults with an acquired brain injury (ABI), which utilizes psychoeducative information and self-evaluation questionnaires for attentional, memory and executive disorders with a feedback, and provides training for internal and external memory and other cognitive strategies. The current study will explore if web-based neuropsychological rehabilitation is a feasible and effective method for carrying out rehabilitation for adults with ABI.
After acquired brain injury (ABI), persons can experience emotional and behavioral difficulties, that can be painful both for the person and his/her family. This clinical study aims at measuring the effectiveness of a third wave cognitive behavioral therapy called "dialectical behavior therapy" (DBT). DBT aims at teaching persons emotion regulation skills, interpersonal effectiveness skills, mindfulness and distress tolerance skills through group and individual sessions. The study's hypothesis is that DBT, in an adapted format for persons with ABI can lead to - a better quality of life, emotional and behavioral regulation, and self-esteem - decrease in problematic behaviors - progress in life goals - increase post traumatic growth and spirituality - better family functioning and lesser burden for care givers - experiencing more emotions and more free will 45 persons with an ABI sustained more than 18 month back, will follow a 3 phases, follow-up with care as usual for 5 months, followed by 5 months of DBT, followed by 5 months of care as usual + DBT monthly sessions. Self- and family-questionnaire will explore quality of life, emotional regulation, self-esteem, stress, anxiety, cognitive difficulties, family functioning and coping, post traumatic growth and spirituality and will be compared across the 3 phases. Results will be analyzed at a group level but also at an individual level (each patient separately) to test for decrease in unwanted behaviors and at a dyadic level (the person and his/her spouse) to test for the mutual effect of regulating emotions. Persons' memories will by analyzed at 3 time points by a linguistic analysis, and experience of free will after ABI will be analyzed by transcribed narratives of participants.
Autoimmune encephalitis is brain inflammation caused by the immune system mistakenly reacting against proteins in the brain. The commonest form is called NMDAR-antibody encephalitis (N-methyl-D-aspartate receptor antibody encephalitis), a rare condition which mainly affects children and young people and causes difficulties in memory, thinking and mental health which can have significant long-term impacts on education, employment and quality of life. In this project we will use advanced magnetic resonance imaging (MRI) to measure changes in the structure, function and chemistry of the brains of children and young people who are in early recovery from NMDAR-antibody encephalitis and other forms of immune-mediated encephalitis. We will investigate if MRI measurements in patients differ from those in healthy people, and if they can help predict patient outcome one year later, assessed by tests of memory, thinking, mental health and functioning in daily life.
Autoimmune encephalitis are characterized by the subacute development of memory deficits, altered mental status, and psychiatric symptoms, generally in association with anti-neuronal antibodies. Two main groups of autoimmune encephalitis may be distinguished based on the location of the targeted antigen: 1) Intracellular antigens, in which the antibodies are thought not to be pathogenic, and the disorders are usually strongly associated with cancer, constituting therefore paraneoplastic neurological syndromes; 2) Synaptic proteins and surface receptors, in which the antibodies are pathogenic and the frequency of cancer is variable depending on the antibody and the demographic characteristics of the patient. Encephalitis with antibodies against N-methy-D-aspartate receptor is the most common autoimmune encephalitis, being even more frequent than infectious etiologies. It is characterized by subacute onset of memory deficits, psychiatric symptoms, speech dysfunction, seizures, movement disorders, decreased level of consciousness, dysautonomia and central hypoventilation. Nearly 50% of women with anti-NMDAR encephalitis have an ovarian teratoma, while associated tumors in elderly patients are usually carcinomas. In contrast, most cases in children and young men are non-paraneoplastic. Recently, herpes-simplex encephalitis has been described as another trigger of NMDAR encephalitis. Conversely, for the vast majority of the non-paraneoplastic autoimmune encephalitis, no acquired triggers have been described so far. In addition to acquired susceptibility, genetic predisposition may also be important in the pathogenesis of autoimmune encephalitis. The human leukocyte antigen (HLA) is the genetic factor most frequently associated with autoimmune diseases, and it has been already linked to a few autoimmune encephalitis, such as anti-leucine rich glioma inactivated 1 (LGI1), contactin-associated protein-like 2 (CASPR2), IgLON5, and glutamic acid decarboxylase 65 (GAD65) encephalitis. However, no HLA association has been reported for NMDAR encephalitis, suggesting that in this condition, and likely in others, non-HLA loci might be involved in the pathogenesis as well. Genome-wide association studies (GWAS) are useful tools to identify variants at genomic loci that are associated with complex diseases, and in particular, to detect associations between single-nucleotide polymorphisms (SNPs) and diseases. The aim of the study is to detect genetic variants in NMDAR encephalitis and other autoimmune encephalitis.
Numerous neurological disorders affecting the central and peripheral nervous system can be attributed to the immune system through multiple effector mechanisms. However, current treatments could be drastically improved by faster and more accurate diagnosis. The sample collection will benefit to patients with rare neuroimmune syndromes such as Autoimmune Encephalitis (AE) and Paraneoplastic Neurological Syndromes (PNS) leading to a better and early diagnosis, as well as treatment improvement.