Discovering dynamic laws from observations: the case of self-propelled, interacting colloids

Ruiz-García, Miguel; Gutierrez, C. Miguel Barriuso; Alexander, Lachlan C.; Aarts, Dirk G. A. L.; Ghiringhelli, Luca M.; Valeriani, Chantal

doi:10.48550/arxiv.2203.14846

Cited by 3 publications

(3 citation statements)

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“…In that case, all position dependence simply becomes a function of the radial distance r ij of each pair of cells. A further promising approach is the inclusion of small convolutional neural networks as the basis functions of the expansion (equation ( 16)), which has been applied to the case of interacting active colloids [308]. An advantage of this approach is that it may reduce the risk of overfitting and provide a flexible basis for complex interaction functions.…”

Section: Inference Approaches For Interacting Active Systemsmentioning

confidence: 99%

Learning dynamical models of single and collective cell migration: a review

Brückner,

Broedersz

2024

Rep. Prog. Phys.

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Single and collective cell migration are fundamental processes critical for physiological phenomena ranging from embryonic development and immune response to wound healing and cancer metastasis. To understand cell migration from a physical perspective, a broad variety of models for the underlying physical mechanisms that govern cell motility have been developed. A key challenge in the development of such models is how to connect them to experimental observations, which often exhibit complex stochastic behaviours. In this review, we discuss recent advances in data-driven theoretical approaches that directly connect with experimental data to infer dynamical models of stochastic cell migration. Leveraging advances in nanofabrication, image analysis, and tracking technology, experimental studies now provide unprecedented large datasets on cellular dynamics. In parallel, theoretical efforts have been directed towards integrating such datasets into physical models from the single cell to the tissue scale with the aim of conceptualizing the emergent behaviour of cells. We first review how this inference problem has been addressed in both freely migrating and confined cells. Next, we discuss why these dynamics typically take the form of underdamped stochastic equations of motion, and how such equations can be inferred from data. We then review applications of data-driven inference and machine learning approaches to heterogeneity in cell behaviour, subcellular degrees of freedom, and to the collective dynamics of multicellular systems. Across these applications, we emphasize how data-driven methods can be integrated with physical active matter models of migrating cells, and help reveal how underlying molecular mechanisms control cell behaviour. Together, these data-driven approaches are a promising avenue for building physical models of cell migration directly from experimental data, and for providing conceptual links between different length-scales of description.

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Section: Inference Approaches For Interacting Active Systemsmentioning

confidence: 99%

Learning dynamical models of single and collective cell migration: a review

Brückner,

Broedersz

2024

Rep. Prog. Phys.

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“…Our approach aims to optimize the parameters by considering several properties of pure H 2 O 2 and water mixtures simultaneously, targeting 22 different values. Notably, ANNs have recently been employed for optimization purposes of pairwise additive molecular models, 29−32 extracting forces and dynamic laws from active-matter trajectories 33,34 and even serving as complex potential functions for molecular simulations. 35−41 We present several liquid and vapor properties of the obtained pairwise additive model as a function of the weight percentage of the water− peroxide mixture and temperature.…”

Section: ■ Introductionmentioning

confidence: 99%

A Neural-Network-Optimized Hydrogen Peroxide Pairwise Additive Model for Classical Simulations

Peralta,

Odriozola

2023

J. Chem. Theory Comput.

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We have developed an all-atom pairwise additive model for hydrogen peroxide using an optimization procedure based on artificial neural networks (ANNs). The model is based on experimental molecular geometry and includes a dihedral potential that hinders the cis-type configuration and allows for crossing the trans one, defined between the planes that have the two oxygen atoms and each hydrogen. The model's parametrization is achieved by training simple ANNs to minimize a target function that measures the differences between various thermodynamic and transport properties and the corresponding experimental values. Finally, we evaluated a range of properties for the optimized model and its mixtures with SPC/E water, including bulk-liquid properties (density, thermal expansion coefficient, adiabatic compressibility, etc.) and properties of systems at equilibrium (vapor and liquid density, vapor pressure and composition, surface tension, etc.). Overall, we obtained good agreement with experimental data.Article pubs.acs.org/JCTC

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“…These findings firmly establish a correlation between local structure and the propensity of passive particles to move in a crowded environment. While ML has also been applied with considerable success in purely active systems [25][26][27][28][29][30][31][32][33], in practice and particularly in biological settings the system of interest will generally contain actors whose activity parameters are different, and distributed. In tumor tissue, for instance, there may be a distribution of epithelial (more stationary, passive) phenotypes and mesenchymal (more motile, active) ones, with the presence of mesenchymal cells being generally associated with greater metastatic potential [5,34].…”

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confidence: 99%

Dead or alive: Distinguishing active from passive particles using supervised learning ^(a)

Janzen

Smeets

Debets

et al. 2023

EPL

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A longstanding open question in the field of dense disordered matter is how precisely structure and dynamics are related to each other. With the advent of machine learning, it has become possible to agnostically predict the dynamic propensity of a particle in a dense liquid based on its local structural environment. Thus far, however, these machine-learning studies have focused almost exclusively on simple liquids composed of passive particles. Here we consider a mixture of both passive and active (i.e.\ self-propelled) Brownian particles, with the aim to identify the active particles from minimal local structural information. We compare a state-of-the-art machine learning approach for passive systems with a new method we develop based on Voronoi tessellation. Both methods accurately identify the active particles based on their structural properties at high activity and low concentrations of active particles. Our Voronoi method is, however, substantially faster to train and deploy because it requires fewer, and easy to compute, input features. Notably, both become ineffective when the activity is low, suggesting a fundamentally different structural signature for dynamic propensity and non-equilibrium activity. Ultimately, these efforts might also find relevance in the context of biological active glasses such as confluent cell layers, where subtle changes in the microstructure can hint at pathological changes in cell dynamics.

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Discovering dynamic laws from observations: the case of self-propelled, interacting colloids

Cited by 3 publications

References 71 publications

Learning dynamical models of single and collective cell migration: a review

Learning dynamical models of single and collective cell migration: a review

A Neural-Network-Optimized Hydrogen Peroxide Pairwise Additive Model for Classical Simulations

Dead or alive: Distinguishing active from passive particles using supervised learning ^(a)

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Discovering dynamic laws from observations: the case of self-propelled, interacting colloids

Cited by 3 publications

References 71 publications

Learning dynamical models of single and collective cell migration: a review

Learning dynamical models of single and collective cell migration: a review

A Neural-Network-Optimized Hydrogen Peroxide Pairwise Additive Model for Classical Simulations

Dead or alive: Distinguishing active from passive particles using supervised learning (a)

Contact Info

Product

Resources

About

Dead or alive: Distinguishing active from passive particles using supervised learning ^(a)