Emergent cell-free layer asymmetry and biased haematocrit partition in a biomimetic vascular network of successive bifurcation

Zhou, Qi and Fidalgo, Joana and Bernabeu, Miguel O. and Oliveira, Mónica S. N. and Krüger, Timm (2021) Emergent cell-free layer asymmetry and biased haematocrit partition in a biomimetic vascular network of successive bifurcation. Soft Matter, 17 (13). pp. 3619-3633. ISSN 1744-6848 (https://doi.org/10.1039/D0SM01845G)

[thumbnail of Zhou-etal-SM-2021-Emergent-cell-free-layer-asymmetry-biased-haematocrit-partition]
Preview
Text. Filename: Zhou_etal_SM_2021_Emergent_cell_free_layer_asymmetry_biased_haematocrit_partition.pdf
Final Published Version
License: Creative Commons Attribution-NonCommercial 4.0 logo

Download (7MB)| Preview

Abstract

Blood is a vital soft matter, and its normal circulation in the human body relies on the distribution of red blood cells (RBCs) at successive bifurcations. Understanding how RBCs are partitioned at bifurcations is key for the optimisation of microfluidic devices as well as for devising novel strategies for diagnosis and treatment of blood-related diseases. We report the dynamics of RBC suspensions flowing through a biomimetic vascular network incorporating three generations of microchannels and two classical types of bifurcations at the arteriole level. Our microfluidic experiments with dilute and semidilute RBC suspensions demonstrate the emergence of excessive heterogeneity of RBC concentration in downstream generations upon altering the network's outflow rates. Through parallel simulations using the immersed-boundary-lattice-Boltzmann method, we reveal that the heterogeneity is attributed to upstream perturbations in the cell-free layer (CFL) and lack of its recovery between consecutive bifurcations owing to suppressed hydrodynamic lift under reduced flow conditions. In the dilute/semidilute regime, this perturbation dominates over the effect of local fractional flow at the bifurcation and can lead to inherently unfavourable child branches that are deprived of RBCs even for equal flow split. Our work highlights the importance of CFL asymmetry cascading down a vascular network, which leads to biased phase separation that deviates from established empirical predictions.