Open AccessNoise and rank-dependent geometrical filter improves sensitivity of highly specific discovery by microarrays
Author(s) -
Hassan M. FathallahShaykh
Publication year - 2005
Publication title -
bioinformatics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.599
H-Index - 390
eISSN - 1367-4811
pISSN - 1367-4803
DOI - 10.1093/bioinformatics/bti684
Subject(s) - sensitivity (control systems) , noise (video) , filter (signal processing) , dna microarray , rank (graph theory) , computer science , pattern recognition (psychology) , computational biology , artificial intelligence , data mining , algorithm , mathematics , biology , electronic engineering , computer vision , engineering , genetics , gene expression , gene , combinatorics , image (mathematics)
MASH is a mathematical algorithm that discovers highly specific states of expression from genomic profiling by microarrays. The goal at the outset of this analysis was to improve the sensitivity of MASH. The geometrical representations of microarray datasets in the 3D space are rank-dependent and unique to each dataset. The first filter (F1) of MASH defines a zone of instability whose F1-sensitive ratios have large variations. A new filter (Fs) constructs in the 3D space rank-dependent lower and upper-bound contour surfaces, which are modeled based on the geometry of the unique noise intrinsic to each dataset. As compared with MASH, Fs increases sensitivity significantly without lowering the high specificity of discovery. Fs facilitates studies in functional genomics and systems biology.
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