Deciphering the interplay between biology and physics: finite element method-implemented vertex organoid model raises the challenge
LAUSSU, J.; Michel, D.; Magne, L.; Segonds, S.; Marguet, S.; Hamel, D.; Quaranta-Nicaise, M.; Barreau, F.; Mas, E.; VELAY, V.; BUGARIN, F.; FERRAND, A.
Show abstract
Understanding the intertwining of biology and mechanics in tissue architecture is a challenging issue, especially when it comes to the 3D tissue organization. Addressing this challenge requires both a biological model allowing multiscale observations from the cell to the tissue, and theoretical and computational approaches allowing the generation of a synthetic model, relevant to the biological model, and allowing access to the mechanical constraints experienced by the tissue. Here, using human colon epithelium monolayer organoid as biological model, and combining vertex and FEM approaches, we generated a comprehensive elastic finite element model of the human colon organoid and demonstrated its flexibility. This FEM model provides a basis for relating cell shape, tissue deformation, and strain at the cellular level due to imposed stresses. In conclusion, we demonstrated that the combination of vertex and FEM approaches allows for better modeling of the alteration of organoid morphology over time and better assessment of the mechanical cues involved in establishing the architecture of the human colon epithelium.
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