Frontiers in Physiology (Oct 2022)

Shear induced diffusion of platelets revisited

  • Christos Kotsalos,
  • Franck Raynaud,
  • Jonas Lätt,
  • Ritabrata Dutta,
  • Frank Dubois,
  • Karim Zouaoui Boudjeltia,
  • Bastien Chopard

DOI
https://doi.org/10.3389/fphys.2022.985905
Journal volume & issue
Vol. 13

Abstract

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The transport of platelets in blood is commonly assumed to obey an advection-diffusion equation with a diffusion constant given by the so-called Zydney-Colton theory. Here we reconsider this hypothesis based on experimental observations and numerical simulations including a fully resolved suspension of red blood cells and platelets subject to a shear. We observe that the transport of platelets perpendicular to the flow can be characterized by a non-trivial distribution of velocities with and exponential decreasing bulk, followed by a power law tail. We conclude that such distribution of velocities leads to diffusion of platelets about two orders of magnitude higher than predicted by Zydney-Colton theory. We tested this distribution with a minimal stochastic model of platelets deposition to cover space and time scales similar to our experimental results, and confirm that the exponential-powerlaw distribution of velocities results in a coefficient of diffusion significantly larger than predicted by the Zydney-Colton theory.

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