AI Article Synopsis
- Chemical organisation theory simplifies the analysis of chemical systems' long-term behavior and is expanded here with new techniques for quantitative analysis of chemical reaction networks using continuous-time Markov chains.
- The study introduces methods to identify the structures (or organisations) within these networks and analyze the movement between them.
- A coarse-grained Markov chain model is developed to approximate the original network's behavior, enabling predictions over time, with experiments showing improved predictive precision through selective refinement of the models.*
Article Abstract
Chemical organisation theory is a framework developed to simplify the analysis of long-term behaviour of chemical systems. In this work, we build on these ideas to develop novel techniques for formal quantitative analysis of chemical reaction networks, using discrete stochastic models represented as continuous-time Markov chains. We propose methods to identify organisations, and to study quantitative properties regarding movements between these organisations. We then construct and formalise a coarse-grained Markov chain model of hierarchic organisations for a given reaction network, which can be used to approximate the behaviour of the original reaction network. As an application of the coarse-grained model, we predict the behaviour of the reaction network systems over time via the master equation. Experiments show that our predictions can mimic the main pattern of the concrete behaviour in the long run, but the precision varies for different models and reaction rule rates. Finally, we propose an algorithm to selectively refine the coarse-grained models and show experiments demonstrating that the precision of the prediction has been improved.
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| http://dx.doi.org/10.1109/TCBB.2018.2804395 | DOI Listing |
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