C. Bonanno, M. Serpelloni, M. Arricca, R.M. McMeeking, A. Salvadori (2023), Actin based motility unveiled: How chemical energy is converted into motion, Journal of the Mechanics and Physics of Solids, Volume 175, June 2023, 105273, https://doi.org/10.1016/j.jmps.2023.105273

Actin-based motility is a complex process in which the actin-polymerization is the primary force-generating motor machinery. It can produce protrusive forces through actin filaments polymerization and cross-link during lamellipodia protrusion in migrating cells and it is responsible for the intracellular motion of certain pathogens in infected host cells. We propose a multi-physics model for actin-based motility, stemming from continuity equations that account for the actin chemical kinetics. Thermodynamic restrictions are identified, moving from the multiplicative decomposition of the deformation gradient into chemical and elastic parts. Constitutive theory and chemical kinetics are prescribed to finally write governing equations for the multi-physics problem. The field equations are solved numerically with the finite element method. As a proof of concept, a one-dimensional model for actin-based motility of bacteria pathogens is studied.