In this work we simulate gene knock-out experiments in networks in which variable domains are continuous and variables can vary continuously in time. This model is more realistic than other well-known switching networks such as Boolean Networks. We show that continuous networks can reproduce the results obtained by Random Boolean Networks (RBN). Nevertheless, they do not reproduce the whole range of activation values of actual experimental data. The reasons for this behavior very close to that of RBN could be found in the specific parameter setting chosen and lines for further investigation are discussed
Motivation: For biological pathways, it is common to measure a gene expression time series after var...
Motivation: For biological pathways, it is common to measure a gene expression time series after var...
This paper describes the effects of perturbations, whichsimulate the knock-out of single genes, one ...
In this work we simulate gene knock-out experiments in networks in which variable domains are contin...
It is shown here how gene knock-out experiments can be simulatedin Random Boolean Networks (RBN), wh...
analysis of avalanche distribution in the Glass continuous model of genetic network
This paper describes the effects of perturbations, which simulatethe knock-out of single genes, one ...
Random boolean networks (RBN) have been proposed more thanthirty years ago as models of genetic regu...
We emphasize here the importance of generic models of biological systems that aim at describing the ...
Growing information and knowledge on gene regulatory networks, which are typical hybrid systems, has...
We describe here and discuss in detail the model of random Boolean networks (RBNs). Although these m...
We investigate the effects of constitutive gene activation upon the dynamics of random Boolean netwo...
Random boolean networks are a model of genetic regulatory networks that has proven able to describe ...
Gene regulatory networks, like any evolving biological system, are subject to potentially damaging m...
We analyze the perturbation of the expression levels of thousandsof genes when one of them is knocke...
Motivation: For biological pathways, it is common to measure a gene expression time series after var...
Motivation: For biological pathways, it is common to measure a gene expression time series after var...
This paper describes the effects of perturbations, whichsimulate the knock-out of single genes, one ...
In this work we simulate gene knock-out experiments in networks in which variable domains are contin...
It is shown here how gene knock-out experiments can be simulatedin Random Boolean Networks (RBN), wh...
analysis of avalanche distribution in the Glass continuous model of genetic network
This paper describes the effects of perturbations, which simulatethe knock-out of single genes, one ...
Random boolean networks (RBN) have been proposed more thanthirty years ago as models of genetic regu...
We emphasize here the importance of generic models of biological systems that aim at describing the ...
Growing information and knowledge on gene regulatory networks, which are typical hybrid systems, has...
We describe here and discuss in detail the model of random Boolean networks (RBNs). Although these m...
We investigate the effects of constitutive gene activation upon the dynamics of random Boolean netwo...
Random boolean networks are a model of genetic regulatory networks that has proven able to describe ...
Gene regulatory networks, like any evolving biological system, are subject to potentially damaging m...
We analyze the perturbation of the expression levels of thousandsof genes when one of them is knocke...
Motivation: For biological pathways, it is common to measure a gene expression time series after var...
Motivation: For biological pathways, it is common to measure a gene expression time series after var...
This paper describes the effects of perturbations, whichsimulate the knock-out of single genes, one ...