Published online by Cambridge University Press: 03 February 2022
Biological membranes are host to proteins and molecules which may form domain-like structures resulting in spatially varying material properties. Vesicles with such heterogeneous membranes can exhibit intricate shapes at equilibrium and rich dynamics when placed into a flow. Under the assumption of small deformations and a two-dimensional system, we develop a reduced-order model to describe the fluid-structure interaction between a viscous background shear flow and an inextensible membrane with spatially varying bending stiffness and spontaneous curvature. Material property variations of a critical magnitude, relative to the flow rate and internal/external viscosity contrast, can set off a qualitative change in the vesicle dynamics. A membrane of nearly constant bending stiffness or spontaneous curvature undergoes a small amplitude swinging motion (which includes tangential tank-treading), while for large enough material variations the dynamics pass through a regime featuring tumbling and periodic phase-lagging of the membrane material, and ultimately for very large material variation to a rigid-body tumbling behaviour. Distinct differences are found for even and odd spatial modes of domain distribution. Full numerical simulations are used to probe the theoretical predictions, which appear valid even when studying substantially deformed membranes.
Movie M1: Vesicle dynamics with bending stiffness variation in spatial mode M=2. Beyond a critical magnitude of variation the elongated axis transitions from swinging to tumbling.
Movie M4: Vesicles in a shear flow with different spatial modes of material property variation. The M=2 mode most strongly interacts with the deformation imposed by the background shear flow. The magnitude of the variation is just large enough for the case with two domains (M=2) to tumble.
Movie M5: As in Movie M3, but with increased variation in the bending stiffnesses. The swinging amplitudes of vesicles with even numbers of domains (M even) are increasing.