We study chemical reaction networks (CRNs) as a kernel model of concurrency provided with semantics based on ordinary differential equations. We investigate the problem of comparing two CRNs, i.e., to decide whether the solutions of a source and of a target CRN can be matched for an appropriate choice of initial conditions. Using a categorical framework, we extend and unify model-comparison approaches based on dynamical (semantic) and structural (syntactic) properties of CRNs. Then, we provide an algorithm to compare CRNs, running linearly in time with respect to the cardinality of all possible comparisons. Finally, using a prototype implementation, CAGE, we apply our results to biological models from the literature
The emerging fields of genetic engineering, synthetic biology, DNA computing, DNA nanotechnology, an...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. Assuming a fixe...
Understanding the algorithmic behaviors that are in princi-ple realizable in a chemical system is ne...
We study chemical reaction networks (CRNs) as a kernel language for concurrency models with semantic...
We study chemical reaction networks (CRNs) as a kernel language for concurrency models with semantic...
We study chemical reaction networks (CRNs) as a kernel language for concurrency models with semantic...
Chemical reaction networks (CRNs) provide a convenient language for modelling a broad variety of bio...
The Chemical Reaction Network (CRN) model is a language designed to describe the behavior of chemica...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
Recent advances in systems biology have uncovered detailed mechanisms of biological pro-cesses such ...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
This paper further develops the connection between Chemical Reaction Network Theory (CRNT) and Bioch...
Motivated by the intriguing complexity of biochemical circuitry within individual cells we study Sto...
Abstract. Computational models in open model repositories support biologists in understanding and in...
The emerging fields of genetic engineering, synthetic biology, DNA computing, DNA nanotechnology, an...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. Assuming a fixe...
Understanding the algorithmic behaviors that are in princi-ple realizable in a chemical system is ne...
We study chemical reaction networks (CRNs) as a kernel language for concurrency models with semantic...
We study chemical reaction networks (CRNs) as a kernel language for concurrency models with semantic...
We study chemical reaction networks (CRNs) as a kernel language for concurrency models with semantic...
Chemical reaction networks (CRNs) provide a convenient language for modelling a broad variety of bio...
The Chemical Reaction Network (CRN) model is a language designed to describe the behavior of chemica...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
Recent advances in systems biology have uncovered detailed mechanisms of biological pro-cesses such ...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
This paper further develops the connection between Chemical Reaction Network Theory (CRNT) and Bioch...
Motivated by the intriguing complexity of biochemical circuitry within individual cells we study Sto...
Abstract. Computational models in open model repositories support biologists in understanding and in...
The emerging fields of genetic engineering, synthetic biology, DNA computing, DNA nanotechnology, an...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. Assuming a fixe...
Understanding the algorithmic behaviors that are in princi-ple realizable in a chemical system is ne...