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Autoimmune Encephalitis clinical trials

View clinical trials related to Autoimmune Encephalitis.

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NCT ID: NCT03542279 Recruiting - Clinical trials for Autoimmune Encephalitis

Immunotherapy in Autoimmune Encephalitis

PE
Start date: January 1, 2018
Phase: N/A
Study type: Interventional

The study is to explore the treatment effects and long-term prognosis (12 months and 24 months after immunotherapy) by comparing the early plasma exchange (PE) combined with medication therapy with the PE after medication immunotherapy in autoimmune encephalitis (AE) patients, to make clear that the early PE can be more effective than the treatment of PE after medication immunotherapy. As well as, the study is to explore whether PE is also effective in AE with autoantibody synthesis in the sheath, positive cerebrospinal fluid antibody and seronegative.

NCT ID: NCT03530462 Completed - Clinical trials for Cognitive Impairment

To Explore Cognitive Neural Mechanism of Autoimmune Encephalitis by Using Neuropsychological Tests and Multi-modal MRI

Start date: April 7, 2017
Phase:
Study type: Observational

Most of patients with autoimmune encephalitis are left with permanent cognitive deficits of varying severity. The patients' life and career would be affected definitely by cognitive deficits. Recently, more and more clinical physician have begun to focus on cognitive impairment of patients with autoimmune encephalitis. Generally, the outcome was measured by the modified Rankin Scale (mRS). However, the mRS are commonly used to evaluate the degree of disability or dependence in the daily activities of the patients suffering from a stroke and cognition function were minimally evaluated in this scale. It is crucial to adopt detailed cognition tools to study the long-term cognitive outcomes and as an indicator of overall curative effect judgment in autoimmune encephalitis. Currently, only early immunotherapy is uniformly and consistently considered to produce favorable cognitive outcomes. However, studies concerning the association of second-line immunotherapy with cognitive outcomes have been scarce and have shown conflicting results regarding autoimmune encephalitis. Hence, the goal of this study was to explore cognitive neural mechanism of autoimmune encephalitis by using neuropsychological tests and multi-mode MRIs.

NCT ID: NCT03194815 Recruiting - Psychosis Clinical Trials

IVIG and Rituximab in Antibody-associated Psychosis - SINAPPS2

SINAPPS2
Start date: November 1, 2017
Phase: Phase 2
Study type: Interventional

A randomised phase II double-blinded placebo-controlled trial designed to explore the utility of immunotherapy for patients with acute psychosis associated with anti-neuronal membranes (NMDA-receptor or Voltage Gated Potassium Channel). Primary objective: To test the efficacy of immunotherapy (IVIG and rituximab) for patients with acute psychosis associated with anti-neuronal membranes. Secondary objective: To test safety of immunotherapy (IVIG and rituximab) for patients with acute psychosis associated with anti-neuronal membranes.

NCT ID: NCT03004209 Withdrawn - Clinical trials for Autoimmune Encephalitis

Effect of Erythropoietin in Refractory Autoimmune Encephalitis Patients

Start date: December 2016
Phase: Phase 4
Study type: Interventional

This study evaluates the efficacy of erythropoietin in refractory autoimmune encephalitis. Ten patients will receive 100 IU/kg of erythropoietin 3 times a week for 12 weeks.

NCT ID: NCT02905136 Completed - Clinical trials for Autoimmune Encephalitis

Mechanisms of Auto-immune Encephalitis

MECANO
Start date: May 23, 2017
Phase:
Study type: Observational

Neurological and psychiatric diseases are one of the major health problems worldwide. Decades of fundamental and clinical research have led to the model that these disorders results from synaptic imbalance between excitatory, inhibitory and modulatory systems in key brain structures. Although the network and neurotransmitter systems involved have been delineated, the mechanisms leading to improper neurotransmissions remain poorly understood. One major limitation lays in the difficulty to transpose the identified dysregulation in humans to relevant animal models in which molecular and cellular targets can be manipulated. The amino-acid glutamate mediates the vast majority of excitatory neurotransmission in the mammalian brain. We know that the glutamatergic synapses can change their strength by regulating surface expression and dynamics of their postsynaptic receptors, through changes in receptor recycling and/or lateral diffusion. This synaptic plasticity underlies higher cognitive functions such as learning and memory and is likely compromised in several disease states. Regulating glutamate receptor number and function is thus of primary importance. New subcellular imaging technique rendered possible the study of receptor trafficking and receptor regulation in various conditions including pathological models opening new fundamental questions. Moreover, recent breakthroughs on glutamate receptor structure offer unprecedented clues on the molecular and structural mechanisms underpinning receptor dysfunction at the atomic level. Recently, description of encephalitis associated with specific autoantibodies (Abs) directed against neuronal synaptic receptors or proteins (NSA-Abs) opens new lights in the pathophysiological mechanisms of some human brain disorders. The best example and the most frequent syndrome is the synaptic autoimmune encephalitis associated with autoantibodies against extracellular domains of the glutamatergic NMDA receptor (NMDAR-Abs). Classically, patients first present psychiatric symptoms with hallucinations and bizarre behavior before development of neurological symptoms such as seizures, dyskinesia, and autonomic instability. Despite the severity of neuropsychiatric symptoms, more than 80% of patients fully recover after immunomodulatory treatments and many arguments suggest a direct role of NMDAR-Abs in the symptoms. The investigators recently demonstrated that NMDAR-Abs directly modify, at the synaptic level, NMDAR lateral diffusion by disruption of the interaction between NMDAR and EphrinB2 receptor, a synaptic protein anchoring NMDAR at the synapse (Mikasova et al, Brain 2012; Dupuis et al, EMBOJ 2014). These data suggest that NMDAR-Abs could directly participate in the neuropsychiatric disorders observed in patients and that NMDAR dysfunctions could be directly responsible for the observed symptoms. Furthermore, these data suggest that other NSA-Abs directed against other synaptic proteins could explain specific neurological symptoms in patients with encephalitis that are not associated with NMDAR-Abs. The aim of MECANO is to combine multidisciplinary approaches (clinical, immunological, and neurobiological ones) to identify new NSA-Abs, to characterize their specific pathological roles and to decipher acute and chronic NMDAR-Abs effects on biophysical and structural properties of the NMDA receptor, synaptic plasticity, neuronal morphology, and cognitive performance. This project should provide key insights onto the effects of patients' NSA-Abs on the cellular dynamic and regulation of synaptic proteins or receptors and on the molecular cascades activated during synapse dysfunction. The investigators will investigate how NSA-Abs binding alter receptor activity, modify surface receptor mobility and dynamically regulate the maturation of synapses and circuitries. For that purpose, The investigators will use a unique combination of high-resolution imaging (single nanoparticle tracking), receptor engineering, cellular electrophysiology, computational (structural modeling) and cellular and molecular biology approaches and finally behaviour assays. Based on both cutting-edge neurobiology and clinical expertise of autoimmune disorders, and strengthened by promising preliminary experiments, the MECANO project will likely open new avenues of fundamental research in the understanding of synaptic dysfunction and clinical research for the treatment of neuropsychiatric disorders.