Add to ORKGWe investigate in this paper reverse engineering of gene regulatory networks from time-series microarray data. We apply dynamic Bayesian networks (DBNs) for modeling cell cycle regulations. In developing a network inference algorithm, we focus on soft solutions that can provide a posteriori probability (APP) of network topology. In particular, we propose a variational Bayesian structural expectation maximization algorithm that can learn the posterior distribution of the network model parameters and topology jointly. We also show how the obtained APPs of the network topology can be used in a Bayesian data integration strategy to integrate two different microarray data sets. The proposed VBSEM algorithm has been tested on yeast cell cycle dat...
This article deals with the identification of gene regula-tory networks from experimental data using...
Gene regulatory networks are a visual representation of genes and their interactions. In this visual...
Background: A central goal of molecular biology is to understand the regulatory mechanisms of gene t...
The inference of gene regulatory networks (GRN) from microarrray data suffers from the low accuracy ...
Two major challenges in inferring the sparse topological architecture of Gene Regulatory Networks us...
Enabled by recent advances in bioinformatics, the inference of gene regulatory networks (GRNs) from ...
Differential equations have been established to model the dynamic behavior of gene regulatory networ...
Method: Dynamic Bayesian networks (DBNs) have been applied widely to reconstruct the structure of re...
Method: Dynamic Bayesian networks (DBNs) have been applied widely to reconstruct the structure of re...
The experimental microarray data has the potential application in determining the underlying mechani...
Exploring gene regulatory network is a key topic in molecular biology. In this paper, we present a n...
Gene regulatory networks are collections of genes that interact, whether directly or indirectly, wit...
Inferring gene regulatory networks (GRNs) is a challenging inverse problem. Most existing approaches...
Background: Dynamic Bayesian Network (DBN) is an approach widely used for reconstruction of gene reg...
In this paper, we apply Bayesian networks (BN) to infer gene regulatory network (GRN) model from gen...
This article deals with the identification of gene regula-tory networks from experimental data using...
Gene regulatory networks are a visual representation of genes and their interactions. In this visual...
Background: A central goal of molecular biology is to understand the regulatory mechanisms of gene t...
The inference of gene regulatory networks (GRN) from microarrray data suffers from the low accuracy ...
Two major challenges in inferring the sparse topological architecture of Gene Regulatory Networks us...
Enabled by recent advances in bioinformatics, the inference of gene regulatory networks (GRNs) from ...
Differential equations have been established to model the dynamic behavior of gene regulatory networ...
Method: Dynamic Bayesian networks (DBNs) have been applied widely to reconstruct the structure of re...
Method: Dynamic Bayesian networks (DBNs) have been applied widely to reconstruct the structure of re...
The experimental microarray data has the potential application in determining the underlying mechani...
Exploring gene regulatory network is a key topic in molecular biology. In this paper, we present a n...
Gene regulatory networks are collections of genes that interact, whether directly or indirectly, wit...
Inferring gene regulatory networks (GRNs) is a challenging inverse problem. Most existing approaches...
Background: Dynamic Bayesian Network (DBN) is an approach widely used for reconstruction of gene reg...
In this paper, we apply Bayesian networks (BN) to infer gene regulatory network (GRN) model from gen...
This article deals with the identification of gene regula-tory networks from experimental data using...
Gene regulatory networks are a visual representation of genes and their interactions. In this visual...
Background: A central goal of molecular biology is to understand the regulatory mechanisms of gene t...