Background Recovering the network topology and associated kinetic parameter values from time-series data are central topics in systems biology. Nevertheless, methods that simultaneously do both are few and lack generality. Results Here, we present a rigorous approach for simultaneously estimating the parameters and regulatory topology of biochemical networks from time-series data. The parameter estimation task is formulated as a mixed-integer dynamic optimization problem with: (i) binary variables, used to model the existence of regulatory interactions and kinetic effects of metabolites in the network processes; and (ii) continuous variables, denoting metabolites concentrations and kinetic parameters values. The approach simultaneously...
Mathematical modeling and analysis of biochemical reaction networks are key routines in computationa...
Dynamic models present a fundamental tool in systems biology, but rely on kinetic parameters, such a...
Dynamic models present a fundamental tool in systems biology, but rely on kinetic parameters, such a...
Background: Recovering the network topology and associated kinetic parameter values from time-series...
154 páginasKinetic models are central in systems biology to describe and analyse metabolic, generic ...
Background Determining the interaction topology of biological systems is a topic that currently att...
Abstract. In recent years, the modeling and simulation of biochemical networks has attracted increas...
Background: Determining the interaction topology of biological systems is a topic that currently at...
Background Accurate estimation of parameters of biochemical models is required to characterize the d...
ObjectiveThe complexity of biochemical networks is enormous and difficult to unravel by intuitive re...
Motivation: Network models are widely used as structural summaries of biochemical systems. Statistic...
Mathematical modelling opens the door to a rich pathway to study the dynamic properties of biologica...
Systems biology applies quantitative, mechanistic modelling to study genetic networks, signal transd...
Motivation: The inference of biochemical networks, such as gene regulatory networks, protein–protein...
Mathematical modeling and analysis of biochemical reaction networks are key routines in computationa...
Dynamic models present a fundamental tool in systems biology, but rely on kinetic parameters, such a...
Dynamic models present a fundamental tool in systems biology, but rely on kinetic parameters, such a...
Background: Recovering the network topology and associated kinetic parameter values from time-series...
154 páginasKinetic models are central in systems biology to describe and analyse metabolic, generic ...
Background Determining the interaction topology of biological systems is a topic that currently att...
Abstract. In recent years, the modeling and simulation of biochemical networks has attracted increas...
Background: Determining the interaction topology of biological systems is a topic that currently at...
Background Accurate estimation of parameters of biochemical models is required to characterize the d...
ObjectiveThe complexity of biochemical networks is enormous and difficult to unravel by intuitive re...
Motivation: Network models are widely used as structural summaries of biochemical systems. Statistic...
Mathematical modelling opens the door to a rich pathway to study the dynamic properties of biologica...
Systems biology applies quantitative, mechanistic modelling to study genetic networks, signal transd...
Motivation: The inference of biochemical networks, such as gene regulatory networks, protein–protein...
Mathematical modeling and analysis of biochemical reaction networks are key routines in computationa...
Dynamic models present a fundamental tool in systems biology, but rely on kinetic parameters, such a...
Dynamic models present a fundamental tool in systems biology, but rely on kinetic parameters, such a...