Machine Learning to Detect Alzheimer’s Disease from Circulating Non-coding RNAs

Machine Learning to Detect Alzheimer’s Disease from Circulating Non-coding RNAs

Blood-borne small non-coding (sncRNAs) are among the prominent candidates for blood-based diagnostic tests. Often, high-throughput approaches are applied to discover biomarker signatures. These have to be validated in larger cohorts and evaluated by adequate statistical learning approaches. Previous...

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Veröffentlicht in:Genomics, proteomics & bioinformatics proteomics & bioinformatics, 2019-08, Vol.17 (4), p.430-440
Hauptverfasser: Ludwig, Nicole, Fehlmann, Tobias, Kern, Fabian, Gogol, Manfred, Maetzler, Walter, Deutscher, Stephanie, Gurlit, Simone, Schulte, Claudia, von Thaler, Anna-Katharina, Deuschle, Christian, Metzger, Florian, Berg, Daniela, Suenkel, Ulrike, Keller, Verena, Backes, Christina, Lenhof, Hans-Peter, Meese, Eckart, Keller, Andreas
Format: Artikel
Sprache:eng
Schlagworte:
Alzheimer Disease - diagnosis
Alzheimer Disease - genetics
Alzheimer’s disease
Area Under Curve
bioinformatics
Biomarker
biomarkers
Biomarkers - blood
blood serum
cytotoxicity
disease severity
Exosomes
Female
gender
Gene regulation
genomics
Germany
High-Throughput Nucleotide Sequencing
Humans
Machine Learning
Male
microRNA
MicroRNAs - blood
MicroRNAs - genetics
miRNAs
monocytes
Monocytes - cytology
Neurodegeneration
neurodegenerative diseases
Non-coding RNAs
Original research
proteomics
Real-Time Polymerase Chain Reaction
T-Lymphocytes, Helper-Inducer - cytology
Up-Regulation
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Zusammenfassung:Blood-borne small non-coding (sncRNAs) are among the prominent candidates for blood-based diagnostic tests. Often, high-throughput approaches are applied to discover biomarker signatures. These have to be validated in larger cohorts and evaluated by adequate statistical learning approaches. Previously, we published high-throughput sequencing based microRNA (miRNA) signatures in Alzheimer’s disease (AD) patients in the United States (US) and Germany. Here, we determined abundance levels of 21 known circulating miRNAs in 465 individuals encompassing AD patients and controls by RT-qPCR. We computed models to assess the relation between miRNA expression and phenotypes, gender, age, or disease severity (Mini-Mental State Examination; MMSE). Of the 21 miRNAs, expression levels of 20 miRNAs were consistently de-regulated in the US and German cohorts. 18 miRNAs were significantly correlated with neurodegeneration (Benjamini-Hochberg adjusted P 
ISSN:1672-0229
2210-3244
DOI:10.1016/j.gpb.2019.09.004