Efforts in programming DNA and other biological molecules have recently focused on general schemes to physically implement arbitrary Chemical Reaction Networks. Errors in some of the proposed schemes have driven a desire for formal verification methods. We show that by interpreting each implementation species as a set of formal species, the concept of weak bisimulation can be adapted to CRNs in a way that agrees with an intuitive notion of a correct implementation. We give examples of how to use bisimulation to prove the correctness of an implementation or detect subtle problems. We examine the complexity of finding a valid interpretation between two CRNs if one exists, and that of checking whether an interpretation is valid. We show that b...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. CRNs are widely...
When disallowing error, traditional chemical reaction networks are very limited in computational pow...
Motivated by the intriguing complexity of biochemical circuitry within individual cells we study Sto...
Efforts in programming DNA and other biological molecules have recently focused on general schemes t...
The Chemical Reaction Network (CRN) model is a language designed to describe the behavior of chemica...
The Chemical Reaction Network model has been proposed as a programming language for molecular progra...
The emerging fields of genetic engineering, synthetic biology, DNA computing, DNA nanotechnology, an...
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...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. Assuming a fixe...
International audienceOne goal of synthetic biology is to implement useful functions with biochemica...
The mathematical formalism of mass-action chemical reaction networks (CRNs) has been proposed as a m...
The computational ability of the chemical reaction networks (CRNs) using DNA as the substrate has be...
The contributions of this thesis are motivated by an exciting challenge at the intersection of comp...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. CRNs are widely...
When disallowing error, traditional chemical reaction networks are very limited in computational pow...
Motivated by the intriguing complexity of biochemical circuitry within individual cells we study Sto...
Efforts in programming DNA and other biological molecules have recently focused on general schemes t...
The Chemical Reaction Network (CRN) model is a language designed to describe the behavior of chemica...
The Chemical Reaction Network model has been proposed as a programming language for molecular progra...
The emerging fields of genetic engineering, synthetic biology, DNA computing, DNA nanotechnology, an...
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...
We present two quantitative behavioral equivalences over species of a chemical reaction network (CRN...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. Assuming a fixe...
International audienceOne goal of synthetic biology is to implement useful functions with biochemica...
The mathematical formalism of mass-action chemical reaction networks (CRNs) has been proposed as a m...
The computational ability of the chemical reaction networks (CRNs) using DNA as the substrate has be...
The contributions of this thesis are motivated by an exciting challenge at the intersection of comp...
Chemical reaction networks (CRNs) formally model chemistry in a well-mixed solution. CRNs are widely...
When disallowing error, traditional chemical reaction networks are very limited in computational pow...
Motivated by the intriguing complexity of biochemical circuitry within individual cells we study Sto...