Stiffness in chemical reaction systems is a frequently encountered computational problem, arising when different reactions in the system take place at different time-scales. Computational savings can be obtained under time-scale separation. Assuming that the system can be partitioned into slow- and fast- equilibrating subsystems, it is then possible to efficiently simulate the slow subsystem only, provided that the corresponding kinetic laws have been modified so that they reflect their dependency on the fast system. We show that the rate expectation with respect to the fast subsystem\u2019s steady-state is a continuous function of the state of the slow system. We exploit this result to construct an analytic representation of the modified r...
BACKGROUND: It is well known that the deterministic dynamics of biochemical reaction networks can be...
Recently the application of the quasi-steady-state approximation (QSSA) to the stochastic simulation...
The frequently used reduction technique is based on the chemical master equation for stochastic chem...
Reactions in real chemical systems often take place on vastly different time scales, with "fast" rea...
AbstractMany physiological characteristics of living cells are regulated by protein interaction netw...
We present an efficient numerical algorithm for simulating chemical kinetic systems with multiple ti...
We propose a stochastic model reduction strategy for deterministic and stochastic slow-fast systems ...
AbstractIn biochemical networks, reactions often occur on disparate timescales and can be characteri...
We consider stochastic descriptions of chemical reaction networks in which there are both fast and s...
Reaction rate equations are ordinary differential equations that are frequently used to describe det...
Stochastic simulation of coupled chemical reactions is often computationally intensive, especially i...
We present a simple algorithm for the simulation of stiff, discrete-space, continuous-time Markov pr...
The slow-scale linear noise approximation: an accurate, reduced stochastic description of biochemica...
For chemical systems involving both fast and slow scales, stiffness presents challenges for efficien...
In this paper we give an overview of some very recent work on the stochastic simulation of systems i...
BACKGROUND: It is well known that the deterministic dynamics of biochemical reaction networks can be...
Recently the application of the quasi-steady-state approximation (QSSA) to the stochastic simulation...
The frequently used reduction technique is based on the chemical master equation for stochastic chem...
Reactions in real chemical systems often take place on vastly different time scales, with "fast" rea...
AbstractMany physiological characteristics of living cells are regulated by protein interaction netw...
We present an efficient numerical algorithm for simulating chemical kinetic systems with multiple ti...
We propose a stochastic model reduction strategy for deterministic and stochastic slow-fast systems ...
AbstractIn biochemical networks, reactions often occur on disparate timescales and can be characteri...
We consider stochastic descriptions of chemical reaction networks in which there are both fast and s...
Reaction rate equations are ordinary differential equations that are frequently used to describe det...
Stochastic simulation of coupled chemical reactions is often computationally intensive, especially i...
We present a simple algorithm for the simulation of stiff, discrete-space, continuous-time Markov pr...
The slow-scale linear noise approximation: an accurate, reduced stochastic description of biochemica...
For chemical systems involving both fast and slow scales, stiffness presents challenges for efficien...
In this paper we give an overview of some very recent work on the stochastic simulation of systems i...
BACKGROUND: It is well known that the deterministic dynamics of biochemical reaction networks can be...
Recently the application of the quasi-steady-state approximation (QSSA) to the stochastic simulation...
The frequently used reduction technique is based on the chemical master equation for stochastic chem...