A comprehensive survey on computational learning methods for analysis of gene expression data

Computational analysis methods including machine learning have a significant impact in the fields of genomics and medicine. High-throughput gene expression analysis methods such as microarray technology and RNA sequencing produce enormous amounts of data. Traditionally, statistical methods are used...

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Veröffentlicht in:	arXiv.org 2022-09
Hauptverfasser:	Bhandari, Nikita, Walambe, Rahee, Kotecha, Ketan, Khare, Satyajeet
Format:	Artikel
Sprache:	eng
Schlagworte:	Data analysis Feature extraction Gene expression Gene sequencing Genomics Machine learning Proteomics Ribonucleic acid RNA Software Standardization Statistical methods
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creator	Bhandari, Nikita Walambe, Rahee Kotecha, Ketan Khare, Satyajeet
description	Computational analysis methods including machine learning have a significant impact in the fields of genomics and medicine. High-throughput gene expression analysis methods such as microarray technology and RNA sequencing produce enormous amounts of data. Traditionally, statistical methods are used for comparative analysis of gene expression data. However, more complex analysis for classification of sample observations, or discovery of feature genes requires sophisticated computational approaches. In this review, we compile various statistical and computational tools used in analysis of expression microarray data. Even though the methods are discussed in the context of expression microarrays, they can also be applied for the analysis of RNA sequencing and quantitative proteomics datasets. We discuss the types of missing values, and the methods and approaches usually employed in their imputation. We also discuss methods of data normalization, feature selection, and feature extraction. Lastly, methods of classification and class discovery along with their evaluation parameters are described in detail. We believe that this detailed review will help the users to select appropriate methods for preprocessing and analysis of their data based on the expected outcome.
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subjects	Data analysis Feature extraction Gene expression Gene sequencing Genomics Machine learning Proteomics Ribonucleic acid RNA Software Standardization Statistical methods
title	A comprehensive survey on computational learning methods for analysis of gene expression data
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