Issue 6, 2022

Flow driven vesicle unbinding under mechanosensitive adhesion

Abstract

Ligand receptor based adhesion is the primary mode of interaction of cellular blood constituents with the endothelium. These adhered entities also experience shear flow imposed by the blood which may lead to their detachment due to the viscous lift forces. Here, we have studied the role of the ligand–receptor bond kinetics in the detachment of an adhered vesicle (a simplified cell model) under shear flow. Using boundary integral formulation we performed numerical simulation of a two dimensional vesicle under shear flow for different values of applied shear rates and time scale of bond kinetics. We observe that the vesicle demonstrates three steady state configurations – adhered, pinned and detached for fast enough ligand-receptor kinetics (akin to Lennard-Jones adhesion). However, for slow bond kinetics the pinned state is not observed. We present scaling laws for the critical shear rates corresponding to the transitions among these three states. These results can help with identifying the processes of cell adhesion/detachment in the blood stream, prevalent features during the immune response and cancer metastasis.

Graphical abstract: Flow driven vesicle unbinding under mechanosensitive adhesion

Article information

Article type
Paper
Submitted
06 Sep 2021
Accepted
09 Jan 2022
First published
11 Jan 2022

Soft Matter, 2022,18, 1209-1218

Flow driven vesicle unbinding under mechanosensitive adhesion

M. S. Rizvi, A. Farutin and C. Misbah, Soft Matter, 2022, 18, 1209 DOI: 10.1039/D1SM01284C

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