Abstract Background Dynamic Bayesian network (DBN) is among the mainstream approaches for modeling various biological networks, including the gene regulatory network (GRN). Most current methods for learning DBN employ either local search such as hill-climbing, or a meta stochastic global optimization framework such as genetic algorithm or simulated annealing, which are only able to locate sub-optimal solutions. Further, current DBN applications have essentially been limited to small sized networks. Results To overcome the above difficulties, we introduce here a deterministic global optimization based DBN approach for reverse engineering genetic networks from time course gene expression data. For such DBN models that consist only of inter ti...
Enabled by recent advances in bioinformatics, the inference of gene regulatory networks (GRNs) from ...
Background: Dynamic Bayesian Network (DBN) is an approach widely used for reconstruction of gene reg...
The importance of 'big data' in biology is increasing as vast quantities of data are being produced ...
Background: Dynamic Bayesian network (DBN) is among the mainstream approaches for modeling various b...
BACKGROUND: Dynamic Bayesian network (DBN) is among the mainstream approaches for modeling various b...
Deciphering genetic interactions is of fundamental importance in computational systems biology, with...
Recently, there has been much interest in reverse engineering genetic networks from time series data...
Dynamic Bayesian networks (DBN) are widely applied in Systems biology for modeling various biologica...
Inferring gene regulatory networks from data requires the development of algorithms devoted to struc...
Learning optimal Bayesian networks (BN) from data is NP-hard in general. Nevertheless, certain BN cl...
Dynamic Bayesian networks (DBNs) can be used for the discovery of gene regulatory networks (GRNs) fr...
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...
A holistic understanding of genetic interactions, in the post-genomic era, is vital for analysing co...
Abstract Background A central goal of molecular biology is to understand the regulatory mechanisms o...
Enabled by recent advances in bioinformatics, the inference of gene regulatory networks (GRNs) from ...
Background: Dynamic Bayesian Network (DBN) is an approach widely used for reconstruction of gene reg...
The importance of 'big data' in biology is increasing as vast quantities of data are being produced ...
Background: Dynamic Bayesian network (DBN) is among the mainstream approaches for modeling various b...
BACKGROUND: Dynamic Bayesian network (DBN) is among the mainstream approaches for modeling various b...
Deciphering genetic interactions is of fundamental importance in computational systems biology, with...
Recently, there has been much interest in reverse engineering genetic networks from time series data...
Dynamic Bayesian networks (DBN) are widely applied in Systems biology for modeling various biologica...
Inferring gene regulatory networks from data requires the development of algorithms devoted to struc...
Learning optimal Bayesian networks (BN) from data is NP-hard in general. Nevertheless, certain BN cl...
Dynamic Bayesian networks (DBNs) can be used for the discovery of gene regulatory networks (GRNs) fr...
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...
A holistic understanding of genetic interactions, in the post-genomic era, is vital for analysing co...
Abstract Background A central goal of molecular biology is to understand the regulatory mechanisms o...
Enabled by recent advances in bioinformatics, the inference of gene regulatory networks (GRNs) from ...
Background: Dynamic Bayesian Network (DBN) is an approach widely used for reconstruction of gene reg...
The importance of 'big data' in biology is increasing as vast quantities of data are being produced ...