Orbital drift of capsules and red blood cells in shear flow

Cordasco, Daniel; Bagchi, Prosenjit

doi:10.1063/1.4820472

Cited by 60 publications

(79 citation statements)

References 55 publications

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“…However, during each tumbling period the membrane elements oscillate around a given position and this local oscillatory strain seems to destabilize RBCs from tumbling toward rolling (27) instead of tank treading. Although not fully settled, this phenomenon is well captured by our simulations and is described as a stable motion in several recent numerical simulations of capsules (28) and RBCs (29).…”

Section: Discussionmentioning

confidence: 66%

Red cells’ dynamic morphologies govern blood shear thinning under microcirculatory flow conditions

Lanotte

Mauer

Mendez

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

218

221

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Blood viscosity decreases with shear stress, a property essential for an efficient perfusion of the vascular tree. Shear thinning is intimately related to the dynamics and mutual interactions of RBCs, the major component of blood. Because of the lack of knowledge about the behavior of RBCs under physiological conditions, the link between RBC dynamics and blood rheology remains unsettled. We performed experiments and simulations in microcirculatory flow conditions of viscosity, shear rates, and volume fractions, and our study reveals rich RBC dynamics that govern shear thinning. In contrast to the current paradigm, which assumes that RBCs align steadily around the flow direction while their membranes and cytoplasm circulate, we show that RBCs successively tumble, roll, deform into rolling stomatocytes, and, finally, adopt highly deformed polylobed shapes for increasing shear stresses, even for semidilute volume fractions of the microcirculation. Our results suggest that any pathological change in plasma composition, RBC cytosol viscosity, or membrane mechanical properties will affect the onset of these morphological transitions and should play a central role in pathological blood rheology and flow behavior.

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Section: Discussionmentioning

confidence: 66%

Red cells’ dynamic morphologies govern blood shear thinning under microcirculatory flow conditions

Lanotte

Mauer

Mendez

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

218

221

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“…In the present study, the simulations are conducted for capsules enclosed by an SK membrane with C = 1, unless otherwise stated. The bending resistance of the membrane is modelled using Helfrich's formulation (Zhong-Can & Helfrich 1989;Cordasco & Bagchi 2013) …”

Section: Problem Descriptionmentioning

confidence: 99%

Motion of a spherical capsule in branched tube flow with finite inertia

et al. 2016

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We computationally study the transient motion of an initially spherical capsule flowing through a right-angled tube bifurcation, composed of tubes having the same diameter. The capsule motion and deformation is simulated using a three-dimensional immersed-boundary lattice Boltzmann method. The capsule is modelled as a liquid droplet enclosed by a hyperelastic membrane following the Skalak's law (Skalak et al., Biophys. J., vol. 13(3), 1973, pp. 245-264). The fluids inside and outside the capsule are assumed to have identical viscosity and density. We mainly focus on path selection of the capsule at the bifurcation as a function of the parameters of the problem: the flow split ratio, the background flow Reynolds number Re, the capsule-to-tube size ratio a/R and the capillary number Ca, which compares the viscous fluid force acting on the capsule to the membrane elastic force. For fixed physical properties of the capsule and of the tube flow, the ratio Ca/Re is constant. Two size ratios are considered: a/R = 0.2 and 0.4. At low Re, the capsule favours the branch which receives most flow. Inertia significantly affects the background flow in the branched tube. As a consequence, at equal flow split, a capsule tends to flow straight into the main branch as Re is increased. Under significant inertial effects, the capsule can flow into the downstream main tube even when it receives much less flow than the side branch. Increasing Ca promotes cross-stream migration of the capsule towards the side branch. The results are summarized in a phase diagram, showing the critical flow split ratio for which the capsule flows into the side branch as a function of size ratio, Re and Ca/Re. We also provide a simplified model of the path selection of a slightly deformed capsule and explore its limits of validity. We finally discuss the experimental feasibility of the flow system and its applicability to capsule sorting.

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“…In contrast to snaking in 2D, the snaking motion in 3D is fully three dimensional and exhibits an orbital dri (see Movie S1 †), which is similar to that for a RBC rolling motion in shear ow occurring in a range of shear rates between RBC tumbling and tank-treading. 39,40 The origin of orbital oscillations in the snaking regime might be similar to that for a rolling RBC; however, this issue requires a more detailed investigation. Note that at very low _ g* ( k B T/k r , the rotational diffusion of RBCs becomes important, and RBC dynamics is characterized by random cell orientation.…”

mentioning

confidence: 99%

Deformation and dynamics of red blood cells in flow through cylindrical microchannels

2014

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The motion of red blood cells (RBCs) in microcirculation plays an important role in blood flow resistance and in the cell partitioning within a microvascular network. Different shapes and dynamics of RBCs in microvessels have been previously observed experimentally including the parachute and slipper shapes.We employ mesoscale hydrodynamic simulations to predict the phase diagram of shapes and dynamics of RBCs in cylindrical microchannels, which serve as idealized microvessels, for a wide range of channel confinements and flow rates. A rich dynamical behavior is found, with snaking and tumbling discocytes, slippers performing a swinging motion, and stationary parachutes. We discuss the effects of different RBC states on the flow resistance, and the influence of RBC properties, characterized by the Föppl-von Kármán number, on the shape diagram. The simulations are performed using the same viscosity for both external and internal fluids surrounding a RBC; however, we discuss how the viscosity contrast would affect the shape diagram.

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Orbital drift of capsules and red blood cells in shear flow

Cited by 60 publications

References 55 publications

Red cells’ dynamic morphologies govern blood shear thinning under microcirculatory flow conditions

Red cells’ dynamic morphologies govern blood shear thinning under microcirculatory flow conditions

Motion of a spherical capsule in branched tube flow with finite inertia

Deformation and dynamics of red blood cells in flow through cylindrical microchannels

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