A continuum model for the elongation and orientation of Von Willebrand Factor with applications in arterial flow

TL;DR

This paper introduces a continuum model for Von Willebrand Factor (VWF) dynamics in blood flow, predicting its unfolding behavior under various flow conditions relevant to arterial thrombosis.

Contribution

The paper presents a novel viscoelastic fluid model for VWF that incorporates unfolding propensity based on shear rate, validated with experimental data and applied to complex arterial flows.

Findings

VWF unfolds at lower shear rates in elongational flow than in shear flow.

Model predicts VWF unfolds between 600-3,200 s$^{-1}$ depending on maximum length.

VWF extension varies significantly across different flow regions in arteries.

Abstract

The blood protein Von Willebrand Factor (VWF) is critical in facilitating arterial thrombosis. At pathologically high shear rates the protein unfolds and binds to the arterial wall, enabling the rapid deposition of platelets from the blood. We present a novel continuum model for VWF dynamics in flow based on a modified viscoelastic fluid model that incorporates a single constitutive relation to describe the propensity of VWF to unfold as a function of the scalar shear rate. Using experimental data of VWF unfolding in pure shear flow, we fix the parameters for VWF's unfolding propensity and the maximum VWF length, so that the protein is half unfolded at a shear rate of approximately 5,000 s$^{-1}$. We then use the theoretical model to predict VWF's behaviour in two complex flows where experimental data is challenging to obtain: pure elongational flow and stenotic arterial flow. In pure elongational flow, our model predicts that VWF is 50% unfolded at approximately 2,000 s$^{-1}$, matching the established hypothesis that VWF unfolds at lower shear rates in elongational flow than in shear flow. We demonstrate the sensitivity of this elongational flow prediction to the value of maximum VWF length used in the model, which varies significantly across experimental studies, predicting that VWF can unfold between 600 - 3,200 s$^{-1}$ depending on the selected value. Finally, we examine VWF dynamics in a range of idealised arterial stenoses, predicting the relative extension of VWF in elongational flow structures in the centre of the artery compared to high-shear regions near the arterial walls.