Predicting the vascular adhesion of deformable drug carriers in narrow capillaries traversed by blood cell

Abstract

In vascular targeted therapies, blood-borne carriers should realize sustained drug release from the luminal side towards the diseased tissue. In this context, such carriers are required to firmly adhere to the vessel walls for a sufficient period of time while resisting force perturbations induced by the blood flow and circulating cells. Here, a hybrid computational model, combining a Lattice Boltzmann (LBM) and Immersed Boundary Methods (IBM), is proposed for predicting the strength of adhesion of particles in narrow capillaries (7.5 μ m) traversed by blood cells. While flowing down the capillary, globular and biconcave deformable cells ( 7 μ m ) encounter 2 μ m discoidal particles, adhering to the vessel walls. Particles present aspect ratios ranging from 0.25 to 1.0 and a mechanical stiffness varying from rigid (Ca=0) to soft (Ca=10-3). Cell-particle interactions are quantitatively predicted over time via three independent parameters: the cell membrane stretching δ p; the cell-to-particle distance r, and the number of engaged ligand-receptor bonds NL.