Depletion layer formation in suspensions of elastic capsules in Newtonian and viscoelastic fluids

Pranay, Pratik; Henríquez-Rivera, Rafael G.; Graham, Michael D.

doi:10.1063/1.4726058

Cited by 53 publications

(63 citation statements)

References 69 publications

(104 reference statements)

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“…2 shows φ p normalized by its mean volume fractionφ p . In the unconfined limit C → ∞, l d → η p /φ pc , confirming the φ −1 dependence found earlier in scaling analyses [23,25,28]. More generally, Eq.…”

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Margination Regimes and Drainage Transition in Confined Multicomponent Suspensions

2015

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A mechanistic theory is developed to describe segregation in confined multicomponent suspensions such as blood. It incorporates the two key phenomena arising in these systems at low Reynolds number: hydrodynamic pair collisions and wall-induced migration. In simple shear flow, several regimes of segregation arise, depending on the value of a "margination parameter" M. Most importantly, there is a critical value of M below which a sharp "drainage transition" occurs: one component is completely depleted from the bulk flow to the vicinity of the walls. Direct simulations also exhibit this transition as the size or flexibility ratio of the components changes.Introduction. Flow-induced segregation is ubiquitous in multicomponent suspensions and granular materials, including systems as disparate as hard macroscopic particles in air [1], polydisperse droplet suspensions [2], foams [3], and blood. During blood flow, the focus of the present work, both the leukocytes and platelets segregate near the vessel walls, a phenomenon known as margination, while the red blood cells (RBCs) tend to be depleted in the near-wall region, forming a so-called cell-free or depletion layer [4]. Engineering the margination process has been proposed for microfluidic cell separations in blood (e.g. [5]) as well as for enhanced drug delivery to the vasculature [6].Direct simulations of flowing multicomponent suspensions -models of blood -can capture margination phenomena [7][8][9][10][11][12][13][14][15][16], but developing a fundamental understanding of underlying mechanisms and parameterdependence from simulations is difficult. It is thus important to have a simple yet mechanistic mathematical model, ideally one with closed form solutions that reveal parameter-dependence, that can distill out the essential phenomena that drive segregation and capture the key effects and transitions. We present such a model here.Theory. We consider a dilute suspension containing N s types of deformable particles with total volume fraction φ undergoing flow in a slit bounded by no-slip walls at y = 0 and y = 2H and unbounded in x and z. Quantities referring to a specific component α in the mixture will have subscript α: for example n α is the number density of component α. We consider here only simple shear (plane Couette) flow and, consistent with the diluteness assumption, take the shear rateγ to be independent of the local number densities and thus independent of position. In a dilute suspension of particles, where φ ≪ 1, the particle-particle interactions can be treated as a sequence of uncorrelated pair collisions [17][18][19]. For the moment, we neglect molecular diffusion of the particles. This issue is further addressed below. Since the particles are deformable, they migrate away from the wall during flow with velocity v αm (y) [20,21]. The evolution of the particle number density distributions can be idealized by a kinetic master equation that captures the migration

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“…This scales as a 4 α , where a α is the particle radius of species α, and asγ 2 at lowγ with this dependency becoming weaker asγ increases [16,25].…”

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Margination Regimes and Drainage Transition in Confined Multicomponent Suspensions

2015

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“…This is a significant result from the point of view of a general understanding of capsule dynamics. In most other flow problems such as capsule deformation in shear flow or the rheological properties of a capsule suspension, the shear modulus is usually the most relevant modulus and the area dilation modulus is usually of secondary importance [29,30]. These two examples illustrate the important fact that different moduli may control the response of the capsule in different types of deformation and flow.…”

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Adhesion and detachment of a capsule in axisymmetric flow

Keh

Leal

2016

Phys. Rev. Fluids

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The adhesion and detachment of a capsule on a solid boundary surface is studied via a combination of scaling theory and numerical simulation and the behavior is compared and contrasted with a vesicle. It is shown that the dominant physical property for both capsules and vesicles is the area dilation modulus K s of the membrane. The nonzero shear modulus G s for capsules increases the resistance to deformation and thus decreases slightly the equilibrium contact radius for an adhered capsule compared to an adhered vesicle. The detachment process in this study is due to an external axisymmetric flow. Unlike a rigid body that must be pulled away without change of shape, capsules (and vesicles) almost always detach dominantly by peeling in which the contact radius decreases but the minimum separation distance does not change until the final moments of detachment. Compared to a vesicle with the same K s , a capsule maintains a more compact shape and is harder to elongate under a given external flow. Hence, the detachment process is slower for capsules compared to vesicles with the same K s .

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“…Although this model has been effective in predicting moderate RBC depletion near the wall, it is not capable of predicting near-wall RBCs free layer. Therefore, an improvement would be to introduce the wall effect which is influenced by the particle deformability and the distance from the wall, as described by Pranay et al (2012) [43] Grandchamp et al (2013) [44], and Kumar et al (2012) [45]. Another limitation is the use of 2D approximation of a spheroidal domain.…”

Section: Bulging Saccular Aneurysmmentioning

confidence: 99%

Numerical Simulation of Red Blood Cell-Induced Platelet Transport in Saccular Aneurysms

Aubry

et al. 2017

Applied Sciences

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Abstract:We present a numerical simulation of blood flow in two aneurysmal vessels. Using a multicomponent continuum approach, called mixture theory, the velocity fields and spatial distribution of the red blood cells (RBCs) and the plasma are predicted. Platelet migration is described by a convection-diffusion equation, coupled to the RBC concentration field. The model is applied to study a two-dimensional straight vessel and multiple two-dimensional aneurysm vessels with different neck sizes. The model accurately predicts the enrichment of the platelets near the wall in the straight vessel, agreeing with the experimental measurement quantitatively. The numerical results also show that the near-wall enrichment of the platelets in the parent vessel highly influences the platelet concentration within the aneurysm. The results also indicate that the platelet concentration within the aneurysm increases with Reynolds number and decreases with a smaller neck size. This might have significance on the formation of thrombus (blood clot) within the aneurysm, which in turn may have a protective effect on preventing ruptures. Based on the success with the problems studied, we believe the current model can be a useful tool for analyzing the blood flow and platelets transport within patient specific aneurysms in the future.

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Depletion layer formation in suspensions of elastic capsules in Newtonian and viscoelastic fluids

Cited by 53 publications

References 69 publications

Margination Regimes and Drainage Transition in Confined Multicomponent Suspensions

Margination Regimes and Drainage Transition in Confined Multicomponent Suspensions

Adhesion and detachment of a capsule in axisymmetric flow

Numerical Simulation of Red Blood Cell-Induced Platelet Transport in Saccular Aneurysms

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