Construction of GRN for Lung Cancer Datasets Using Weighted Co-Expression Networks

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dc.contributor.author Rafsanzani, H. M.
dc.contributor.author Anan, Samin
dc.date.accessioned 2020-10-19T17:51:24Z
dc.date.available 2020-10-19T17:51:24Z
dc.date.issued 2018-11-15
dc.identifier.citation 1. Yoli Shavitab, Boyan Yordanovb, Sara-Jane Dunnb, Christoph M. Wintersteigerb, Tomoki Otania, Youssef Hamadib, Frederick J. Liveseya, Hillel Kuglerbc, Automated Synthesis and Analysis of Switching Gene Regulatory Networks, Biosystems 146(2016)26-34. 2. S.-J. Dun et al, Defining an essential transcription factor program for naïve pluripotency, Science 1156 (2014), 10.1126/science.1248882. 3. Boyan Yordanov, Sara-Jane Dunn, Hillel Kugler, Austin Smith, Graziano Martello and Stephen Emmott, a method to identify and analyze biological programs through automated reasoning, 16010; 10.1038/npjsba.2016.10. 4. Yoli Shavit, Boyan Yordanov, Sara-Jane Dunn, Christoph M. Wintersteiger, Youssef Hamadi, and Hillel Kugler, University of Cambridge, UK Microsoft Research, Bar-Ilan University, Israel, Switching Gene Regulatory Networks, 10.1007/978-3-319-23108-2_11. 5. SOMKID INTEP, DESMOND J. HIGHAM, XUERONG MAO, SWITCHING AND DIFFUSION MODELS FOR GENE REGULATION NETWORKS, 10.1137/080735412. en_US
dc.identifier.uri http://hdl.handle.net/123456789/550
dc.description Supervised by Mr. Tareque Mohmud Chowdhury en_US
dc.description.abstract Gene co-expression networks can be used to associate genes of unknown function with biological processes, to prioritize candidate disease genes or to discern transcriptional regulatory programmes. With recent advances in transcriptomics and next-generation sequencing, co-expression networks constructed from RNA sequencing data also enable the inference of functions and disease associations for non-coding genes and splice variants. Although gene co-expression networks typically do not provide information about causality, emerging methods for differential co-expression analysis are enabling the identification of regulatory genes underlying various phenotypes. Correlation networks are increasingly being used in bioinformatics applications. For example, weighted gene co-expression network analysis is a systems biology method for describing the correlation patterns among genes across microarray samples. Weighted correlation network analysis (WGCNA) can be used for finding clusters (modules) of highly correlated genes, for summarizing such clusters using the module eigengene or an intramodular hub gene, for relating modules to one another and to external sample traits (using eigengene network methodology), and for calculating module membership measures. Correlation networks facilitate network based gene screening methods that can be used to identify candidate biomarkers or therapeutic targets. Gene regulatory networks can be used to identify the genes of cancer affected patients that are responsible for tumor formation. We provide a method to use weighted gene co-expression network analysis to identify genes that are responsible for cancer patient based on clinical trait information by cross- matching with healthy patient genes. en_US
dc.language.iso en en_US
dc.publisher Department of Computer Science and Engineering, Islamic University of Technology, Board Bazar, Gazipur, Bangladesh en_US
dc.title Construction of GRN for Lung Cancer Datasets Using Weighted Co-Expression Networks en_US
dc.type Thesis en_US


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