Your search keyword '"Alexandre Kabla"' showing total 2 results

1. Active viscoelastic models for cell and tissue mechanics

Author

Bahareh Tajvidi Safa, Changjin Huang, Alexandre Kabla, and Ruiguo Yang

Subjects

active model, viscoelasticity, cell modeling, cell mechanics, tissue mechanics, Science

Abstract

Living cells are out of equilibrium active materials. Cell-generated forces are transmitted across the cytoskeleton network and to the extracellular environment. These active force interactions shape cellular mechanical behaviour, trigger mechano-sensing, regulate cell adaptation to the microenvironment and can affect disease outcomes. In recent years, the mechanobiology community has witnessed the emergence of many experimental and theoretical approaches to study cells as mechanically active materials. In this review, we highlight recent advancements in incorporating active characteristics of cellular behaviour at different length scales into classic viscoelastic models by either adding an active tension-generating element or adjusting the resting length of an elastic element in the model. Summarizing the two groups of approaches, we will review the formulation and application of these models to understand cellular adaptation mechanisms in response to various types of mechanical stimuli, such as the effect of extracellular matrix properties and external loadings or deformations.

Published

2024

2. A unified rheological model for cells and cellularised materials

Author

Alessandra Bonfanti, Jonathan Fouchard, Nargess Khalilgharibi, Alexandre Kabla, Guillaume Charras, Bonfanti, A [0000-0003-2185-4913], Khalilgharibi, N [0000-0003-4598-5838], Kabla, A [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

Materials science, tissue rheology, fractional viscoelasticity, 01 natural sciences, Viscoelasticity, cell rheology, 03 medical and health sciences, Rheology, 0103 physical sciences, lcsh:Science, 010306 general physics, 030304 developmental biology, Physics and Biophysics, 0303 health sciences, Computational model, Multidisciplinary, Unified Model, Fractional calculus, Creep, Relaxation (physics), lcsh:Q, Relaxation (approximation), Material properties, Biological system, Research Article

Abstract

The mechanical response of single cells and tissues exhibits a broad distribution of time-scales that often gives rise to a distinctive power-law rheology. Such complex behaviour cannot be easily captured by traditional rheological approaches, making material characterisation and predictive modelling very challenging. Here, we present a novel model combining conventional viscoelastic elements with fractional calculus that successfully captures the macroscopic relaxation response of epithelial monolayers. The parameters extracted from the fitting of the relaxation modulus allow prediction of the response of the same material to slow stretch and creep, indicating that the model captured intrinsic material properties. Two characteristic times, derived from the model parameters, delimit different regimes in the materials response. We compared the response of tissues with the behaviour of single cells as well as intra and extra-cellular components, and linked the power-law behaviour of the epithelium to the dynamics of the cell cortex. Such a unified model for the mechanical response of biological materials provides a novel and robust mathematical approach to consistently analyse experimental data and uncover similarities and differences in reported behaviour across experimental methods and research groups. It also sets the foundations for more accurate computational models of tissue mechanics.

Published

2020