Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0014070 (encephalomyelitis)
 13,017 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Therapeutic plasma exchange (TPE), is a procedure, changing pathologic substances in the plasma of patients with replacement fluid. TPE has an increasing list of indications in recent years such as neurological, connective tissue, hematological, nephrological, endocrinological and metabolic disorders. We report our multicenter data about therapeutic plasma exchange in patients with neurological diseases. Six University Hospitals' aphaeresis units medical records about neurologic diseases were reviewed retrospectively. Hundred and fifteen patients and 771 TPE sessions from six aphaeresis units' were included to this study. Of the 115 patients, 53 (46%) were men and 62 (54%) were women. The median age was 50 (range: 5-85) years. Of these patients 58.3% were Guillain-Barre syndrome (GBS), 17.4% were acute disseminated encephalomyelitis (ADEM), 10.4% were chronic inflammatory demyelinating polyradiculoneuropathy (CIDP), 7% were multiple sclerosis, 6.1% were myasthenia gravis (MG) and 0.9% were Wilson disease (WD). The median number of TPE sessions per patient was 5 (range 1-72). Human albumin was used as a replacement fluid in 66% and fresh frozen plasma was used in 34% of cases. TPE was done through central venous catheters in 66%, and peripheral venous access in 34% of patients. Some complications were seen in patients (18.3%) during TPE sessions. These complications were, complications related to catheter placement procedure (8.7%), hypotension (3.5%), hypocalcaemia (3.5%) and allergic reactions (1.7%). The complication ratios were 2.7% in total 771 TPE procedures. TPE procedure was terminated in 6% of sessions depending on these complications. Overall responses to TPE were noted in 89.5% of patients. In conclusion; Therapeutic plasma exchange is an effective treatment option in several neurologic diseases.
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PMID:Therapeutic plasma exchange in patients with neurological diseases: multicenter retrospective analysis. 2361 27

Multiple sclerosis (MS) is a debilitating chronic inflammatory disease of the nervous system that affects approximately 2.3 million individuals worldwide, with higher prevalence in females, and a strong genetic component. While over 200 MS susceptibility loci have been identified in GWAS, the underlying mechanisms whereby they contribute to disease susceptibility remains ill-defined. Forward genetics approaches using conventional laboratory mouse strains are useful in identifying and functionally dissecting genes controlling disease-relevant phenotypes, but are hindered by the limited genetic diversity represented in such strains. To address this, we have combined the powerful chromosome substitution (consomic) strain approach with the genetic diversity of a wild-derived inbred mouse strain. Using experimental allergic encephalomyelitis (EAE), a mouse model of MS, we evaluated genetic control of disease course among a panel of 26 consomic strains of mice inheriting chromosomes from the wild-derived PWD strain on the C57BL/6J background, which models the genetic diversity seen in human populations. Nineteen linkages on 18 chromosomes were found to harbor loci controlling EAE. Of these 19 linkages, six were male-specific, four were female-specific, and nine were non-sex-specific, consistent with a differential genetic control of disease course between males and females. An MS-GWAS candidate-driven bioinformatic analysis using orthologous genes linked to EAE course identified sex-specific and non-sex-specific gene networks underlying disease pathogenesis. An analysis of sex hormone regulation of genes within these networks identified several key molecules, prominently including the MAP kinase family, known hormone-dependent regulators of sex differences in EAE course. Importantly, our results provide the framework by which consomic mouse strains with overall genome-wide genetic diversity, approximating that seen in humans, can be used as a rapid and powerful tool for modeling the genetic architecture of MS. Moreover, our data represent the first step towards mechanistic dissection of genetic control of sexual dimorphism in CNS autoimmunity.
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PMID:Identification of genetic determinants of the sexual dimorphism in CNS autoimmunity. 2567 58

Regulation of gene expression in immune cells is known to be under genetic control, and likely contributes to susceptibility to autoimmune diseases such as multiple sclerosis (MS). How this occurs in concert across multiple immune cell types is poorly understood. Using a mouse model that harnesses the genetic diversity of wild-derived mice, more accurately reflecting genetically diverse human populations, we provide an extensive characterization of the genetic regulation of gene expression in five different naive immune cell types relevant to MS. The immune cell transcriptome is shown to be under profound genetic control, exhibiting diverse patterns: global, cell-specific and sex-specific. Bioinformatic analysis of the genetically controlled transcript networks reveals reduced cell type specificity and inflammatory activity in wild-derived PWD/PhJ mice, compared with the conventional laboratory strain C57BL/6J. Additionally, candidate MS-GWAS (genome-wide association study candidate genes for MS susceptibility) genes were significantly enriched among transcripts overrepresented in C57BL/6J cells compared with PWD. These expression level differences correlate with robust differences in susceptibility to experimental autoimmune encephalomyelitis, the principal model of MS, and skewing of the encephalitogenic T-cell responses. Taken together, our results provide functional insights into the genetic regulation of the immune transcriptome, and shed light on how this in turn contributes to susceptibility to autoimmune disease.
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PMID:Natural genetic variation profoundly regulates gene expression in immune cells and dictates susceptibility to CNS autoimmunity. 2765 16