Revaz D. Chachanidze, Othmane Aouane, Jens Harting, Christian Wagner, Marc Leonetti
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Margination of artificially stiffened red blood cells
Margination, a fundamental process in which leukocytes migrate from the
flowing blood to the vessel wall, is well-documented in physiology. However, it
is still an open question on how the differences in cell size and stiffness of
white and red cells contribute to this phenomenon. To investigate the specific
influence of cell stiffness, we conduct experimental and numerical studies on
the segregation of a binary mixture of artificially stiffened red blood cells
within a suspension of healthy cells. The resulting distribution of stiffened
cells within the channel is found to depend on the channel geometry, as
demonstrated with slit, rectangular, and cylindrical cross-sections. Notably,
an unexpected central peak in the distribution of stiffened RBCs, accompanied
by fourfold peaks at the corners, emerges in agreement with simulations. Our
results unveil a non-monotonic variation in segregation/margination concerning
hematocrit and flow rate, challenging the prevailing belief that higher flow
rates lead to enhanced margination.
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