Surface deformation and shear flow in ligand mediated cell adhesion

Abstract

We present a single, unified, multi-scale model to study the attachment dynamics of two deforming, near spherical cells, coated with binding ligands and subject to a slow, homogeneous shear flow in a viscous fluid medium. The binding ligands on the surface of the cells experience attractive and repulsive forces in an ionic medium and exhibit finite resistance to rotation via bond tilting. The macroscale drag forces and couples describing the fluid flow inside the small separation gap between the cells, are calculated using a combination of methods in lubrication theory and previously published numerical results. For a select range of material and fluid parameters, a hysteretic transition of the sticking probability curves between the adhesion and fragmentation domain is attributed to a nonlinear relation between the total microscale binding forces and the separation gap between the cells. We show that adhesion is favored in highly ionic fluids, increased deformability of the cells, elastic binders and a higher fluid shear rate (until a critical value). Continuation of the limit points predict a bistable region, indicating an abrupt switching between the adhesion and fragmentation regimes at critical shear rates, and suggesting that adhesion of two deformable surfaces in shearing fluids may play a significant dynamical role in some cell adhesion applications.