Reaction Networks as a Language for Systemic Modeling: On the Study of Structural Changes

Veloz, Tomás; Razeto‐Barry, Pablo

doi:10.3390/systems5020030

Cited by 7 publications

(12 citation statements)

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“…Second, it is necessary to develop measures of stability indicators such as resilience, robustness, adaptivity and so in the language of reaction networks. In [70] and [24] some ideas have been advanced in this respect. Third, it is important to extend COT to represent ecological interactions in space.…”

Section: Resultsmentioning

confidence: 99%

“…When a structural perturbation occurs the organizational structure itself is modified. A decomposition theorem for organization allows to identify the parts of the organizational structure that are affected by the structural perturbation, and thus different algorithms have proved that computing the organizational structure is feasible for reactions networks of hundreds or even thousands of species [8,70,72].…”

Section: Chemical Organization Theorymentioning

confidence: 99%

“…In particular, since organizations at the higher levels of the hierarchy can be understood as combinations of organizations at lower levels, COT relates the recursive structure of organizations to the stability of the reaction network. For example, in [70] it is shown that organizations function in dynamically independent modules, and some of these modules are more fragile to perturbations than others, while in [72] it is found that the dynamical analysis of a certain organizations can be disregarded because their dynamical properties can be obtained from the dynamics of the smaller organizations that are contained in them. In this vein, complexity indicators such as synergy and non-decomposability have been developed to better understand those cases.…”

Section: Cot and The Complexity-stability Debatementioning

confidence: 99%

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The Complexity–Stability Debate, Chemical Organization Theory, and the Identification of Non-classical Structures in Ecology

Veloz

2019

Found Sci

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We present a novel approach to represent ecological systems using reaction networks, and show how a particular framework called Chemical Organization Theory (COT) sheds new light on the longstanding complexity-stability debate. Namely, COT provides a novel conceptual landscape plenty of analytic tools to explore the interplay between structure and stability of ecological systems. Given a large set of species and their interactions, COT identifies, in a computationally feasible way, each and every sub-collection of species that is closed and self-maintaining. These sub-collections, called organizations, correspond to the groups of species that can survive together (co-exist) in the long-term. Thus, the set of organizations contains all the stable regimes that can possibly happen in the dynamics of the ecological system. From here, we propose to conceive the notion of stability from the properties of the organizations, and thus apply the vast knowledge on the stability of reaction networks to the Complexity-Stability debate. As an example of the potential of COT to introduce new mathematical tools, we show that the set of organizations can be equipped with suitable joint and meet operators, and that for certain ecological systems the organizational structure is a non-boolean lattice, providing in this way an unexpected connection between logico-algebraic structures, popular in the foundations of quantum theory, and ecology. networks [46]. From here, a myriad of studies have supported the two opposite views. This controversy became known as the Complexity-Stability problem, or the Complexity-Stability debate [47].Recently, some of the most prominent figures around the Complexity-Stability debate have concluded that radically novel approaches are required to understand how different types of ecological interactions develop multi-dimensional architectures that lead to stable ecosystems. For example,in [14] they claim:We assess the scientific and policy literature and show that this disconnect is one consequence of an inconsistent and one-dimensional approach that ecologists have taken to both disturbances and stability.This has led to confused communication of the nature of stability and the level of our insight into it. Disturbances and stability are multidimensional. Our understanding of them is not.

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Section: Resultsmentioning

confidence: 99%

Section: Chemical Organization Theorymentioning

confidence: 99%

Section: Cot and The Complexity-stability Debatementioning

confidence: 99%

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The Complexity–Stability Debate, Chemical Organization Theory, and the Identification of Non-classical Structures in Ecology

Veloz

2019

Found Sci

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“…Namely, a goal might be reached by the parallel (or weakly coupled) work of different units. This can be represented using reaction networks by dynamical decomposition methods which allow to disentangle the dynamics of the network into independent parts [32,42].…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, in [28], Theorem 1 is extended to other stable asymptotic behaviors such as periodic orbits and limit cycles. In addition to these results, necessary conditions for the existence of adequate processes, and their relation to other theories that connect structure and dynamics such as Petri-Nets and Deficiency theory, are explored in [14,15,29], and algorithmic studies concerning the computation of the organizations of a reaction network are presented in [30][31][32][33][34].…”

Section: Goal-oriented Systems Are Organizationsmentioning

confidence: 99%

Goal Directedness, Chemical Organizations, and Cybernetic Mechanisms

Busseniers

Veloz

Heylighen

2021

Entropy

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In this article, we attempt at developing a scenario for the self-organization of goal-directed systems out of networks of (chemical) reactions. Related scenarios have been proposed to explain the origin of life starting from autocatalytic sets, but these sets tend to be too unstable and dependent on their environment to maintain. We apply instead a framework called Chemical Organization Theory (COT), which shows mathematically under which conditions reaction networks are able to form self-maintaining, autopoietic organizations. We introduce the concepts of perturbation, action, and goal based on an operationalization of the notion of change developed within COT. Next, we incorporate the latter with notions native to the theory of cybernetics aimed to explain goal directedness: reference levels and negative feedback among others. To test and refine these theoretical results, we present some examples that illustrate our approach. We finally discuss how this could result in a realistic, step-by-step scenario for the evolution of goal directedness, thus providing a theoretical solution to the age-old question of the origins of purpose.

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