On testing structural identifiability by a simple scaling method: Relying on scaling symmetries can be misleading

Villaverde, Alejandro F.; Massonis, Gemma

doi:10.1371/journal.pcbi.1009032

Cited by 2 publications

(3 citation statements)

References 15 publications

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“…While they are arguably the most commonly found type of symmetry, dynamic models of biological systems may admit symmetry transformations of other types, instead or in addition to scaling. Since the absence of scaling symmetries does not exclude the existence of other types, caution must be exercised when interpreting the results of analyses based exclusively on scalings [25].…”

Section: Discussionmentioning

confidence: 99%

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Symmetries in Dynamic Models of Biological Systems: Mathematical Foundations and Implications

Villaverde

2022

Symmetry

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Symmetries are ubiquitous in nature. Almost all organisms have some kind of “symmetry”, meaning that their shape does not change under some geometric transformation. This geometrical concept of symmetry is intuitive and easy to recognize. On the other hand, the behavior of many biological systems over time can be described with ordinary differential equations. These dynamic models may also possess “symmetries”, meaning that the time courses of some variables remain invariant under certain transformations. Unlike the previously mentioned symmetries, the ones present in dynamic models are not geometric, but infinitesimal transformations. These mathematical symmetries can be related to certain features of the system’s dynamic behavior, such as robustness or adaptation capabilities. However, they can also arise from questionable modeling choices, which may lead to non-identifiability and non-observability. This paper provides an overview of the types of symmetries that appear in dynamic models, the mathematical tools available for their analyses, the ways in which they are related to system properties, and the implications for biological modeling.

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Section: Discussionmentioning

confidence: 99%

“…It detects scaling symmetries, which are arguably the most frequently found in biological models. However, it must be taken into account that, if a model contains other types of symmetries, the results of SIM do not inform about structural identifiability [25].…”

Section: Symmetries and Siomentioning

confidence: 99%

Symmetries in Dynamic Models of Biological Systems: Mathematical Foundations and Implications

Villaverde

2022

Symmetry

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“…More specifically, model reduction based on nondimensionalization amounts to a rescaling of model variables. Scaling symmetries are one of the types of symmetries encountered in dynamical models; 53 a further explanation of the relation between scaling symmetries and nondimensionalization can be found in Reference 54.…”

Section: Methodsmentioning

confidence: 99%

AutoRepar: A method to obtain identifiable and observable reparameterizations of dynamic models with mechanistic insights

Massonis¹,

Banga²,

Villaverde

2021

Intl J Robust & Nonlinear

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Mechanistic dynamic models of biological systems allow for a quantitative and systematic interpretation of data and the generation of testable hypotheses. However, these models are often over-parameterized, leading to nonidentifiability and nonobservability, that is, the impossibility of inferring their parameters and state variables. The lack of structural identifiability and observability (SIO) compromises a model's ability to make predictions and provide insight. Here we present a methodology, AutoRepar, that corrects SIO deficiencies of nonlinear ODE models automatically, yielding reparameterized models that are structurally identifiable and observable. The reparameterization preserves the mechanistic meaning of selected variables, and has the exact same dynamics and input-output mapping as the original model. We implement AutoRepar as an extension of the STRIKE-GOLDD software toolbox for SIO analysis, applying it to several models from the literature to demonstrate its ability to repair their structural deficiencies. AutoRepar increases the applicability of mechanistic models, enabling them to provide reliable information about their parameters and dynamics.

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On testing structural identifiability by a simple scaling method: Relying on scaling symmetries can be misleading

Cited by 2 publications

References 15 publications

Symmetries in Dynamic Models of Biological Systems: Mathematical Foundations and Implications

Symmetries in Dynamic Models of Biological Systems: Mathematical Foundations and Implications

AutoRepar: A method to obtain identifiable and observable reparameterizations of dynamic models with mechanistic insights

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