Mechanistic mathematical modeling of biochemical reaction networks using ordinary differential equation (ODE) models has improved our understanding of small- and medium-scale biological processes. While the same should in principle hold for large- and genome-scale processes, the computational methods for the analysis of ODE models which describe hundreds or thousands of biochemical species and reactions are missing so far. While individual simulations are feasible, the inference of the model parameters from experimental data is computationally too intensive. In this manuscript, we evaluate adjoint sensitivity analysis for parameter estimation in large scale biochemical reaction networks. We present the approach for time discrete measurement...
Characterization of complex cellular behaviors on a molecular scale requires detailed understanding ...
The paper is focused on sensitivity analysis of large-scale models of biological systems that descri...
Systems biology applies quantitative, mechanistic modelling to study genetic networks, signal transd...
Ordinary differential equation models have become a standard tool for the mechanistic description of...
Mathematical modelling opens the door to a rich pathway to study the dynamic properties of biologica...
Abstract. In recent years, the modeling and simulation of biochemical networks has attracted increas...
Many complex kinetic models in the field of biochemical reactions contain a large number of species ...
Background: Stochastic modeling and simulation provide powerful predictive methods for the intrinsic...
Motivation: Cellular information processing can be described mathematically using differential equat...
International audienceCellular processes such as metabolism, decision making in development and diff...
Abstract: The complexity of even comparatively simple biochemical systems necessitates a computation...
International audienceBiochemical networks are used in computational biology, to model the static an...
Funding: This research was funded by the BBSRC Grant BB/K003097/1 (Systems Biology Analysis of Biolo...
Motivation: Stochastic molecular processes are a leading cause of cell-to-cell variability. Their dy...
Stochastic methods for simulating biochemical reaction networks often provide a more realistic descr...
Characterization of complex cellular behaviors on a molecular scale requires detailed understanding ...
The paper is focused on sensitivity analysis of large-scale models of biological systems that descri...
Systems biology applies quantitative, mechanistic modelling to study genetic networks, signal transd...
Ordinary differential equation models have become a standard tool for the mechanistic description of...
Mathematical modelling opens the door to a rich pathway to study the dynamic properties of biologica...
Abstract. In recent years, the modeling and simulation of biochemical networks has attracted increas...
Many complex kinetic models in the field of biochemical reactions contain a large number of species ...
Background: Stochastic modeling and simulation provide powerful predictive methods for the intrinsic...
Motivation: Cellular information processing can be described mathematically using differential equat...
International audienceCellular processes such as metabolism, decision making in development and diff...
Abstract: The complexity of even comparatively simple biochemical systems necessitates a computation...
International audienceBiochemical networks are used in computational biology, to model the static an...
Funding: This research was funded by the BBSRC Grant BB/K003097/1 (Systems Biology Analysis of Biolo...
Motivation: Stochastic molecular processes are a leading cause of cell-to-cell variability. Their dy...
Stochastic methods for simulating biochemical reaction networks often provide a more realistic descr...
Characterization of complex cellular behaviors on a molecular scale requires detailed understanding ...
The paper is focused on sensitivity analysis of large-scale models of biological systems that descri...
Systems biology applies quantitative, mechanistic modelling to study genetic networks, signal transd...