The discovery of gene regulatory network (GRN) using gene expression data is one of the promising directions for deciphering biological mechanisms, which underlie many basic aspects of scientific and medical advances. In this thesis, we focus on the reconstruction of GRN from time-series data using a Granger causality (GC) approach. As there is little existing research on combining data from multiple time-series experiments, we identify the need for developing a methodology with underlying theory to combine multiple experiments for statistical significant discovery. We derive a statistical theory for intersection of two discovered networks. Such a statistical framework is novel and intended for our GRN discovery problem. However, this th...
Gene regulatory network inference is essential to uncover complex relationships among gene pathways ...
Gene regulatory network inference is essential to uncover complex relationships among gene pathways ...
Abstract Background Reverse engineering of gene regul...
Article no. 6314142Granger causality (GC) has been applied to gene regulatory network discovery usin...
Background: Inference and understanding of gene networks from experimental data is an important but ...
Identifying regulatory genes partaking in disease development is important to medical advances. Sinc...
Understanding the interactions of genes plays a vital role in the analysis of complex biological sys...
We introduce a novel method called Prophetic Granger Causality (PGC) for inferring gene regulatory n...
Background Reverse-engineering approaches such as Bayesian network inference, ordinary differential...
Abstract—Identifying regulatory genes partaking in disease development is important to medical advan...
Inferring the gene regulatory network (GRN) is crucial to understanding the working of the cell. Man...
Biological network diagrams provide a natural means to characterize the association between biologic...
Modern technologies and especially next generation sequencing facilities are giving a cheaper access...
This volume explores recent techniques for the computational inference of gene regulatory networks (...
International audienceBACKGROUND: Reverse engineering in systems biology entails inference of gene r...
Gene regulatory network inference is essential to uncover complex relationships among gene pathways ...
Gene regulatory network inference is essential to uncover complex relationships among gene pathways ...
Abstract Background Reverse engineering of gene regul...
Article no. 6314142Granger causality (GC) has been applied to gene regulatory network discovery usin...
Background: Inference and understanding of gene networks from experimental data is an important but ...
Identifying regulatory genes partaking in disease development is important to medical advances. Sinc...
Understanding the interactions of genes plays a vital role in the analysis of complex biological sys...
We introduce a novel method called Prophetic Granger Causality (PGC) for inferring gene regulatory n...
Background Reverse-engineering approaches such as Bayesian network inference, ordinary differential...
Abstract—Identifying regulatory genes partaking in disease development is important to medical advan...
Inferring the gene regulatory network (GRN) is crucial to understanding the working of the cell. Man...
Biological network diagrams provide a natural means to characterize the association between biologic...
Modern technologies and especially next generation sequencing facilities are giving a cheaper access...
This volume explores recent techniques for the computational inference of gene regulatory networks (...
International audienceBACKGROUND: Reverse engineering in systems biology entails inference of gene r...
Gene regulatory network inference is essential to uncover complex relationships among gene pathways ...
Gene regulatory network inference is essential to uncover complex relationships among gene pathways ...
Abstract Background Reverse engineering of gene regul...