Mechanical cell interactions on curved interfaces

We propose a simple mathematical model to describe the mechanical relaxation of cells within a curved epithelial tissue layer represented by an arbitrary curve in two-dimensional space. The model represents the mechanics of the cell body either by straight springs between points of the curve, or by curved springs whose shape follows the curve. To understand the collective behaviour of these discrete models of cells at the broader tissue scale, we devise an appropriate continuum limit in which the number of cells is constant but the number of springs tends to infinity. The continuum limit shows that (i)~the straight spring model and the curved spring model converge to the same dynamics; and (ii)~the density of cells becomes governed by a diffusion equation in arc length space with second-order accuracy, where diffusion may be linear or nonlinear depending on the choice of the spring restoring force law. Our derivation of the continuum limit justifies that to reach consistent dynamics as the number of springs increases, the spring restoring force laws must be rescaled appropriately. Despite mechanical relaxation occurring within a curved tissue layer, we find that the curvature of the tissue does not affect tangential stress nor the mechanics-induced redistribution of cells within the layer in the continuum limit. However, the cell's normal stress does depend on curvature due to surface tension induced by the tangential forces. By characterising the full stress state of a cell, these models provide a basis to represent further mechanobiological processes.