Effect of Cytoplasmic Viscosity on Red Blood Cell Migration in Small Arteriole-level Confinements

Saadat, Amir; Guido, Christopher; Shaqfeh, Eric S. G.

doi:10.1101/572933

Cited by 7 publications

(9 citation statements)

References 49 publications

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“…Although hardened RBCs are not expected to be fully rigid at the concentration of GA used, membrane stiffening affects both individual RBC motion and collision dynamics in RBC suspensions; these effects might combine with the altered local shear gradients in the measured flows to give rise to the observed concentration profiles. 25,34 Wall induced lift forces are expected to be "screened" in the case of dense RBC suspensions 25 which might explain the absence of any observed changes in hematocrit distribution for dense RBC suspensions with a change in viscosity contrast between cells and the suspending medium (hence RBC deformability) reported in the recent numerical studies by de Haan et al 48 and Saadat et al 49 However, the increased tumbling motion of the hardened cells is thought to enhance the collision rate between RBCs and the wall producing larger displacements and…”

Section: Discussionmentioning

confidence: 97%

The effect of deformability on the microscale flow behavior of red blood cell suspensions

et al. 2019

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Red blood cell (RBC) deformability is important for tissue perfusion and a key determinant of blood rheology. Diseases such as diabetes, sickle cell anemia, and malaria, as well as prolonged storage, may affect the mechanical properties of RBCs altering their hemodynamic behavior and leading to microvascular complications. However, the exact role of RBC deformability on microscale blood flow is not fully understood. In the present study, we extend our previous work on healthy RBC flows in bifurcating microchannels [Sherwood et al., "Viscosity and velocity distributions of aggregating and non-aggregating blood in a bifurcating microchannel," Biomech. Model. Mechanobiol. 13, 259-273 (2014); Sherwood et al., "Spatial distributions of red blood cells significantly alter local hemodynamics," PLoS One 9, e100473 (2014); and Kaliviotis et al., "Local viscosity distribution in bifurcating microfluidic blood flows," Phys. Fluids 30, 030706 (2018)] to quantify the effects of impaired RBC deformability on the velocity and hematocrit distributions in microscale blood flows. Suspensions of healthy and glutaraldehyde hardened RBCs perfused through straight microchannels at various hematocrits and flow rates were imaged, and velocity and hematocrit distributions were determined simultaneously using micro-Particle Image Velocimetry and light transmission methods, respectively. At low feed hematocrits, hardened RBCs were more dispersed compared to healthy ones, consistent with decreased migration of stiffer cells. At high hematocrit, the loss of deformability was found to decrease the bluntness of velocity profiles, implying a reduction in shear thinning behavior. The hematocrit bluntness also decreased with hardening of the cells, implying an inversion of the correlation between velocity and hematocrit bluntness with loss of deformability. The study illustrates the complex interplay of various mechanisms affecting confined RBC suspension flows and the impact of both deformability and feed hematocrit on the resulting microstructure.

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Section: Discussionmentioning

confidence: 97%

The effect of deformability on the microscale flow behavior of red blood cell suspensions

et al. 2019

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“…λ > 3.2) was asserted as crucial for the formation of multi-lobed structures on the RBC membrane [62]. It is worth noting that previous simulations which reproduced the polylobe shape were either for simple shear flow [61,62,70] or planar Poiseuille flow [71] without the confinement of lateral walls.…”

Section: Simulated Rbc Morphology and Dynamicsmentioning

confidence: 91%

“…Whilst Pries et al originally postulated a recovery length of 10D (vessel diameter D ∈ [10,30] µm, in vivo measurements for rat mesenteric arterioles), Katanov et al [76] revealed via 3D simulations that a length up to 25D is needed for the CFL to fully develop in cylindrical microchannels (D ∈ [15,80] µm, haematocrit Ht ∈ [15%, 45%]). Also through simulations, Shaqfeh and co-workers [77,71] demonstrated moderately larger recovery lengths (beyond 36D h ) for the CFL to saturate in rectangular channels with comparable dimension and haematocrit levels (channel hydraulic diameter D h ∈ [20,30] µm, Ht ∈ [10%, 20%]). Under the circumstances of locally reduced flow or diluted RBC concentration in individual branches, the CFL recovery process may be further prolonged due to weakened hydrodynamic lift or lack of shear-induced diffusion.…”

Section: Cfl Development Between Arteriole-level Bifurcationsmentioning

confidence: 98%

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

et al. 2021

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“…It has been shown that

significantly affects the RBC behavior in simple shear flow [ 7 , 8 , 9 , 10 ]. Only recently, several studies have confirmed that the viscosity contrast is important in microcapillary flow [ 6 , 11 , 12 , 13 , 14 ]. In [ 6 ], the authors study the dependence of the RBC shape and dynamics on the viscosity contrast in tube flow.…”

Section: Introductionmentioning

confidence: 99%

Modeling Red Blood Cell Viscosity Contrast Using Inner Soft Particle Suspension

2021

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The inner viscosity of a biological red blood cell is about five times larger than the viscosity of the blood plasma. In this work, we use dissipative particles to enable the proper viscosity contrast in a mesh-based red blood cell model. Each soft particle represents a coarse-grained virtual cluster of hemoglobin proteins contained in the cytosol of the red blood cell. The particle interactions are governed by conservative and dissipative forces. The conservative forces have purely repulsive character, whereas the dissipative forces depend on the relative velocity between the particles. We design two computational experiments that mimic the classical viscometers. With these experiments we study the effects of particle suspension parameters on the inner cell viscosity and provide parameter sets that result in the correct viscosity contrast. The results are validated with both static and dynamic biological experiment, showing an improvement in the accuracy of the original model without major increase in computational complexity.

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Effect of Cytoplasmic Viscosity on Red Blood Cell Migration in Small Arteriole-level Confinements

Cited by 7 publications

References 49 publications

The effect of deformability on the microscale flow behavior of red blood cell suspensions

The effect of deformability on the microscale flow behavior of red blood cell suspensions

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

Modeling Red Blood Cell Viscosity Contrast Using Inner Soft Particle Suspension

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