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Autori principali: Sorichetti, Valerio, Májek, Juraj, Palaia, Ivan, Pérez-Verdugo, Fernanda, Vanhille-Campos, Christian, Hannezo, Edouard, Šarić, Anđela
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.13827
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author Sorichetti, Valerio
Májek, Juraj
Palaia, Ivan
Pérez-Verdugo, Fernanda
Vanhille-Campos, Christian
Hannezo, Edouard
Šarić, Anđela
author_facet Sorichetti, Valerio
Májek, Juraj
Palaia, Ivan
Pérez-Verdugo, Fernanda
Vanhille-Campos, Christian
Hannezo, Edouard
Šarić, Anđela
contents Quantitative modeling has become an essential tool in modern biophysics, driven by advances in both experimental techniques and theoretical frameworks. Powerful high-resolution techniques now provide detailed datasets spanning molecular to tissue scales, allowing to visualize cellular structures with unprecedented detail. In parallel, developments in soft and active matter physics have established a robust theoretical basis for describing biological systems. In this context, two main modeling paradigms have emerged: particle-based models, which explicitly represent discrete components and their interactions, and continuum models, which describe systems through spatially varying fields. We compare these approaches across biological scales, highlighting their respective strengths, limitations, and domains of applicability. To keep our discussion biologically relevant, we focus on five systems of fundamental importance: the cytoskeleton, membranes, chromatin, biomolecular condensates and tissues. With this Review, we thus aim to provide a framework for both theorists and experimentalists to select appropriate modeling strategies, and highlight future directions in biophysical modeling.
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publishDate 2026
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spellingShingle Beads, springs and fields: particle-based vs continuum models in cell biophysics
Sorichetti, Valerio
Májek, Juraj
Palaia, Ivan
Pérez-Verdugo, Fernanda
Vanhille-Campos, Christian
Hannezo, Edouard
Šarić, Anđela
Soft Condensed Matter
Biological Physics
Computational Physics
Quantitative modeling has become an essential tool in modern biophysics, driven by advances in both experimental techniques and theoretical frameworks. Powerful high-resolution techniques now provide detailed datasets spanning molecular to tissue scales, allowing to visualize cellular structures with unprecedented detail. In parallel, developments in soft and active matter physics have established a robust theoretical basis for describing biological systems. In this context, two main modeling paradigms have emerged: particle-based models, which explicitly represent discrete components and their interactions, and continuum models, which describe systems through spatially varying fields. We compare these approaches across biological scales, highlighting their respective strengths, limitations, and domains of applicability. To keep our discussion biologically relevant, we focus on five systems of fundamental importance: the cytoskeleton, membranes, chromatin, biomolecular condensates and tissues. With this Review, we thus aim to provide a framework for both theorists and experimentalists to select appropriate modeling strategies, and highlight future directions in biophysical modeling.
title Beads, springs and fields: particle-based vs continuum models in cell biophysics
topic Soft Condensed Matter
Biological Physics
Computational Physics
url https://arxiv.org/abs/2604.13827