Strategy-Driven Exploration for Rule-Based Models of Biochemical Systems with Porgy

Andrei, Oana; Fernández, Maribel; Kirchner, Hélène; Pinaud, Bruno

doi:10.1007/978-1-4939-9102-0_3

Cited by 3 publications

(4 citation statements)

References 39 publications

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“…A variety of GTS tools are available: among others we can cite GROOVE [19], a graph-based model checker for object oriented systems; AGG (the Attributed Graph Grammar System) [31], a graph-based language for the transformation of attributed graphs that comes with a visual programming environment; PROGRES (Programmed Graph Rewriting Systems) [29] that offers backtracking and nondeterministic constructs; GrGen (Graph Rewrite Generator) [18] that uses attributed typed multigraphs and includes features such as Java/C code generation, and GP [28], a graph programming language, where users can define rules and strategy expressions, with support for conditional rewriting. PORGY [14] has been used to model social networks [15] and database design [34,16], as well as biochemical processes [2], where non-determinism, backtracking, positioning constructs, and probabilistic rule application are key features. A distinctive feature of PORGY is that rewriting derivations are directly available to users via the so-called derivation tree, which provides a visual representation of the dynamics of the system modelled and can be used to plot parameters and generate charts as illustrated in Section 4.…”

Section: Related Workmentioning

confidence: 99%

A Strategic Graph Rewriting Model of Rational Negligence in Financial Markets

Ene

Fernández

Pinaud

2020

Springer Proceedings in Mathematics &Amp; Statistics

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We propose to use strategic port graph rewriting as a visual modelling tool to analyse financial market processes. We illustrate the approach by specifying a basic "rational negligence" model in which investors may choose to trade securities without performing independent evaluations of the underlying assets. We show that our model is correct with respect to the equational model and can be used to simulate simple market behaviours. The model has been implemented within PORGY, a graph-based specification and simulation environment.

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Section: Related Workmentioning

confidence: 99%

A Strategic Graph Rewriting Model of Rational Negligence in Financial Markets

Ene

Fernández

Pinaud

2020

Springer Proceedings in Mathematics &Amp; Statistics

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“…To be legible, labels in the figure should use the same (or larger) font size as the caption font, not smaller. Fig 4A shows PPI data from Andrei and colleagues [34], in which the node labels are too small to be legible. In Fig 4B, the layout has been modified to make better use of the available space, resulting in larger labels.…”

Section: Rule 4: Provide Readable Labels and Captionsmentioning

confidence: 99%

“…(A) An example network based on PPI data from Andrei and colleagues [34], in which the node labels are too small to be legible. (B) The same network, but this time the layout has been improved to make better use of the available space, resulting in larger labels.…”

Section: Rule 4: Provide Readable Labels and Captionsmentioning

confidence: 99%

Ten simple rules to create biological network figures for communication

Marai¹,

Pinaud²,

Bühler³

et al. 2019

PLoS Comput Biol

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Biological network figures are ubiquitous in the biology and medical literature. On the one hand, a good network figure can quickly provide information about the nature and degree of interactions between items and enable inferences about the reason for those interactions. On the other hand, good network figures are difficult to create. In this paper, we outline 10 simple rules for creating biological network figures for communication, from choosing layouts, to applying color or other channels to show attributes, to the use of layering and separation. These rules are accompanied by illustrative examples. We also provide a concise set of references and additional resources for each rule.

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“…In [19], the authors advocate the use of higher-order logic to formalize reaction kinetics and exploit the HOL Light theorem prover to verify some reaction-based models of biological networks. Finally, the Porgy system is introduced in [20]. It is a visual environment which allows modelling of biochemical systems as rule-based models.…”

Section: Introductionmentioning

confidence: 99%

Modelling and Verifying Dynamic Properties of Biological Neural Networks in Coq

Bahrami

Maria

Felty

2018

Proceedings of the 9th International Conference on Computational Systems-Biology and Bioinformatics

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Formal verification has become increasingly important because of the kinds of guarantees that it can provide for software systems. Verification of models of biological and medical systems is a promising application of formal verification. Human neural networks have recently been emulated and studied as a biological system. Some recent research has been done on modelling some crucial neuronal circuits and using model checking techniques to verify their temporal properties. In large case studies, model checkers often cannot prove the given property at the desired level of generality. In this paper, we provide a model using the Coq Proof Assistant and prove properties concerning the dynamic behavior of some basic neuronal structures. Understanding the behavior of these modules is crucial because they constitute the elementary building blocks of bigger neuronal circuits. By using a proof assistant, we guarantee that the properties are true for any input values, any length of input, and any amount of time. With such a model, there is the potential to detect inactive regions of the human brain and to treat mental disorders. Furthermore, our approach can be generalized to the verification of other kinds of networks, such as regulatory, metabolic, or environmental networks.

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Strategy-Driven Exploration for Rule-Based Models of Biochemical Systems with Porgy

Cited by 3 publications

References 39 publications

A Strategic Graph Rewriting Model of Rational Negligence in Financial Markets

A Strategic Graph Rewriting Model of Rational Negligence in Financial Markets

Ten simple rules to create biological network figures for communication

Modelling and Verifying Dynamic Properties of Biological Neural Networks in Coq

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