Red Blood Cell Lingering Modulates Hematocrit Distribution in the Microcirculation

[en] The distribution of red blood cells (RBCs) in the microcirculation determines the oxygen delivery and solute transport to tissues. This process relies on the partitioning of RBCs at successive bifurcations throughout the microvascular network, and it has been known since the last century that RBCs partition disproportionately to the fractional blood flow rate, therefore leading to heterogeneity of the hematocrit (i.e., volume fraction of RBCs in blood) in microvessels. Usually, downstream of a microvascular bifurcation, the vessel branch with a higher fraction of blood flow receives an even higher fraction of RBC flux. However, both temporal and time-average deviations from this phase-separation law have been observed in recent studies. Here, we quantify how the microscopic behavior of RBC lingering (i.e., RBCs temporarily residing near the bifurcation apex with diminished velocity) influences their partitioning, through combined in vivo experiments and in silico simulations. We developed an approach to quantify the cell lingering at highly confined capillary-level bifurcations and demonstrate that it correlates with deviations of the phase-separation process from established empirical predictions by Pries et al. Furthermore, we shed light on how the bifurcation geometry and cell membrane rigidity can affect the lingering behavior of RBCs; e.g., rigid cells tend to linger less than softer ones. Taken together, RBC lingering is an important mechanism that should be considered when studying how abnormal RBC rigidity in diseases such as malaria and sickle-cell disease could hinder the microcirculatory blood flow or how the vascular networks are altered under pathological conditions (e.g., thrombosis, tumors, aneurysm).

Disciplines :

Physics

Author, co-author :

Rashidi, Yazdan

Simionato, Greta

Zhou, Qi

John, Thomas

Kihm, Alexander

Bendaoud, Mohammed

Krüger, Timm

Bernabeu, Miguel O.

Kaestner, Lars

Laschke, Matthias W.

More authors (3 more)

External co-authors :

yes

Language :

English

Title :

Red Blood Cell Lingering Modulates Hematocrit Distribution in the Microcirculation

Publication date :

April 2023

Journal title :

Biophysical Journal

ISSN :

0006-3495

eISSN :

1542-0086

Publisher :

Biophysical Society, Us md

Volume :

122

Issue :

Pages :

1526–1537

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBilu :

since 23 December 2023

Statistics

Number of views

82 (1 by Unilu)

Number of downloads

30 (0 by Unilu)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Svanes, K., Zweifach, B., Variations in small blood vessel hematocrits produced in hypothermic rats by micro-occlusion. Microvasc. Res. 1 (1968), 210–220.
Fung, Y.C., Zweifach, B.W., Microcirculation: mechanics of blood flow in capillaries. Annu. Rev. Fluid Mech. 3 (1971), 189–210.
Schmid-Schönbein, G.W., Skalak, R., et al., Chien, S., Cell distribution in capillary networks. Microvasc. Res. 19 (1980), 18–44.
Pries, A.R., Ley, K., Gaehtgens, P., Generalization of the Fahraeus principle for microvessel networks. Am. J. Physiol. 251 (1986), H1324–H1332.
Sherwood, J.M., Holmes, D., et al., Balabani, S., Spatial distributions of red blood cells significantly alter local haemodynamics. PLoS One, 9, 2014, e100473.
Roman, S., Merlo, A., et al., Lorthois, S., Going beyond 20 um-sized channels for studying red blood cell phase separation in microfluidic bifurcations. Biomicrofluidics, 10, 2016, 034103.
Shen, Z., Coupier, G., et al., Podgorski, T., Inversion of hematocrit partition at microfluidic bifurcations. Microvasc. Res. 105 (2016), 40–46.
Clavica, F., Homsy, A., et al., Obrist, D., Red blood cell phase separation in symmetric and asymmetric microchannel networks: effect of capillary dilation and inflow velocity. Sci. Rep., 6, 2016, 36763.
Kaliviotis, E., Sherwood, J.M., Balabani, S., Partitioning of red blood cell aggregates in bifurcating microscale flows. Sci. Rep., 7, 2017, 44563.
Mantegazza, A., Clavica, F., Obrist, D., In vitro investigations of red blood cell phase separation in a complex microchannel network. Biomicrofluidics, 14, 2020, 014101.
Mantegazza, A., Ungari, M., et al., Obrist, D., Local vs. global blood flow modulation in artificial microvascular networks: effects on red blood cell distribution and partitioning. Front. Physiol., 11, 2020, 566273.
Pskowski, A., Bagchi, P., Zahn, J.D., Investigation of red blood cell partitioning in an in vitro microvascular bifurcation. Artif. Organs 45 (2021), 1083–1096.
Hyakutake, T., Abe, H., et al., Tsutsumi, Y., In vitro study on the partitioning of red blood cells using a microchannel network. Microvasc. Res., 140, 2022, 104281.
Barber, J.O., Alberding, J.P., et al., Secomb, T.W., Simulated two-dimensional red blood cell motion, deformation, and partitioning in microvessel bifurcations. Ann. Biomed. Eng. 36 (2008), 1690–1698.
Xiong, W., Zhang, J., Two-dimensional lattice Boltzmann study of red blood cell motion through microvascular bifurcation: cell deformability and suspending viscosity effects. Biomech. Model. Mechanobiol. 11 (2012), 575–583.
Yin, X., Thomas, T., Zhang, J., Multiple red blood cell flows through microvascular bifurcations: cell free layer, cell trajectory, and hematocrit separation. Microvasc. Res. 89 (2013), 47–56.
Hyakutake, T., Nagai, S., Numerical simulation of red blood cell distributions in three-dimensional microvascular bifurcations. Microvasc. Res. 97 (2015), 115–123.
Ye, T., Peng, L., Li, G., Red blood cell distribution in a microvascular network with successive bifurcations. Biomech. Model. Mechanobiol. 18 (2019), 1821–1835.
Liu, Z.L., Clausen, J.R., et al., Aidun, C.K., Heterogeneous partition of cellular blood-borne nanoparticles through microvascular bifurcations. Phys. Rev. E, 102, 2020, 013310.
Triebold, C., Barber, J., Dependence of red blood cell dynamics in microvessel bifurcations on the endothelial surface layer's resistance to flow and compression. Biomech. Model. Mechanobiol. 21 (2022), 771–796.
Zhou, Q., Perovic, T., et al., Bernabeu, M.O., Association between erythrocyte dynamics and vessel remodelling in developmental vascular networks. J. R. Soc. Interface, 18, 2021, 20210113.
Pries, A.R., Ley, K., et al., Gaehtgens, P., Red cell distribution at microvascular bifurcations. Microvasc. Res. 38 (1989), 81–101.
Pries, A.R., Secomb, T.W., et al., Gross, J.F., Blood flow in microvascular networks. Experiments and simulation. Circ. Res. 67 (1990), 826–834.
Pries, A.R., Reglin, B., Secomb, T.W., Structural response of microcirculatory networks to changes in demand: information transfer by shear stress. Am. J. Physiol. Heart Circ. Physiol. 284 (2003), H2204–H2212.
Balogh, P., Bagchi, P., Direct numerical simulation of cellular-scale blood flow in 3D microvascular networks. Biophys. J. 113 (2017), 2815–2826.
Zhou, Q., Fidalgo, J., et al., Krüger, T., Emergent cell-free layer asymmetry and biased haematocrit partition in a biomimetic vascular network of successive bifurcations. Soft Matter 17 (2021), 3619–3633.
Chang, S.-S., Tu, S., et al., Roper, M., Optimal occlusion uniformly partitions red blood cells fluxes within a microvascular network. PLoS Comput. Biol., 13, 2017, e1005892.
Balogh, P., Bagchi, P., Analysis of red blood cell partitioning at bifurcations in simulated microvascular networks. Phys. Fluids, 30, 2018, 051902.
Kihm, A., Quint, S., et al., Wagner, C., Lingering dynamics in microvascular blood flow. Biophys. J. 120 (2021), 432–439.
Ebrahimi, S., Bagchi, P., A computational study of red blood cell deformability effect on hemodynamic alteration in capillary vessel networks. Sci. Rep., 12, 2022, 4304.
Stuart, J., Nash, G.B., Red cell deformability and haematological disorders. Blood Rev. 4 (1990), 141–147.
Symeonidis, A., Athanassiou, G., et al., Zoumbos, N., Impairment of erythrocyte viscoelasticity is correlated with levels of glycosylated haemoglobin in diabetic patients. Clin. Lab. Haematol. 23 (2001), 103–109.
Dondorp, A.M., Nyanoti, M., et al., Marsh, K., The role of reduced red cell deformability in the pathogenesis of severe falciparum malaria and its restoration by blood transfusion. Trans. R. Soc. Trop. Med. Hyg. 96 (2002), 282–286.
Shevkoplyas, S.S., Yoshida, T., et al., Bitensky, M.W., Direct measurement of the impact of impaired erythrocyte deformability on microvascular network perfusion in a microfluidic device. Lab Chip 6 (2006), 914–920.
Mohandas, N., Gallagher, P.G., Red cell membrane: past, present, and future. Blood 112 (2008), 3939–3948.
Mannino, R., Myers, D.R., et al., Lam, W., Increased erythrocyte rigidity is sufficient to cause endothelial dysfunction in sickle cell disease. Blood, 120, 2012, 818.
Rabe, A., Kihm, A., et al., Kaestner, L., The erythrocyte sedimentation rate and its relation to cell shape and rigidity of red blood cells from chorea-acanthocytosis patients in an off-label treatment with dasatinib. Biomolecules, 11, 2021, 727.
Reichel, F., Kräter, M., et al., Guck, J., Changes in blood cell deformability in chorea-acanthocytosis and effects of treatment with dasatinib or lithium. Front. Physiol. 13 (2022), 1–11.
Laschke, M.W., Vollmar, B., Menger, M.D., The dorsal skinfold chamber: window into the dynamic interaction of biomaterials with their surrounding host tissue. Eur. Cell. Mater. 22 (2011), 147–164 discussion 164-167.
Xu, X., Xu, S., Jin, L., Song, E., Characteristic analysis of Otsu threshold and its applications. Pattern Recogn. Lett. 32 (2011), 956–961.
Sbalzarini, I.F., Koumoutsakos, P., Feature point tracking and trajectory analysis for video imaging in cell biology. J. Struct. Biol. 151 (2005), 182–195.
Bernabeu, M.O., Jones, M.L., et al., Franco, C.A., PolNet: a tool to quantify network-level cell polarity and blood flow in vascular remodeling. Biophys. J. 114 (2018), 2052–2058.
Sugii, Y., Okuda, R., et al., Madarame, H., Velocity measurement of both red blood cells and plasma of in vitro blood flow using high-speed micro PIV technique. Meas. Sci. Technol. 16 (2005), 1126–1130.
Secomb, T.W., Blood flow in the microcirculation. Annu. Rev. Fluid Mech. 49 (2017), 443–461.
Jiang, X.Z., Goligorsky, M.S., Luo, K.H., Cross talk between endothelial and red blood cell glycocalyces via near-field flow. Biophys. J. 120 (2021), 3180–3191.
Chien, S., Tvetenstrand, C.D., et al., Schmid-Schönbein, G.W., Model studies on distributions of blood cells at microvascular bifurcations. Am. J. Physiol. 248 (1985), H568–H576.
Barber, J.O., Restrepo, J.M., Secomb, T.W., Simulated red blood cell motion in microvessel bifurcations: effects of cell–cell interactions on cell partitioning. Cardiovasc. Eng. Technol. 2 (2011), 349–360.
Wang, Z., Sui, Y., et al., Wang, W., Path selection of a spherical capsule in a microfluidic branched channel: towards the design of an enrichment device. J. Fluid Mech. 849 (2018), 136–162.