Monitoring of technical variation in quantitative high-throughput datasets

M Lauss, I Visne, A Kriegner, M Ringnér… - Cancer …, 2013 - journals.sagepub.com
M Lauss, I Visne, A Kriegner, M Ringnér, G Jönsson, M Höglund
Cancer informatics, 2013journals.sagepub.com
High-dimensional datasets can be confounded by variation from technical sources, such as
batches. Undetected batch effects can have severe consequences for the validity of a study's
conclusion (s). We evaluate high-throughput RNAseq and miRNAseq as well as DNA
methylation and gene expression microarray datasets, mainly from the Cancer Genome
Atlas (TCGA) project, in respect to technical and biological annotations. We observe
technical bias in these datasets and discuss corrective interventions. We then suggest a …
High-dimensional datasets can be confounded by variation from technical sources, such as batches. Undetected batch effects can have severe consequences for the validity of a study's conclusion(s). We evaluate high-throughput RNAseq and miRNAseq as well as DNA methylation and gene expression microarray datasets, mainly from the Cancer Genome Atlas (TCGA) project, in respect to technical and biological annotations. We observe technical bias in these datasets and discuss corrective interventions. We then suggest a general procedure to control study design, detect technical bias using linear regression of principal components, correct for batch effects, and re-evaluate principal components. This procedure is implemented in the R package swamp, and as graphical user interface software. In conclusion, high-throughput platforms that generate continuous measurements are sensitive to various forms of technical bias. For such data, monitoring of technical variation is an important analysis step.
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