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Assessment of coupled bilayer–cytoskeleton modelling strategy for red blood cell dynamics in flow

Published online by Cambridge University Press:  22 January 2024

V. Puthumana
Affiliation:
Aix Marseille Univ, CNRS, Centrale Marseille, M2P2, Turing Centre for Living Systems, 13013 Marseille, France
P.G. Chen
Affiliation:
Aix Marseille Univ, CNRS, Centrale Marseille, M2P2, Turing Centre for Living Systems, 13013 Marseille, France
M. Leonetti*
Affiliation:
Aix Marseille Univ, CNRS, CINaM, Turing Centre for Living Systems, 13009 Marseille, France
R. Lasserre*
Affiliation:
Aix Marseille Univ, CNRS, INSERM, CIML, Turing Centre for Living Systems, 13009 Marseille, France
M. Jaeger*
Affiliation:
Aix Marseille Univ, CNRS, Centrale Marseille, M2P2, Turing Centre for Living Systems, 13013 Marseille, France
*
Email addresses for correspondence: [email protected], [email protected], [email protected]
Email addresses for correspondence: [email protected], [email protected], [email protected]
Email addresses for correspondence: [email protected], [email protected], [email protected]

Abstract

The red blood cell (RBC) membrane is composed of a lipid bilayer and a cytoskeleton interconnected by protein junction complexes, allowing for potential sliding between the lipid bilayer and the cytoskeleton. Despite this biological reality, it is most often modelled as a single-layer model, a hyperelastic capsule or a fluid vesicle. Another approach involves incorporating the membrane's composite structure using double layers, where one layer represents the lipid bilayer and the other represents the cytoskeleton. In this paper, we computationally assess the various modelling strategies by analysing RBC behaviour in extensional flow and four distinct regimes that simulate RBC dynamics in shear flow. The proposed double-layer strategies, such as the vesicle–capsule and capsule–capsule models, account for the fluidity and surface incompressibility of the lipid bilayer in different ways. Our findings demonstrate that introducing sliding between the layers offers the cytoskeleton a considerable degree of freedom to alleviate its elastic stresses, resulting in a significant increase in RBC elongation. Surprisingly, our study reveals that the membrane modelling strategy for RBCs holds greater importance than the choice of the cytoskeleton's reference shape. These results highlight the inadequacy of considering mechanical properties alone and emphasise the need for careful integration of these properties. Furthermore, our findings fortuitously uncover a novel indicator for determining the appropriate stress-free shape of the cytoskeleton.

Type
JFM Papers
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

The red blood cell (RBC) is a unique cell that, during maturation, frees all typical internal organisation (Mohandas & Gallagher Reference Mohandas and Gallagher2008; Kim, Kim & Park Reference Kim, Kim and Park2012). Its impressive mechanical performance is due to its membrane, which is made up of a lipid bilayer supported by a cortical spectrin cytoskeleton (Evans & Skalak Reference Evans and Skalak1980; Mohandas & Evans Reference Mohandas and Evans1994; Mohandas & Gallagher Reference Mohandas and Gallagher2008; Kim et al. Reference Kim, Kim and Park2012). This organisation gives the RBC a richness of dynamics in flow, critical to understanding blood rheology. Numerical modelling of the RBC presents a challenge in identifying the dominant features necessary to reproduce this richness.

Some models retain the main membrane organisation into two structures of different nature, likely to slide in relation to each other (Krishnaswamy Reference Krishnaswamy1996; Noguchi & Gompper Reference Noguchi and Gompper2005; Peng, Asaro & Zhu Reference Peng, Asaro and Zhu2010, Reference Peng, Asaro and Zhu2011; McWhirter, Noguchi & Gompper Reference McWhirter, Noguchi and Gompper2011; Peng & Zhu Reference Peng and Zhu2013; Peng et al. Reference Peng, Li, Pivkin, Dao, Karniadakis and Suresh2013; Li et al. Reference Li, Peng, Lei, Dao and Karniadakis2014; Peng, Mashayekh & Zhu Reference Peng, Mashayekh and Zhu2014; Peng, Salehyar & Zhu Reference Peng, Salehyar and Zhu2015b; Chang et al. Reference Chang, Li, Li and Karniadakis2016; Pivkin et al. Reference Pivkin, Peng, Karniadakis, Buffet, Dao and Suresh2016; Salehyar & Zhu Reference Salehyar and Zhu2016; Chang, Li & Karniadakis Reference Chang, Li and Karniadakis2017; Zhu et al. Reference Zhu, Salehyar, Cabrales and Asaro2017; Lu & Peng Reference Lu and Peng2019). Each structure then has its own mesh, allowing for different kinematics to be considered. However, although these models have provided compelling arguments in their favour (Peng et al. Reference Peng, Chen, Lu, Pan and Chang2015a; Zhang et al. Reference Zhang, Huang, Kim, Golkaram, Dixon, Tilley, Li, Zhang and Suresh2015; Li, Lu & Peng Reference Li, Lu and Peng2018), they are not the most common approach.

In the quest for simplicity, a single-layer model is often preferred, despite the inevitable compromise of sacrificing some mechanical properties. When modelling the lipid bilayer as a vesicle, it becomes challenging to consider the shear elasticity provided by the cytoskeleton, as the focus shifts to favouring the fluidity and incompressibility of the bilayer. Conversely, when modelling the cytoskeleton as a capsule, the fluid nature of the lipid bilayer is compromised in favour of the elasticity of the cytoskeleton. In any case, a single-layer model imposes the same kinematics on the cytoskeleton and the lipid bilayer. For the out-of-plane kinematics, this assumption is limited only to the rare cases of cytoskeleton detachment (Peng et al. Reference Peng, Li, Pivkin, Dao, Karniadakis and Suresh2013; Zhu et al. Reference Zhu, Salehyar, Cabrales and Asaro2017). For the in-plane kinematics, the limitation of prohibiting the sliding of the cytoskeleton is less clear. The lipid bilayer, being in direct contact with the external environment, is susceptible to hydrodynamic stress and can, in turn, only drive the cytoskeleton via frictional forces that the lipid medium exerts on the junction proteins. Although the theoretical analysis of Fischer (Reference Fischer1992) suggests that the kinematics of the cytoskeleton and the lipid bilayer are identical in the tank-treading regime in shear flow, and the surface incompressibility constraint is transmitted from the lipid bilayer to the cytoskeleton, these findings cannot be generalised due to the lack of research in this area.

Vesicle modelling has proven useful in understanding the dynamics of flowing RBCs and is still used to study ensemble behaviour and its extrapolation to the rheology of blood (Brust et al. Reference Brust2014; Kabacaoğlu & Biros Reference Kabacaoğlu and Biros2019; Lu et al. Reference Lu, Morse, Rahimian, Stadler and Zorin2019). However, the fundamental contribution of shear elasticity provided by the cytoskeleton cannot be overlooked (Hoore et al. Reference Hoore, Yaya, Podgorski, Wagner, Gompper and Fedosov2018; Mendez & Abkarian Reference Mendez and Abkarian2018). To account for this, the single-layer capsule representation has emerged as the more prevalent modelling strategy.

While the various modelling strategies for RBCs contribute to our understanding of their dynamics, a comparative study to assess the impact of each simplification has not yet been undertaken, to our knowledge. Only the choice between a capsule represented by a network of springs or a continuum model has been considered (Omori et al. Reference Omori, Ishikawa, Barthès-Biesel, Salsac, Walter, Imai and Yamaguchi2011; Tsubota Reference Tsubota2014). However, this may lead to bias in the identification of mechanical properties necessary to reproduce experimental observations. To be meaningful, a comparative study must minimise the specificities of numerical implementation for each choice. This entails treating the method of flow solution and the geometric representation of surfaces with the same precision. The numerical platform we have developed to investigate the fluid–structure interaction problem of surfactant-coated drops, vesicles and capsules, enables such study (Boedec, Leonetti & Jaeger Reference Boedec, Leonetti and Jaeger2017). In the vesicle model, we employ distinct approaches to handle the movements of the bilayer in the normal and tangential directions. Specifically, we adopt a Lagrangian approach for the normal movement, while we use an Eulerian description for the tangential movement. Consequently, the tangential motion of mesh vertices (or nodes within a finite-element framework), which does not alter the membrane's shape, is entirely decoupled from the tangential movement of the lipids. In fact, this decoupling allows us to conveniently prescribe the tangential velocities of mesh vertices to maintain mesh quality in the context of vesicle simulations. Additionally, in Lyu et al. (Reference Lyu, Chen, Boedec, Leonetti and Jaeger2018), we demonstrated that different in-plane kinematics of the cytoskeleton and lipid bilayer can be considered without duplicating meshes. This is achieved by using an Eulerian kinematic description for the fluid lipid bilayer and a Lagrangian one for the solid cytoskeleton. The motion of the mesh coincides with that of the cytoskeleton, while the Eulerian description allows for different tangential motions of the lipid bilayer. Using only one mesh prohibits consideration of different out-of-plane kinematics but allows different in-plane ones at a minimal cost.

We believe that a comparative study to characterise the impact of different RBC modelling strategies is justified for another important reason: the contribution of surface viscosity. The origin of this viscosity can be explained by several mechanisms, but its inclusion in simulations depends on the choice of membrane representation (Li, Vlahovska & Karniadakis Reference Li, Vlahovska and Karniadakis2013; Vlahovska, Barthes-Biesel & Misbah Reference Vlahovska, Barthes-Biesel and Misbah2013; Yazdani & Bagchi Reference Yazdani and Bagchi2013; Fedosov, Noguchi & Gompper Reference Fedosov, Noguchi and Gompper2014; Freund Reference Freund2014; Gounley & Peng Reference Gounley and Peng2015; Peng et al. Reference Peng, Chen, Lu, Pan and Chang2015a; Prado et al. Reference Prado, Farutin, Misbah and Bureau2015; Li et al. Reference Li, Lu and Peng2018; Guglietta et al. Reference Guglietta, Behr, Biferale, Falcucci and Sbragaglia2020; Tsubota Reference Tsubota2021). For instance, the friction of the junction proteins in the lipid bilayer can lead to significant variation in the effective surface viscosity of the RBC. Therefore, we feel it is essential to first assess the purely elastic aspects of RBC mechanics before considering the contribution of surface viscosity.

The rest of this paper is organised as follows. In § 2, we outline the implementation of the different modelling strategies, which are then subjected to a comparative study of their elastic properties under axisymmetric extensional flow in § 3 and simple shear flow in § 4, respectively. The former, akin to laser tweezer stretching, is a widely used technique for characterising the mechanical properties of cells, while the latter is the reference flow for characterising the dynamics of RBCs. In § 5, we discuss the results and their implications and provide new insights into the dynamics of RBCs. Finally, in § 6, we draw broader conclusions that extend beyond the modelling framework.

2. Red blood cell modelling strategies

We have implemented the vesicle and capsule models in our platform, which have been previously described in Boedec et al. (Reference Boedec, Leonetti and Jaeger2017) and Lyu et al. (Reference Lyu, Chen, Boedec, Leonetti and Jaeger2021) for use in unbounded and confined spaces, respectively. The vesicle model accounts for the fluid nature of the membrane and enforces surface incompressibility by projecting the three-dimensional (3-D) velocity field onto a space with zero surface divergence (Boedec, Leonetti & Jaeger Reference Boedec, Leonetti and Jaeger2011). In addition, the isogeoparametric representation of the geometry (Cottrell, Hughes & Bazilevs Reference Cottrell, Hughes and Bazilevs2009), which has at least $C^1$ (i.e. continuous first derivatives) regularity, allows for the incorporation of the Helfrich bending energy using a rigorous weak mathematical formulation. Meanwhile, the capsule model can utilise several models of polymerised membrane behaviour and incorporate bending elasticity through the Helfrich formulation developed for the vesicle model or other common forms of thin-shell modelling. Although the vesicle and capsule models can incorporate shear and dilatation surface viscosity developed for a surfactant drop (Gounley et al. Reference Gounley, Boedec, Jaeger and Leonetti2016), we will not be utilising this option for our objective of this paper, which is to assess the purely elastic aspects of RBC mechanics. As the details of these models are available elsewhere, we will focus solely on their key elements in this section.

Our isogeometric representation is obtained using the Loop subdivision method (Loop Reference Loop1987; Cirak, Ortiz & Schröder Reference Cirak, Ortiz and Schröder2000; Cirak & Ortiz Reference Cirak and Ortiz2001). To generate the control mesh for a vesicle or capsule, we start with an icosahedron and perform $N$ Loop subdivisions. The value $N=0$ corresponds to the initial icosahedron, which has $N_{elem}=20$ equilateral triangular elements that correspond to 20 Loop elements. With each refinement level, each element is subdivided into four equivalent equilateral triangles, and a node is inserted at the centre of each edge. The spatial position of all nodes in the refined mesh is determined using Loop's rules, which ensure zero geometric representation error. The level $N$ generates a mesh with $N_{elem}=20 \times 4^N$. We typically achieve satisfactory accuracy using $N=3$, resulting in $N_{elem}=1280$. Note that the twelve nodes of the $N=0$ level have fifth-order connectivity, while all other nodes introduced afterwards have sixth-order connectivity. These twelve nodes are called singular, and they are an inevitable trace of the icosahedron. The regularity of the Loop approximation is only $C^1$ at these nodes, while it is $C^2$ everywhere else. It is worth highlighting that our isogeometric finite-element method, which relies on the Loop subdivision, diverges from traditional shell modelling techniques commonly used in structural mechanics. The advantage of our approach is its ability to circumvent the shear-locking phenomenon typically observed in conventional methods (Cirak et al. Reference Cirak, Ortiz and Schröder2000; Cirak & Ortiz Reference Cirak and Ortiz2001).

The boundary element method (Pozrikidis Reference Pozrikidis1992, Reference Pozrikidis2002) is used with the surface mesh described earlier to obtain the velocity of the lipid medium at each node. We can then determine the velocity at any point of an element using Loop's interpolation functions. The normal component of this velocity field determines the evolution of the surface position between two time steps in the simulation. Meanwhile, the movement of the nodes tangentially to the membrane is identified with the kinematics of a cytoskeleton. This tangential movement is determined by equilibrating the elastic forces exerted by the cytoskeleton with the viscous friction forces of the points of attachment of the cytoskeleton in the lipid bilayer. The viscous friction force is proportional to the velocity difference between the bilayer and the cytoskeleton. For the unconfined case and without considering a viscosity contrast to simplify the presentation, the system can be formulated as follows (Lyu et al. Reference Lyu, Chen, Boedec, Leonetti and Jaeger2018):

(2.1)\begin{gather} \boldsymbol{v}^{BL} = \boldsymbol{v}^{3D} = \boldsymbol{\mathsf{P}} \left( \boldsymbol{v}^{\infty} + \boldsymbol{\mathsf{G}} \boldsymbol{f}^{RBC} \right) \quad \mbox{with} \ \boldsymbol{f}^{RBC} = \boldsymbol{f}^{BL} + \boldsymbol{f}^{SC}, \end{gather}
(2.2)\begin{gather}\boldsymbol{x}(t+\mathrm{d}t) = \boldsymbol{x}(t) + \boldsymbol{v}^{SC}\,\mathrm{d}t \quad \mbox{with} \ \boldsymbol{v}^{SC} = \boldsymbol{v}^{BL} + \boldsymbol{v}^{SC/BL}. \end{gather}

Position and velocity fields of the RBC membrane are denoted by $\boldsymbol {x}$ and $\boldsymbol {v}$, respectively. Superscripts BL and SC are used to distinguish between the lipid bilayer and the spectrin cytoskeleton, respectively, while $3D$ is for the bulk flow and $\infty$ for the imposed background one. The velocity difference between the cytoskeleton and the lipid bilayer $\boldsymbol {v}^{SC/BL} = \boldsymbol {v}^{SC} - \boldsymbol {v}^{BL}$ is a tangential vector. The Green's operator associated with the Stokeslet is represented by $\boldsymbol{\mathsf{G}}$, and the projection operator on a subspace with zero surface divergence is denoted by $\boldsymbol{\mathsf{P}}$. This operator ensures that the surface tension $\gamma$, which is the Lagrange multiplier of the surface incompressibility constraint, satisfies the condition that the surface divergence of the velocity field $\boldsymbol {v}^{BL}$ is zero. The surface densities of force induced by the lipid bilayer and the cytoskeleton correspond to $\boldsymbol {f}^{BL}$ and $\boldsymbol {f}^{SC}$, respectively, and their sum $\boldsymbol {f}^{RBC}$ corresponds to the surface force density exerted by the entire RBC membrane on the ambient fluids. The matrix expression of the system (2.1)–(2.2) and the principle of the solution algorithms are presented in detail in Boedec et al. (Reference Boedec, Leonetti and Jaeger2017) and Lyu et al. (Reference Lyu, Chen, Boedec, Leonetti and Jaeger2018, Reference Lyu, Chen, Boedec, Leonetti and Jaeger2021). While we encourage interested readers to refer to these sources, we note that the rest of the paper is accessible without prior knowledge of them.

Using this validated approach, which has been successfully applied in our previous studies of vesicles and capsules, we have developed several strategies for modelling RBCs. These strategies encompass single-layer vesicle and capsule models, as well as double-layer vesicle–capsule and capsule–capsule models. To aid in visual comprehension, figure 1 presents a schematic depiction of the surface densities relevant to the RBC models. In the subsequent sections, we provide a detailed outline of the implementation for each of these models. To aid in the comparison of the results across all the studies, the same colour coding is utilised in all figures, where the vesicle is represented in black, the capsule in blue, the vesicle–capsule in red and the capsule–capsule in green.

Figure 1. Schematic representation of the RBC models illustrating the relevant surface force densities on the respective layers. (a) Single-layer vesicle model with out-of-plane elasticity ($\boldsymbol {f}^{e\perp }$) and surface incompressibility ($\boldsymbol {f}^{\gamma }$). (b) Single-layer capsule model with in-plane ($\boldsymbol {f}^{e\parallel }$) and out-of-plane elasticities (surface incompressibility is approximatively considered). (c) Double-layer vesicle–capsule model with in-plane and out-of-plane elasticities, along with surface incompressibility. (d) Double-layer capsule–capsule model with in-plane and out-of-plane elasticities (surface incompressibility is approximatively considered). All models employ a single mesh, with the distinction that, in double-layer models, $\boldsymbol {v}^{BL} \neq \boldsymbol {v}^{SC}$ due to the differing assumed tangential kinematics of the two layers.

Throughout this paper, we use dimensionless variables, denoted by a star symbol. Lengths are expressed in units of a volume-based radius $R\equiv [3V/(4{\rm \pi} )]^{1/3}$, where $V\simeq 94\ \mathrm {\mu }{\rm m}^3$ represents the enclosed volume of RBCs. The surface area $A$ is approximately $135\ \mathrm {\mu }{\rm m}^2$, giving a reduced volume $v\equiv 3\sqrt {4{\rm \pi} }VA^{-3/2} = 0.64$ (Evans & Skalak Reference Evans and Skalak1980). Time is scaled by $\eta _{ext}R/\mu _s$, where $\eta _{ext}$ is the viscosity of the suspending fluid and $\mu _s$ is the surface shear modulus. A summary of the mechanical properties utilised in the simulations is provided in table 1. These data are based on averages of recognised values for a healthy RBC (see, e.g. table 1 in Levant & Steinberg Reference Levant and Steinberg2016). The table also displays the distribution of properties between the cytoskeleton and the lipid bilayer in the modelling strategies that distinguish them.

Table 1. Mechanical properties.

The reference shape, whether quasi-spherical or biconcave, represents the shape relative to which in-plane and out-of-plane deformations are defined. In simpler terms, when the cytoskeleton (Skalak capsule) adopts the reference shape, the in-plane deformations are zero. It is important to clarify that all our simulations begin with an RBC already in the biconcave shape (i.e. $v=0.64$), which we obtain directly from an analytical expression (Evans & Skalak Reference Evans and Skalak1980) and consistently used in our prior work, as outlined in Lyu et al. (Reference Lyu, Chen, Boedec, Leonetti and Jaeger2018). The reference shapes we consider include the biconcave shape itself, a quasi-spherical shape ($v=0.96$) with zero spontaneous curvature and a quasi-spherical shape ($v=0.96$) with positive curvature ($C_0^* = C_0/R = 4$) (Peng et al. Reference Peng, Mashayekh and Zhu2014). If not specified, we have used quasi-spherical with zero spontaneous curvature. The quasi-spherical reference shape, achieved through a relaxation process, corresponds to the deflated shape of a vesicle with a reduced volume of $v=0.96$.

2.1. Single-layer vesicle strategy (colour code $=$ black)

The vesicle model does not consider a separate contribution of the cytoskeleton (i.e. $\boldsymbol {f}^{SC} = \boldsymbol {0}$), while

(2.3)\begin{gather} \boldsymbol{f}^{BL}(\boldsymbol{x}) = \boldsymbol{f}^{\gamma}(\boldsymbol{x}) + \boldsymbol{f}^{e\perp}(\boldsymbol{x}) ={-}\frac{\delta \mathcal{W}^{BL}}{\delta \boldsymbol{x}} ={-}\frac{\delta ( \mathcal{W}^{\gamma} + \mathcal{W}^{H} )}{\delta \boldsymbol{x}}, \end{gather}
(2.4ac)\begin{gather}\mathcal{W}^{\gamma} = \int_S \gamma \,\mathrm{d} S, \quad \mathcal{W}^{H} = \int_S w^H \,\mathrm{d}S, \quad w^H = \frac{k_b}{2} (2 H + C_0 )^2. \end{gather}

The $\boldsymbol {f}^{e\perp }$ contribution represents the out-of-plane elastic forces, namely the bending forces induced by the Helfrich surface energy density $w^H$, which depend on the mean curvature $H$ and the spontaneous curvature $C_0$. The spontaneous curvature $C_0$ is defined as $C_0 = - 2H_0$, where $H_0$ is the mean curvature of the spontaneous or reference shape of the lipid bilayer. For zero spontaneous curvature, the Helfrich energy reduces to the simple expression $w^H = 2 k_b H^2$, where $k_b=2.4\times 10^{-19}$ J is the bending modulus. We omit the contribution of the Gaussian curvature, which can occur in $w^H$ but is not useful due to the Gauss–Bonnet theorem, as we are not considering a change in surface topology. The contribution of $\boldsymbol {f}^{\gamma }$ corresponds to the forces induced by the surface tension $\gamma$. For a constant tension, it results in an out-of-plane force contribution, but it can also produce in-plane forces if the tension varies, as $\boldsymbol {f}^{\gamma } = 2 \gamma H \boldsymbol {n} + \boldsymbol {\nabla }_s \gamma$, where $\boldsymbol {n}$ is the normal vector to the surface and $\boldsymbol {\nabla }_s= (\boldsymbol{\mathsf{I}} - \boldsymbol {n} \boldsymbol {n}) \boldsymbol {\cdot } \boldsymbol {\nabla }$ is the surface gradient operator, with $\boldsymbol{\mathsf{I}}$ being the identity in $\mathbb {R}^3$.

We want to emphasise that in the vesicle model, surface incompressibility, expressed as $\boldsymbol {\nabla }_s \boldsymbol {\cdot }\boldsymbol {v}^{BL} = 0$, is enforced through a projection algorithm, specifically, the projection operator $\boldsymbol{\mathsf{P}}$ as defined in (2.1). This projection introduces the surface tension parameter $\gamma$, acting as a Lagrange multiplier for the surface incompressibility constraint. While this method effectively ensures both local and global surface area conservation, it does come at a significant computational cost, as previously discussed (Boedec et al. Reference Boedec, Leonetti and Jaeger2017).

2.2. Single-layer capsule strategy (colour code $=$ )

The capsule model does not consider a separate contribution of the cytoskeleton (i.e. $\boldsymbol {f}^{SC} = \boldsymbol {0}$). While bending is still modelled using the Helfrich energy, the in-plane elasticity of the cytoskeleton is nicely represented by a capsule. On the other hand, fluidity is lost and surface incompressibility can only be approximated since the projector $\boldsymbol{\mathsf{P}}$ is replaced by the identity. Thus, we obtain the capsule model with

(2.5)\begin{equation} \boldsymbol{f}^{BL}(\boldsymbol{x}) = \boldsymbol{f}^{e \parallel}(\boldsymbol{x}) + \boldsymbol{f}^{e\perp}(\boldsymbol{x}) ={-}\frac{\delta \mathcal{W}^{BL}}{\delta \boldsymbol{x}} ={-}\frac{\delta ( \mathcal{W}^{SK} + \mathcal{W}^{H} )}{\delta \boldsymbol{x}} , \end{equation}

where $\boldsymbol {f}^{e\parallel }$ represents the in-plane elastic forces deduced from a polymerised membrane strain energy, which is usually defined on the reference configuration ($S^0$). Surface deformations are computed relative to this reference configuration (Boedec et al. Reference Boedec, Leonetti and Jaeger2017, (24)). To model the strain-hardening behaviour of the RBC membrane, we typically use the expression proposed by Skalak et al. (Reference Skalak, Tozeren, Zarda and Chien1973), which is given by

(2.6a,b)\begin{equation} \mathcal{W}^{SK} = \int_{S^0} w^{SK} \,\mathrm{d} S^0, \quad w^{SK} = \frac{G_s}{4} ( I_1^2 + 2I_1 - 2I_2 + C^{SK}I_2^2 ), \end{equation}

where the two invariants $I_1$ and $I_2$ are expressed as functions of the two main strains $\lambda _1$ and $\lambda _2$. The resistance to shear is controlled by the coefficient $G_s$, which is the surface shear modulus $\mu _s = 6\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$, and the resistance to local area variation is controlled by the coefficient $C^{SK}$, which is the ratio of the area dilatation modulus to the shear modulus. The limiting case of surface incompressibility is obtained by making $C^{SK}$ tend towards infinity, where $I_2$ cancels. In practice, however, the numerical problem becomes too steep when $C^{SK}$ exceeds a hundred (Dodson & Dimitrakopoulos Reference Dodson and Dimitrakopoulos2010). For long-term simulations, we add a global area conservation constraint to prevent a strong drift of the RBC surface area. This constraint results in a contribution of the same type as $\mathcal {W}^{\gamma }$, with the surface tension $\gamma$ being replaced by a constant tension $k_s (S - S^0)/S^0$. In all our simulations, we used $C^{SK} = 80$ in combination with $k_s = 10^{3}\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$ (Sigüenza, Mendez & Nicoud Reference Sigüenza, Mendez and Nicoud2017) when surface incompressibility has to be considered. Our extensive investigation has revealed that the contribution of $k_s$ remains negligible, as local area preservation is consistently maintained throughout our study.

2.3. Double-layer vesicle–capsule strategy (colour code $=$ )

The vesicle–capsule model is obtained by combining the expression (2.3) of $\boldsymbol {f}^{BL}$ and

(2.7)\begin{equation} \boldsymbol{f}^{SC}(\boldsymbol{x}) = \boldsymbol{f}^{e \parallel}(\boldsymbol{x}) ={-}\frac{\delta \mathcal{W}^{SC}}{\delta \boldsymbol{x}} ={-} \frac{\delta \mathcal{W}^{SK}}{\delta \boldsymbol{x}}. \end{equation}

In contrast to the vesicle model, the contribution from the cytoskeleton $\boldsymbol {f}^{SC}$ is not set to zero. The incompressibility constraint is still rigorously ensured by the $\boldsymbol{\mathsf{P}}$ projector. The coefficient $C^{SK}$ in Skalak's law is then fixed to represent the contribution of the cytoskeleton only, which is negligible compared with the resistance to expansion provided by the lipid bilayer. The dilatation modulus of the cytoskeleton was determined experimentally to be within the range of $1\unicode{x2013}10\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$ (Lenormand et al. Reference Lenormand, Hénon, Richert, Siméon and Gallet2001, Reference Lenormand, Hénon, Richert, Siméon and Gallet2003; Kim et al. Reference Kim, Kim and Park2012), with a theoretical value for a regular hexagonal lattice being twice the shear modulus (Discher, Mohandas & Evans Reference Discher, Mohandas and Evans1994; Hansen et al. Reference Hansen, Skalak, Chien and Hoger1996). Thus, we set the expansion rigidity of the capsule representing the cytoskeleton to $C^{SK} = 2$ in our double-layer strategy simulations. In other words, the cytoskeleton only provides resistance to shear deformation, with $G_s = 6\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$ and $C^{SK}=2$.

2.4. Double-layer capsule–capsule strategy (colour code $=$ )

The distinction between the vesicle–capsule model and the capsule–capsule model lies in how the lipid bilayer is represented, with the former using a vesicle and the latter using a capsule to mimic an incompressible fluid membrane. This disparity is particularly noticeable in (2.5), which incorporates the necessary bending energy to represent the bilayer. In contrast, (2.7) lacks a bending energy term, which is essential for modelling the cytoskeleton. These variations in mechanical properties are outlined in detail in table 1.

To derive the capsule–capsule model, we combine (2.5) for $\boldsymbol {f}^{BL}$ and (2.7) for $\boldsymbol {f}^{SC}$. Similar to the vesicle–capsule model, Skalak's law is used to represent the cytoskeleton, employing the same parameter values ($G_s = 6\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$ and $C^{SK} = 2$). However, achieving the behaviour of the lipid bilayer in $\boldsymbol {f}^{e \parallel }$ within $\boldsymbol {f}^{BL}$ necessitates another capsule model and a second application of Skalak's law. To accomplish this, the elastic shear modulus $G_s$ is chosen to be sufficiently small to ensure that the shear strength contribution remains negligible in comparison with the cytoskeleton. For this purpose, we have selected $G_s = 10^{-3}\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$ (Zhu et al. Reference Zhu, Salehyar, Cabrales and Asaro2017), alongside $C^{SK} = 80$ and $k_s = 10^{3}\ \mathrm {\mu }{\rm N}\ {\rm m}^{-1}$. While this approach does not perfectly emulate the fluid nature of the lipid bilayer due to the non-zero shear modulus, it enhances computational efficiency.

2.5. Membrane elastic force determination

The boundary conditions between the two-layer structure are implicit. Because of the single mesh representation, the two structures are constrained to have the same motion in the normal direction. In the tangent plane, sliding is permitted and limited exclusively by tangential friction forces. Therefore, the double-layer models depend on the frictional coupling between the lipid bilayer and cytoskeleton through junction protein complexes. Let $\boldsymbol {f}^{BL/SC}$ be the surface density of frictional force exerted by the lipid bilayer on the cytoskeleton. By the action–reaction principle, $\boldsymbol {f}^{SC/BL} = -\boldsymbol {f}^{BL/SC}$. The static equilibrium of the two structures can be expressed as

(2.8a,b)\begin{equation} \boldsymbol{f}^{SC} + \boldsymbol{f}^{BL/SC} = 0, \quad \boldsymbol{f}^{BL} + \boldsymbol{f}^{SC/BL} + \boldsymbol{f}^{ext} = 0, \end{equation}

where $\boldsymbol {f}^{ext}$ represents the action of the ambient fluids on the RBC membrane, which is in equilibrium with the forces induced by the deformation of the RBC, namely

(2.9)\begin{equation} \boldsymbol{f}^{ext} ={-}\boldsymbol{f}^{RBC} ={-}(\boldsymbol{f}^{BL} + \boldsymbol{f}^{SC}), \end{equation}

consistent with (2.1).

The finite-element method is used to determine the external forces through a weak formulation using the virtual work principle, for a given membrane configuration

(2.10)\begin{gather} \delta \mathcal{W}^{ext} + \delta \mathcal{W}^{int} = 0, \end{gather}
(2.11)\begin{gather} \delta \mathcal{W}^{ext}= \int_S \boldsymbol{f}^{ext} \boldsymbol{\cdot} \delta\boldsymbol{x}\,\mathrm{d}S ={-} \int_S \boldsymbol{f}^{RBC} \boldsymbol{\cdot} \delta\boldsymbol{x}\,\mathrm{d}S , \end{gather}
(2.12)\begin{align} \delta \mathcal{W}^{int}&={-}( \delta \mathcal{W}^{BL} + \delta \mathcal{W}^{SC} ) = \int_S -\frac{\delta \mathcal{W}^{BL}}{\delta \boldsymbol{x}} \boldsymbol{\cdot} \delta\boldsymbol{x}\,\mathrm{d}S + \int_S -\frac{\delta \mathcal{W}^{SC}}{\delta \boldsymbol{x}} \boldsymbol{\cdot} \delta\boldsymbol{x}\,\mathrm{d}S \nonumber\\ & = \int_S \boldsymbol{f}^{BL} \boldsymbol{\cdot} \delta\boldsymbol{x}\,\mathrm{d}S + \int_S \boldsymbol{f}^{SC} \boldsymbol{\cdot} \delta\boldsymbol{x}\,\mathrm{d}S. \end{align}

The internal virtual work $\delta \mathcal {W}^{int}$ depends on the surface stress and strain tensors, which can be determined based on the membrane configuration, see Boedec et al. (Reference Boedec, Leonetti and Jaeger2017) for details

(2.13)\begin{equation} \delta \mathcal{W}^{int} ={-}\int_S \left[ \sigma^{\alpha\beta} \delta(E_{\alpha\beta}) + \mu^{\alpha\beta} \delta(B_{\alpha\beta})\right]\mathrm{d}S = \int_S \left[\frac{1}{2} \sigma^{\alpha\beta} \delta(a_{\alpha\beta}) + \mu^{\alpha\beta} \delta(b_{\alpha\beta})\right]\mathrm{d}S. \end{equation}

Here, $\sigma _{\alpha \beta }$ and $\mu _{\alpha \beta }$ correspond to the stresses induced by membrane and bending strains, respectively. The tensor of components $E_{\alpha \beta }$ with $2E_{\alpha \beta } = a_{\alpha \beta }-a^{0}_{\alpha \beta }$ is the surface Green–Lagrange strain tensor and the tensor of components $B_{\alpha \beta } = b_{\alpha \beta }-b^{0}_{\alpha \beta }$ is the bending equivalent, where superscript 0 refers to the reference configuration. The $a_{\alpha \beta }$ are components of the metric tensor $\boldsymbol{\mathsf{a}}$ that correspond to the identity operator in the tangent plane $\boldsymbol{\mathsf{I}}^S = \boldsymbol{\mathsf{I}} - \boldsymbol {n} \boldsymbol {n}$. Its determinant $a = \mathrm {det}(\boldsymbol{\mathsf{a}})$ expresses the surface element as a function of the surface parameterisation $(s^1, s^2)$ as $\mathrm {d}S = \sqrt {a} \,\mathrm {d}s^1 \,\mathrm {d}s^2$.

2.6. Cytoskeleton drag force determination

We define $C_{f_{JC}}$ as the mean friction coefficient of a protein junction complex in the lipid bilayer. The frictional force generated by the movement of a single junction complex, on average, can be expressed as

(2.14)\begin{align} {\boldsymbol{f}_{\!JC}^{BL/SC}} &= C_{f_{JC}} \left( \boldsymbol{v}^{BL}(\boldsymbol{x}_{JC}) - \boldsymbol{v}^{SC}(\boldsymbol{x}_{JC}) \right) \nonumber\\ &= C_{f_{JC}} \boldsymbol{v}^{BL/SC}(\boldsymbol{x}_{JC}) ={-}C_{f_{JC}} \boldsymbol{v}^{SC/BL}(\boldsymbol{x}_{JC}). \end{align}

The equivalent friction coefficient per unit area of the membrane, denoted as $C_{f}$, is given by

(2.15)\begin{equation} \int_{\triangle S} C_{f} \boldsymbol{v}^{BL/SC}(\boldsymbol{x})\,\mathrm{d}S = \sum_{\boldsymbol{x}_{JC} \in \triangle S} C_{f_{JC}} \boldsymbol{v}^{BL/SC}(\boldsymbol{x}_{JC}) . \end{equation}

For a small patch of surface $\triangle S$, where the velocity variations can be ignored (i.e. $\forall \boldsymbol {x} \in \triangle S$, $\boldsymbol {v}^{BL/SC}(\boldsymbol {x}) = \boldsymbol {v}^{BL/SC}(\boldsymbol {x}_{JC}) \approx {\rm const}.$), we can simplify the expression to

(2.16)\begin{equation} C_{f} \triangle S = C_{f_{JC}} N_{JC} , \end{equation}

where $N_{JC}$ is the number of junction complexes within the patch. We can also introduce the areal density of the junction complex, denoted as $\rho _{JC}$, and obtain

(2.17)\begin{equation} C_{f} = \frac{N_{JC}}{\triangle S} C_{f_{JC}} = \rho_{JC} C_{f_{JC}}. \end{equation}

For our study, we adopted $C_f = 144\ {\rm pN}\ {\rm s}\ \mathrm {\mu }{\rm m}^{-3}$ (Peng et al. Reference Peng, Asaro and Zhu2011). The sensitivity of the double-layer modelling strategies to this parameter is discussed in § 5.

2.7. Cytoskeleton kinematics

The velocity differential between the cytoskeleton and the lipid bilayer is defined by the expression

(2.18)\begin{equation} \boldsymbol{v}^{SC/BL}(\boldsymbol{x}) = \boldsymbol{v}^{SC}(\boldsymbol{x}) - \boldsymbol{v}^{BL}(\boldsymbol{x}) ={-} \frac{1}{C_f} \boldsymbol{f}^{BL/SC}(\boldsymbol{x}) = \frac{1}{C_f} \boldsymbol{\mathsf{I}}^S \boldsymbol{f}^{SC}(\boldsymbol{x}). \end{equation}

To obtain the weak formulation of the problem, we employ the weighted residual method with $\delta \boldsymbol {x}$ as the test function, leading to the expression

(2.19)\begin{equation} \int_S \boldsymbol{v}^{SC/BL}(\boldsymbol{x}) \boldsymbol{\cdot} \delta \boldsymbol{x}\,\mathrm{d}S = \frac{1}{C_f} \int_S \boldsymbol{\mathsf{I}}^S \boldsymbol{f}^{SC}(\boldsymbol{x}) \boldsymbol{\cdot} \delta \boldsymbol{x}\,\mathrm{d}S. \end{equation}

The first member of this equation can be expressed as a function of the mass matrix in terms of the Loop interpolation functions, as given in Boedec et al. (Reference Boedec, Leonetti and Jaeger2017). Notably, the second term in the equation, which represents the internal force density of the cytoskeleton, is similar to the corresponding expression used to determine the elastic membrane forces of the RBC.

3. Comparison of RBC modelling strategies on extensional flow

Laser tweezer stretching is a widely used method to measure the mechanical properties of cells. However, numerical studies have two major shortcomings. Firstly, there is variability in how the opposing forces are applied in simulations (Sigüenza et al. Reference Sigüenza, Mendez and Nicoud2017). Secondly, it is not representative of the stretch that an RBC may experience in a flow since it does not consider the interaction with the surrounding fluid. An alternative approach that avoids these limitations is extensional flow, which has been used for studying vesicles in previous studies (Kantsler, Segre & Steinberg Reference Kantsler, Segre and Steinberg2007, Reference Kantsler, Segre and Steinberg2008; Zhao & Shaqfeh Reference Zhao and Shaqfeh2013; Narsimhan, Spann & Shaqfeh Reference Narsimhan, Spann and Shaqfeh2014; Dahl et al. Reference Dahl, Narsimhan, Gouveia, Kumar, Shaqfeh and Muller2016). In this method, the flow is defined by a single parameter, $\dot {\epsilon }$, which represents the stretching rate. In a Cartesian coordinate system, the velocity component in the direction of stretching ($z$ coordinate) is given by $v_z = \dot {\epsilon } z$. In its planar version, the other two velocity components are $v_x = - \dot {\epsilon } x$ and $v_y = 0$. In its axisymmetric version, they are written as $v_x = - \dot {\epsilon } x /2$ and $v_y = - \dot {\epsilon } y /2$. We considered both configurations, with the axis of symmetry of the RBC along the $y$ axis and a value of $\dot {\epsilon } = 55\ {\rm s}^{-1}$. The viscosity of the surrounding fluid was set at $\eta _{ext} =25\ {\rm mPa}\ {\rm s}$. As the behaviours were found to be similar, we only present the results for the axisymmetric configuration.

We first checked that the double-layer models behave similarly to the single-layer capsule model when the layers are prevented from sliding. This similarity is expected because all models employ the same set of elastic properties, as outlined in table 1. The difference lies in the distribution of these properties. In the capsule–capsule model, the outer capsule mimics the lipid bilayer and assumes responsibility for bending resistance and area conservation. The coefficient of shear elasticity for the outer capsule is considered negligible compared with that of the inner capsule, which solely represents the cytoskeleton properties. The vesicle–capsule model follows a similar approach. However, as the lipid bilayer is now represented by a vesicle, surface incompressibility is treated more rigorously. Consequently, a slightly reduced elongation compared with the other models is observed, reflecting the stiffening effect caused by the surface incompressibility constraint.

When sliding is allowed, the double-layer models deviate significantly from the single-layer capsule model, with a much higher elongation. In dimensionless time $t^*$, the capsule model reaches a state of permanent deformation at $t^*=3$, while the double-layer models continue to stretch out to $t^*=6$. Despite the slightly lower elongation of the vesicle–capsule model due to its better consideration of surface incompressibility, it remains close to that of the capsule–capsule model. The evolution of the RBC's shape is illustrated by the cross-sectional profiles in the three planes of symmetry in figures 2, 3 and 4 at $t^*=0$ (initial biconcave shape), $1$, $3$ and $6$. In all models, the dimple is reduced under stretching, with complete flattening observed in the capsule–capsule model, consistent with its higher elongation.

Figure 2. Shape evolution in the ($x^*, y^*$) plane perpendicular to the stretching direction for the axisymmetric extensional flow (capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ), for $t^* = 0$ ((a) initial shape – plotted in hereafter), $1$ (b), $3$ (c) and $6$ (d).

Figure 3. Shape evolution in the ($x^*,z^*$) stretch plane for the axisymmetric extensional flow (capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ), for $t^* = 0$ ((a) initial shape), $1$ (b), $3$ (c) and $6$ (d).

Figure 4. Shape evolution in the ($y^*,z^*$) stretch plane for the axisymmetric extensional flow (capsule $=$ , vesicle–capsule $=$ , capsule–capsule = ), for $t^* = 0$ ((a) initial shape), $1$ (b), $3$ (c) and $6$ (d).

The mechanical properties of all models are identical, resulting in similar behaviour when sliding is prohibited in the double-layer strategies. However, when sliding is allowed, the observed variation in behaviour must be explained by this additional degree of freedom. To quantify the intensity of sliding, figure 5 displays the dimensionless velocity difference between the cytoskeleton and lipid bilayer, which shows that sliding is maximal in the initial stages and disappears completely when the stationary state is reached. The sliding velocity in the ($x^*, y^*$) plane as a function of $x^*$ (figure 5a) and in the ($y^*,z^*$) plane as a function of $z^*$ (figure 5b) is given for $t^*=1$, $2$ and $6$. The curves of sliding velocity as a function of $z^*$ in the ($x^*,z^*$) plane (not shown here) are similar to those in the ($y^*,z^*$) plane, the intensity is slightly lower, with a maximum of approximately $0.04$ instead of $0.06$, and the sliding is almost identical for both models at $t^*=1$.

Figure 5. Decrease of the sliding velocity $\delta {\boldsymbol {v}}^*=\boldsymbol {v}^{*BL} - \boldsymbol {v}^{*SC}$ for $t^*=1$, 2 and $6$ for the axisymmetric extensional flow (vesicle–capsule $=$ , capsule–capsule $=$ ), as a function of $x^*$ in the ($x^*,y^*$) plane (a) and of $z^*$ in the ($y^*,z^*$) plane (b).

One explanation for the observed behaviour concerns the degree to which the surface incompressibility of the lipid bilayer is transmitted to the cytoskeleton. In the capsule model, the transmission is total since it is not possible to uncouple the cytoskeleton from the lipid bilayer. This is reflected by a value of the $C^{SK}$ coefficient of the Skalak model as large as possible, i.e. 80 in our simulations. On the other hand, in the double-layer models, the cytoskeleton can relax this constraint, thanks to the possibility of sliding. For these two models, $C^{SK}=2$ for the capsule which represents the cytoskeleton. Figure 6 compares the local relative area variation for the cytoskeleton between the three models. The local area variation is normalised by the total surface area of the RBC at rest, i.e. at the initial time. Although the variations are stronger and very comparable for the vesicle–capsule and capsule–capsule models, this explanation alone does not account for the observed behaviour.

Figure 6. Relative cytoskeleton area change (represented by the colour code between $-0.25$ in blue and $0.25$ in red) for the axisymmetric extensional flow at $t^* = 6$. $C^{SK} = 80$ for the capsule model (a) and $C^{SK} = 2$ for the capsule representing the cytoskeleton in the vesicle–capsule model (b) and capsule–capsule model (c).

The stress relaxation in the cytoskeleton offered by the possibility of sliding is more general, as it is not just about the local variation in the area. Instead, the cytoskeleton can better manage the whole deformation state imposed on it by the displacement of the RBC surface to which it is subject. The possibility of sliding gives it complete freedom to optimise its elastic stress state by the tangential movement to the surface. Moreover, there is a flow amplification effect, since the intensity of the velocity component according to the direction of the flow increases linearly in $|z^{*}|$. By reducing its deformation energy, the RBC can stretch further, and its two tips venture into regions where the intensity of the stretching velocity is greater, in accordance with the linear increase of the latter.

Figure 7 provides validation for this scenario, with a comparison of the elastic strain energy evolution for the whole RBC membrane (lipid bilayer $+$ cytoskeleton). The graph shows the deformation energy as a function of elongation, which is characterised by the position of the RBC tip in the stretching direction, denoted as $z^*_{max}$. This position is a nonlinear function of time, and the maximum elongation is reached when $z^*_{max}$ stabilises. When sliding is not allowed, the three evolution curves coincide, as seen in the blue curve obtained for the capsule model. In contrast, when sliding is allowed, the curves differ from each other, with the deformation energy being highest for the capsule model and lowest for the capsule–capsule model. The evolution curve for the vesicle–capsule model falls within the envelope formed by the other two curves, illustrating the correlation between the growth of deformation energy and the intensity of elongation. The final $z^*_{max}$ value for the capsule model is lower than 1.7, while it is higher for the vesicle–capsule and capsule–capsule models, reaching almost 1.9 for the latter. The bending contribution to the deformation energy is also plotted on the graph, but its influence is found to be negligible, with the three dashed lines being nearly identical.

Figure 7. Elastic deformation energy ($\mathcal {W}^{BL}+\mathcal {W}^{SC}$) as a function of the RBC elongation, given by the normalised position of the RBC's tip $z^*_{max}$ at normalised time $t^*$ (capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ). Solid lines: total elastic energy (lipid bilayer $+$ cytoskeleton). Dashed lines: bending energy contribution ($\mathcal {W}^{H}$).

It is interesting to note that the three curves of the total deformation energy all show a minimum for the same elongation value of $z^*_{max} \approx 1.1$, which is related to the chosen reference shape for the cytoskeleton, namely quasi-spherical. The deformation energy of the cytoskeleton decreases as the RBC comes closer to its reference shape, resulting in a minimum value for the deformation energy. If the discocyte reference shape is chosen instead, the curves no longer show a minimum. However, apart from this point, the evolution of the deformation energy is similar for both reference shapes, and the conclusion drawn from them is identical. The elastic strain energy curves are also found to be very close when a spontaneous curvature is considered for the quasi-spherical reference shape. Overall, these findings provide important insights into the relationship between deformation energy and elongation for different RBC models.

4. Comparison of RBC modelling strategies for shear flow

The simple shear flow is the most commonly used configuration for characterising the dynamics of a flowing RBC. By orienting the reference frame such that the $x$ axis corresponds to the direction of flow and the $y$ axis corresponds to that of the velocity gradient, the velocity field can be written as $\boldsymbol {v} = v(y) \boldsymbol {e}_x$, with $v(y) = \dot {\gamma }y$, as shown in figure 8. The $(x, y)$ plane corresponds to the shear plane, and the $z$ axis corresponds to the vorticity axis. The intensity of the shear rate $\dot {\gamma }$ is the single operating parameter that characterises this plane flow. For a suspended particle, such as an RBC, $\dot {\gamma }$ is a hydrodynamic forcing characterised by a viscous stress $\tau = \eta _{ext}\dot {\gamma }$, where $\eta _{ext}$ is the viscosity of the suspending fluid.

Figure 8. Schematic representation of the shear flow configuration (($x, y, z$) frame) with an RBC (($X, Y, Z$) frame). The angle $\phi$ is the orbit angle, i.e. the angle between the vorticity axis of the flow ($z$ axis) and the symmetry axis of the particle ($Z$ axis). The angle $\theta$ is the inclination angle between the direction of the velocity gradient ($y$ axis) and the projection in the shear plane of the particle's axis of symmetry ($Z$ axis).

Characterising the dynamics of the RBC requires considering its properties as a soft object, in addition to the characteristics of the flow. The first element determining its rigidity is the viscosity contrast $\lambda = \eta _{int}/\eta _{ext}$. Under physiological conditions, $\lambda$ is typically greater than unity because the viscosity of the cytosol of a healthy RBC can vary from $6$ to 20 mPa s (Mohandas & Gallagher Reference Mohandas and Gallagher2008; Williams & Morris Reference Williams and Morris2009), whereas that of the plasma is only approximately $1.5$ mPa s (between $1$ and $1.3$ at body temperature Késmárky et al. Reference Késmárky, Kenyeres, Rábai and Tóth2008). The value of $6$ mPa s is generally considered to be characteristic of the cytosol viscosity of a young and healthy RBC at body temperature. All simulations were carried out with $\eta _{int} = 10\ {\rm mPa}\ {\rm s}$, the value at room temperature. However, most experimental studies have been carried out with much more viscous outside fluids, resulting in characteristic viscosity contrasts below unity.

The second characteristic of the RBC's stiffness is related to the elastic properties of the RBC membrane, via its shear modulus $\mu _s$. Its contribution must be compared with that of the hydrodynamic strength, which gives rise to the introduction of the capillary number $Ca(\dot {\gamma },\mu _s) = \eta _{ext}\dot {\gamma }R/\mu _s = \tau /\tau _{ref}$, the ratio of the viscous stress $\tau = \eta _{ext}\dot {\gamma }$ and $\tau _{ref} = \mu _s/R$, which characterises the intensity of the elastic response of the cytoskeleton. Note that, with our choice of time reference scale $t_{ref} = \eta _{ext}R/\mu _s$, the capillary number may also be defined as $Ca(\dot {\gamma },\mu _s) = \dot {\gamma }t_{ref}$.

The dynamic regimes of RBC, and more generally of a capsule, in shear flow can be represented in the plane $\lambda, Ca(\dot {\gamma },\mu _s)$. For a vesicle, the reference elastic property is the bending modulus $k_b$. The capillary number used therefore is $Ca(\dot {\gamma },k_b) = \eta _{ext}\dot {\gamma }R^3/k_b$, which is related to the capillary number for capsules by the dimensionless Von Kármán number $\mathcal {K} = k_b/R^2\mu _s = (k_b/R^3)/{\tau _{ref}}$, reflecting the relative importance of curvature elasticity (out of plane) vs shear elasticity (in plane). For RBCs, the Von Kármán number is approximately $5\times 10^{-3}$ based on average values from table 1 of Levant & Steinberg (Reference Levant and Steinberg2016).

We use normalised quantities (indicated by a star) and dimensionless input data in our simulations. All surface density of force quantities is normalised by the reference elastic stress $\tau _{ref}$. Hence, the actual values of $\mu _s$ and $k_b$ are not provided. Instead, the former is specified using the capillary number $Ca(\dot {\gamma },\mu _s)$, while the latter is specified using the Von Kármán number $\mathcal {K}$.

Successive experimental studies have continued to enrich the RBC's phase diagram, and a synthesis of the experimental observations is proposed in Minetti et al. (Reference Minetti, Audemar, Podgorski and Coupier2019). Studies often assume the axis of symmetry of the RBC remains in the shear plane. Under these conditions, the RBC's dynamics can be characterised by the inclination angle $\theta$ (see figure 8) and the Taylor deformation parameter $D= (L - B)/(L+B)$, in which $L$ and $B$ are the major and minor axes of the ellipsoid having the same moment of inertia as the RBC. At low values of $\tau\!$, the RBC exhibits a tumbling dynamics. As $\tau$ increases, the axis of symmetry moves closer to the direction of the velocity and the deformation becomes more intense, resulting in the transition from tumbling to tank-treading dynamics. The inclination angle and the Taylor parameter take constant values in the tank-treading regime, with periodic variations around their mean values (swinging) but with decreasing amplitude at higher $\tau\!$. However, experimental studies indicate that an increase in the shear rate is more likely to cause the axis of symmetry to drift out of the shear plane, leading to a rolling dynamics and the appearance of new dynamic regimes showing RBCs with stomatocyte and then multilobe shapes (Mauer et al. Reference Mauer, Mendez, Lanotte, Nicoud, Abkarian, Gompper and Fedosov2018). The critical transition capillary number curve $Ca_c(\dot {\gamma },\mu _s)$ reaches its minimum when $\eta _{ext}$ is greater than 20 mPa s (Fischer & Korzeniewski Reference Fischer and Korzeniewski2013), making it easier to reach the tank-treading regime at high values of $\eta _{ext}$. As we move towards physiological values of $\eta _{ext}$, i.e. at $\lambda > 1$, the curve $Ca_c(\dot {\gamma },\mu _s)$ sharply increases and the transition can only be reached by imposing very high shear rates.

To simplify our analysis, we have assumed that the axis of symmetry of the RBC remains in the shear plane. Although this assumption may not hold for all transition routes, it is sufficient for our purpose, which is to compare modelling strategies at representative points of the RBC dynamics. Moreover, as demonstrated in Levant & Steinberg (Reference Levant and Steinberg2016), the relationship between simple shear flow and plane linear flow allows for this simplified configuration. Another reason to restrict to this simpler configuration is that the characteristic drift time of the RBC symmetry axis out of the shear plane can be large relative to the time scale of RBC dynamics for large $\eta _{ext}$ and small $\dot {\gamma }$ (Levant & Steinberg Reference Levant and Steinberg2016). In addition, under physiological conditions, stable orbits widen as the shear rate decreases, and all orbits become stable below a certain value of $\tau\!$, which is approximately $10^{-2}$ Pa (as shown in figure 14(c) in Minetti et al. Reference Minetti, Audemar, Podgorski and Coupier2019). This trend is consistent at both low and high $\eta _{ext}$ values, as long as we consider equivalent viscous stress. Therefore, exploring the low $\tau$ region is easier when $\eta _{ext}$ is small, as in physiological conditions.

To comprehensively explore the diverse dynamic regimes of an RBC in shear flow, our comparative study focuses on four key points ($\lambda, Ca(\dot {\gamma },\mu _s)$) of the phase diagram. The first point corresponds to the tumbling regime, which is a stable regime for an RBC with its axis of symmetry in the flow plane under physiological conditions. The second point corresponds to the tank-treading regime, which is observed at $\eta _{ext}$ values greater than 20 mPa s. We consider both possible orientations of the axis of symmetry of the RBC, aligned with the axis of vorticity or in the shear plane. The third point is located in the intermittency region, where both tumbling and tank-treading dynamics coexist. Finally, the last point is selected under physiological conditions but with a high shear rate to compare the modelling strategies in the regime of very high deformations.

4.1. Effect of modelling strategy on tumbling dynamics

Our first investigation point considered a viscous stress of 0.01 Pa and an external viscosity of 1.5 mPa s, corresponding to the characteristic dimensionless numbers $\lambda = 6.67$ and $Ca(\dot {\gamma },\mu _s) = 5 \times 10^{-3}$. We found that the inclination angle of the RBC (figure 9a) undergoes a tumbling motion, with the spinning frequency around the vorticity axis varying based on the model used. Interestingly, the capsule model exhibited the highest frequency, while the vesicle model's rotation frequency was almost half that of the other models.

Figure 9. (a) Time evolution of the inclination angles $\theta /{\rm \pi}$ in tumbling regime at $\lambda = 6.67, Ca(\dot {\gamma },\mu _s) = 5\times 10^{-3}$. Points: simulations (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ). Solid lines: Jeffery's theory (second equation of (4.1a,b)) for fitted $r$ on frequency criteria ($r = 2.25$ for capsule, $r = 2.35$ for vesicle–capsule, $r = 2.46$ for capsule–capsule and $r = 4.15$ for vesicle). (b) Time evolution of the deformation parameter $D$.

Additionally, the Taylor deformation parameter $D$ (figure 9b) highlighted a direct relationship between an object's stiffness and its rotation frequency, with the effect being particularly amplified in the vesicle model, which lacks shear elasticity. Further analysis showed that the stiffening effect of the surface incompressibility constraint was clearly demonstrated in the comparison between the capsule–capsule and vesicle–capsule models.

Since the RBC's deformation is small, this dynamic regime is close to that of a rigid particle, and Jeffery's theory (Jeffery Reference Jeffery1922)

(4.1a,b)\begin{equation} r\tan\phi = \frac{C^{orbit}}{\sqrt{r^{{-}2}\cos^2\theta+\sin^2\theta}} , \quad r\tan\theta = \tan \frac{\dot{\gamma}t}{r+r^{{-}1}}, \end{equation}

holds well, where $C^{orbit} = r\tan \phi _0$ is the orbit parameter and $r$ is the particle's aspect ratio. The prolate and oblate shapes are characterised by $r < 1$ and $r > 1$, respectively, with $r$ appearing in the equation $X^2 + Y^2 + r^2Z^2 = 1$ for the surface of an ellipsoidal object. It is important to note that, in this theory, all orbits are probable and determined solely by the initial value $\phi _0$ of the angle $\phi$. To verify Jeffery's theory, we superimposed the curves obtained for each modelling strategy using the second equation of (4.1a,b) as solid lines (figure 9a), with the aspect ratio $r$ adjusted to reproduce the oscillation frequency of the model.

4.2. Effect of modelling strategy on tank-treading dynamics

In the second point, we investigated the effects of increased external viscosity ($\eta _{ext} = 25\ {\rm mPa}\ {\rm s}$) and high shear rate ($\tau = 1.06\ {\rm Pa}$) on RBCs, characterised by the dimensionless numbers $\lambda = 0.4$ and $Ca(\dot {\gamma },\mu _s) = 0.5$. When the RBC axis of symmetry is initially aligned with the axis of vorticity, the transient phase during which it adapts its shape is longer. Figures 10 and 11 show the shape evolution during this phase in the $(x^*,y^*)$ and $(z^*,y^*)$ planes, respectively. All models follow a similar transition pattern with equivalent times, except for the vesicle model, which undergoes a large deformation and then lengthens. However, a difference in behaviour can be observed between single-layer and double-layer strategies. While the capsule model still shows a curvature inversion at $y^* = 0$ in the $(y^*, z^*)$ plane at $t^* = 11$, the double-layer models do not. Figure 12 provides a 3-D view at that time.

Figure 10. Shape evolutions ($(x^*,y^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transient phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), for the case when the RBC's symmetry axis is initially aligned with the axis of vorticity (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ).

Figure 11. Shape evolutions ($(y^*,z^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transient phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), for the case when the RBC's symmetry axis is initially aligned with the axis of vorticity (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ).

Figure 12. Shapes (3-D view) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transient phase at $t^* = 11$, for the case when the RBC's symmetry axis is initially aligned with the axis of vorticity. (a) Vesicle, (b) capsule, (c) vesicle–capsule, (d) capsule–capsule.

When the RBC's axis of symmetry is initially in the shear plane, it is already well oriented relative to its final steady state. The transient phase of large deformations is, correspondingly, reduced. The shape evolution during this phase in the $(x^*,y^*)$ and $(z^*,y^*)$ planes is shown in figures 13 and 14, respectively. Figure 15 at $t^* = 15$ provides a 3-D view.

Figure 13. Shape evolutions ($(x^*,y^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transition phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), when the RBC's symmetry axis is in the shear plane at the start (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ).

Figure 14. Shape evolutions ($(y^*,z^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transition phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), when the RBC's symmetry axis is in the shear plane at the start (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ).

Figure 15. Shapes (3-D view) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transition phase at $t^* = 15$, when the RBC's symmetry axis is in the shear plane at the start (a) vesicle, (b) capsule, (c) vesicle–capsule, (d) capsule–capsule.

After the transient phase, the dynamics is identical, regardless of the initial orientation of the symmetry axis. The evolution curves in figure 16 are indistinguishable from those obtained when the axis of symmetry is aligned with the axis of vorticity, with a normalised time shift of $\triangle t^* =11.6$. Thus, generalisation to any initial orientation is highly likely.

Figure 16. Time evolution of the inclination angle $\theta /{\rm \pi}$ (a) and the deformation parameter $D$ (b) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, when the RBC's symmetry axis is initially in the shear plane (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ).

Once the steady state is reached, the inclination angle's evolution (figure 16a) reveals that the swinging is most pronounced for the capsule model and least pronounced for the vesicle–capsule model. The capsule–capsule model is in between. As expected, the vesicle model exhibits pure tank-treading motion, characterised by a constant value of the inclination angle.

The evolution of deformation via the Taylor parameter $D$ (figure 16b) remains the most effective way to distinguish between the different models. As expected, the vesicle model has the most intense deformation and is completely separate from the other models. The double-layer models produce mean deformations of the same order, with an almost sinusoidal regularity of the Taylor parameter evolution. However, the stiffness provided by the surface incompressibility is reflected in an oscillation amplitude half as large for the vesicle–capsule model as for the capsule–capsule model. Although the mean deformation intensity is lower for the capsule model, its oscillation amplitude is two to three times greater than that of the capsule–capsule model, with the oscillations appearing to be much less symmetrical. We also note that there is an apparent increase in the rotation frequency when the lipid bilayer is modelled as an incompressible fluid film rather than a solid shell. However, it is difficult to conclude whether this increase is related to the consideration of the fluid nature of the lipid bilayer or to the more rigorous treatment of the surface incompressibility constraint.

Figure 17 compares the shape evolutions in the established regime with the vesicle model excluded due to its much larger deformation. The double-layer models produce very similar shapes that are relatively stable, while the capsule model undergoes strong shape variations. In cross-section in the shear plane, the evolution of the capsule model periodically changes from an elliptical to an S-shape (breathing phenomenon).

Figure 17. Shape evolution in the established tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, when the RBC's symmetry axis is initially in the shear plane. Left panel: $(x^*,y^*)$ plane sectional drawing at $t^* = 7$ (a), $t^* = 15$ (b), $t^* = 20$ (c) and $t^* = 33$ (d) (capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ). Right panel: corresponding 3-D views for capsule (left), vesicle–capsule (middle) and capsule–capsule (right).

A legitimate question is whether the transitional phase in the case where the axis of symmetry is aligned with the axis of vorticity is only a shape adaptation or whether it is accompanied by a general pivoting of the cytoskeleton. If the answer is negative, the final state reached cannot be considered completely identical to the one reached starting from the other orientation, at least from an energetic point of view. To answer this question, we tracked the $y^*$ coordinate of two markers, one initially located on the dimple in the centre of one of the two faces of the RBC and the other on the periphery. The answer is clearly negative: when the axis of symmetry is initially in the shear plane, the dimple undergoes the tank-treading movement, whereas when the axis of symmetry is initially aligned with the axis of vorticity, the marker at the periphery performs the rotation.

4.3. Effect of modelling strategy on the transition to tank treading

Our third point of investigation lies at the upper limit of the intermittency region. For an external viscosity $\eta _{ext}=24\ {\rm mPa}\ {\rm s}$, Fischer & Korzeniewski (Reference Fischer and Korzeniewski2013) identified a critical shear rate of 10 s$^{-1}$ for the transition, corresponding to a critical viscous stress of 0.24 Pa. The corresponding dimensionless numbers are $\lambda = 0.417$ and $Ca(\dot {\gamma },\mu _s) = 0.113$.

Since this point is located in the transition zone, it is expected that the models’ behaviour is particularly sensitive to the modelling strategy. This sensitivity is clearly demonstrated in figure 18. The vesicle model exhibits pure tank treading with a constant inclination angle. The capsule model, on the other hand, stays in the tumbling regime. The double-layer models initially exhibit tumbling, but after one or two periods, they adopt a permanent tank-treading dynamic. Their inclination angle oscillates around a mean value similar to that of the vesicle model, with a slightly larger amplitude for the capsule–capsule model.

Figure 18. Time evolution of the inclination angle $\theta /{\rm \pi}$ (a) and the deformation parameter $D$ (b) in the tumbling to tank-treading transition region at $\lambda = 0.417, Ca(\dot {\gamma },\mu _s) = 0.113$ (vesicle $=$ black, capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ).

4.4. Effect of modelling strategy in very high deformation regime

Mauer et al. (Reference Mauer, Mendez, Lanotte, Nicoud, Abkarian, Gompper and Fedosov2018) reported a wide range of RBC shapes and dynamics observed in their microfluidic experiments and through simulations using two distinct techniques. Notably, the multilobe regime represents conditions closely resembling the physiological environment, characterised by an external viscosity of $\eta _{ext} = 1.5\ {\rm mPa}\ {\rm s}$, at very high shear rates with $\tau = 3.19$ Pa. This corresponds to dimensionless numbers $\lambda = 6.67$ and $Ca(\dot {\gamma },\mu _s) = 1.5$. We use these simulation parameters to align with the phase diagram presented by Mauer et al. (Reference Mauer, Mendez, Lanotte, Nicoud, Abkarian, Gompper and Fedosov2018), pinpointing a specific point within this multilobe regime. As anticipated, our simulations effectively yielded multilobe shapes, indicating a strong alignment between our modelling approaches and experimental observations. It is worth noting that multilobe shapes have also been observed in a study using a two-dimensional (2-D) vesicle model (Abbasi et al. Reference Abbasi, Farutin, Nait-Ouhra, Ez-Zahraouy, Benyoussef and Misbah2022), suggesting that the cytoskeleton may not be necessary for the multilobe manifestation.

The evolution of the inclination angle and the Taylor deformation parameter is shown in figure 19. The deformation parameter varies between a minimum $D_{min}$ and a maximum $D_{max}$, resulting in different shapes depending on the modelling strategy.

Figure 19. Time evolution of the inclination angle $\theta /{\rm \pi}$ (a) and the deformation parameter $D$ (b) in the multilobe region at $\lambda = 6.67, Ca(\dot {\gamma },\mu _s) = 1.5$ (capsule $=$ , vesicle–capsule $=$ , capsule–capsule $=$ ). Inserted in (b) are $x$ and $y$ shape views for the capsule and vesicle–capsule models when $D$ is minimal and maximal.

4.5. Comparison with experimental data

In §§ 4.14.4, we intentionally selected four points within the phase diagram of an RBC in shear flow. These points were chosen to comprehensively cover the spectrum of the RBC dynamics. Across each of these chosen points, our simulations consistently replicated the anticipated shapes and dynamic responses, including the characteristic multilobe shape. These consistent agreements between our simulation results and experimental observations serve as compelling validation, affirming the effectiveness and reliability of our modelling approaches.

In this subsection, we directly compare our numerical results with existing experimental data. Specifically, we analyse the relationship between the tank-treading frequency ($\,f$) and the shear rate ($\dot {\gamma }$). Fischer (Reference Fischer2007) previously reported that the frequency scales with shear rate as $f\sim \dot {\gamma }^{\beta }$, with the scaling exponent $\beta$ in the range of 0.85 to 0.95.

Employing the same viscosity value for the suspending medium ($\eta _{ext} = 28.9\ {\rm mPa}\ {\rm s}$) as reported in Fischer (Reference Fischer2007), which leads to $\lambda = 0.346$, we conducted a series of simulations using both single-layer and double-layer models to investigate the tank-treading frequency as a function of shear rate. Figure 20 displays a comparison between our simulation results and experimental data. The results show that both single-layer and double-layer models indeed exhibit a power-law relationship with $\beta$ around 0.92. We note that our numerical results are also consistent with the results obtained by Peng et al. (Reference Peng, Li, Pivkin, Dao, Karniadakis and Suresh2013), where they reported a value of approximately 0.91 for both their one-component and two-component models. In our simulations, we assumed a quasi-spherical reference shape with non-zero spontaneous curvature. We also explored scenarios with zero spontaneous curvature, resulting in negligible deviations from the primary results.

Figure 20. The frequency ($\,f$) of the tank-treading motion of an RBC in shear flow plotted against the shear rate ($\dot {\gamma }$). Simulated results using various models are denoted by filled symbols, while experimental data from Fischer (Reference Fischer2007) are represented by open circles. An exponential fit to the numerical results ($\,f\sim \dot {\gamma }^{0.92}$) is shown as a dashed line, and a linear fit ($\,f\sim \dot {\gamma }$) is depicted by the solid line.

5. Discussion

The choice of modelling strategy, either single or double layers, appears to have a significant impact on the dynamics of the RBC in shear flow. One way to assess the significance of this impact is to compare the influence of the cytoskeleton's reference shape. Figure 21 provides such a comparison for the study point $\lambda = 0.417, Ca(\dot {\gamma },\mu _s) = 0.113$, located in the transition from tumbling to tank treading. The capsule and capsule–capsule models are compared with two alternatives of reference shape: discocyte or quasi-spherical (sphericity of $0.96$, which has already been used). For both modelling strategies, switching to the discocyte reference shape has a slight effect of reducing the oscillation frequency. Additionally, for the capsule–capsule model, a slight increase in the amplitude of the oscillations can be observed. However, for neither strategy does the influence go so far as to alter the nature of the dynamics. The capsule model remains in tumbling dynamics, while the capsule–capsule model remains in tank treading. In other words, distinguishing the cytoskeleton from the bilayer appears to have a greater impact.

Figure 21. Time evolution of the inclination angle $\theta /{\rm \pi}$ in the tumbling to tank-treading transition region at $\lambda = 0.417, Ca(\dot {\gamma },\mu _s) = 0.113$, for capsule () and capsule–capsule (), using the quasi-spherical (solid line) and discocyte (dotted line) reference shapes for the cytoskeleton.

Pushing the comparison in the tank-treading regime ($\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$), we observe a greater influence of the cytoskeleton's reference shape. The evolution curves of the inclination angle and the Taylor deformation parameter are shown in figures 22 and 23 for the two initial orientations of the RBC symmetry axis, i.e. in the shear plane or along its vorticity axis. Furthermore, the RBC shapes at $t^* = 48$ and $t^* = 52$ are compared in figure 24. Switching to the discocyte reference shape has a significant impact, inducing undeniable discrimination between the two cases of the orientation of the RBC symmetry axis. This effect is evident for both the capsule and the capsule–capsule models, but it is more pronounced for the latter. When the axis of symmetry of the RBC is initially in the shear plane, an increase in the amplitude of the oscillations of the inclination angle and the deformation parameter is observed for both models. This result is consistent with the interpretation in terms of the energy barrier required to allow tank-treading movement, which is greater for the discocyte reference shape than for the quasi-spherical one. However, when the axis of symmetry of the RBC is aligned with the axis of vorticity, this energy barrier is reduced. For the capsule model, this results in a smaller oscillation amplitude for both the angle and the deformation, with a lower average deformation intensity. However, the most significant consequence is the doubling of the oscillation frequency. In contrast, for the capsule–capsule model, the barrier effect seems to disappear completely. The inclination angle and the deformation parameter take a constant value, and the RBC switches to a pure tank-treading dynamics. However, the intensity of the deformation increases, unlike the capsule model, because of a greater influence of the dimple from the axis of symmetry towards the periphery for the more rigid capsule model. Here, the difference in modelling strategy between one or two layers still has a strong impact, but its influence combines with that of the reference shape for the cytoskeleton.

Figure 22. Impact of switching from the quasi-spherical (a,c) to the discocyte (b,d) reference shape on inclination angle in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, for capsule () and capsule–capsule (). The RBC's axis of symmetry is initially in the shear plane (solid line) or aligned with the axis of vorticity (dotted line).

Figure 23. Impact of switching from the quasi-spherical (a) to the discocyte (b) reference shape on deformation in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, for capsule () and capsule–capsule (). The RBC's axis of symmetry is initially in the shear plane (solid line) or aligned with the axis of vorticity (dotted line).

Figure 24. Shape evolution ($(x^*,y^*)$ plane sectional drawing) with the discocyte reference shape in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, for capsule () and capsule–capsule (), at $t^* = 48$ (a,c) and $t^* = 52$ (b,d). The RBC's axis of symmetry is initially in the shear plane (a,b) or aligned with the axis of vorticity (c,d).

We conducted simulations with a non-zero spontaneous curvature for the quasi-spherical reference shape. However, we do not present the corresponding curves as they are very similar to those obtained with zero spontaneous curvature.

We emphasise the significance of conducting a comparative study that minimises the discrepancies arising from specific numerical implementations, such as the method for solving flows and the geometric representation of surfaces. It is crucial for these numerical aspects to share the same level of precision. While the choice of our modelling may be subject to debate, including the numerical method and solution algorithms, our approach, built upon the relatively recent finite-element method, known as isogeometric analysis, provides a coherent and consistent numerical framework. However, the dissipative contribution of the coupling between the cytoskeleton and the lipid bilayer is not present in single-layer models. Although our study does not consider the relaxation dynamics, it is still legitimate to question the sensitivity of double-layer models to the friction coefficient $C_f$. To investigate this, we repeated simulations by varying $C_f$ by a factor of ten, but the impact was almost negligible. While it may seem surprising at first glance, the intensity of dissipation cannot be directly linked to the friction between the cytoskeleton and the lipid bilayer, since increasing the friction intensity decreases the velocity differential between the cytoskeleton and the lipid bilayer.

The double-layer models used in our study clearly differ from the single-layer capsule model. However, beyond the surface incompressibility constraint that our study has revealed, what are the fundamental differences between the capsule–capsule and vesicle–capsule models, and why is it important to model the lipid bilayer as a fluid film? A fluid nature would allow the lipid bilayer to more easily adapt to ambient fluid flow, and even exhibit vortices in the surface velocity field if the energy balance is improved. In contrast, modelling the lipid bilayer as a solid shell would make such a scenario impossible. While the tank-treading dynamics is compatible with a solid membrane and has been observed experimentally for capsules, it is unclear whether all the dynamics adopted by an RBC in a shear flow exhibits this behaviour. To investigate this further, we extended our comparison between capsule–capsule and vesicle–capsule models to multilobe dynamics ($\lambda = 6.67, Ca(\dot {\gamma }, \mu _s) = 1.5$). Figure 25 illustrates this comparison, showing comparable shapes obtained with both models when the Taylor parameter passes through its minimum. However, the vesicle–capsule model exhibits two counter-rotating vortices in the concavity, unlike the capsule–capsule model, which widens the concavity. This difference in surface flow topology may have a more significant effect on other aspects, including frictional dissipation between the cytoskeleton and lipid bilayer and the physiological role of the plasma membrane, which relies on its fluidity for proteins to diffuse widely and be easily mobilised to fulfil biological functions.

Figure 25. Surface velocity fields in the multilobe region at $\lambda = 6.67, Ca(\dot {\gamma }, \mu _s) = 1.5$, for the capsule–capsule (a) and vesicle–capsule (c) models, when $D = D_{min}$. (b,d) The corresponding surface velocity field inside the concavity projected on a plane perpendicular to the concavity.

6. Conclusions

The RBC is a commonly studied area in the field of biomechanics, and it is traditionally modelled as a single-layer capsule or vesicle. While a few double-layer models exist, they often require two separate meshes – one for the lipid bilayer and the other for the cytoskeleton. In this paper, we have presented an alternative double-layer membrane model that utilises a single mesh, significantly reducing computational complexity. Through computational assessment of different modelling strategies, including both single-layer and double-layer models, we have examined their respective effects on RBC dynamics and their potential implications in understanding the biomechanics of RBCs.

By analysing extensional flow, we have gained insight into the behaviour of the RBC membrane and why single-layer models like the capsule model and double-layer models like the capsule–capsule and vesicle–capsule models are not equivalent. The capsule model fails to distinguish the tangential kinematics of the cytoskeleton and the lipid bilayer, while in reality the latter only drives the former through the action of frictional forces of the lipids on the junction proteins. The cytoskeleton has a degree of freedom of tangential sliding, allowing it to relax its elastic stresses to an imposed surface shape, which is effective in double-layer modelling strategies but prohibited in the single-layer capsule model. As a result, our findings show that the elastic strain energy of the cytoskeleton and the RBC membrane as a whole increase more slowly in the double-layer modelling strategies during extensional flow, resulting in a non-negligible increase in the elongation of the RBC.

We aimed to investigate the influence of the interaction between the lipid bilayer and cytoskeleton layers of the RBC membrane on its dynamics in simple shear flow. To achieve this, we considered four points ($\lambda, Ca(\dot {\gamma }, \mu _s)$) of the phase diagram that corresponded to the dynamic regimes of tumbling, tank treading, transition to tank treading and multilobe-shaped RBCs under very high shear. These points were chosen because they represent the richness of RBC behaviour in shear flow while keeping the RBC symmetry axis in the shear plane. For the tank-treading dynamics, we also considered the alternative where the symmetry axis remains aligned with the vorticity axis. The modelling strategies were compared using the usual indicators of inclination angle and the Taylor deformation parameter, along with other indicators such as the shape of the RBC or the velocity field on its surface.

Our results show that modelling the RBC membrane as a single material surface or as two structures that can slide relative to each other is not equivalent. For all the study points, this difference in behaviour is always present, although it may be more or less marked depending on the nature of the dynamics considered. Our numerical methods were accurate, and any criticism of our choices would affect all RBC modelling strategies compared. The mechanical properties we considered were those recognised for a healthy RBC, but their assignment to one of the modelled components may vary depending on the strategy adopted. The sliding degree of freedom between the two layers in the double-layer models induced a dissipative phenomenon not considered in simpler models where the membrane is modelled as a block. However, we have shown that the sensitivity to the value of the surface friction coefficient is negligible, while the existence of this sliding degree of freedom is an important factor. Moreover, none of the cases we have considered involves the relaxation dynamics.

Our study has yielded a surprising finding, emphasising the significance of the membrane modelling strategy for RBCs compared with the choice of the cytoskeleton's reference shape. Our results suggest that the combination of mechanical properties alone is insufficient, and careful consideration must be given to how these properties are incorporated. While the numerical efficiency favours a single-layer capsule approach, a double-layer model aligns more closely with biological reality. Fortunately, the additional computational cost of the double-layer model is minimal when utilising a single mesh, as demonstrated in our continuum-mechanical approach. Based on all the aspects considered, we conclude that the optimal sequence of RBC modelling strategies is as follows: double-layer vesicle–capsule and capsule–capsule models, followed by single-layer capsule and vesicle models if a particular model would be preferred.

However, an open question remains: is it necessary, useful or avoidable to model the lipid bilayer as a vesicle rather than a capsule? To date, no such model has been widely adopted in the community. Our study identifies two mechanical properties contributed by the lipid bilayer: its surface incompressibility and its fluid nature. We show that the former consistently provides a marked stiffening effect compared with a quasi-incompressible capsule model, reducing up to 50 % of swinging oscillations in the tank-treading dynamics. The importance of fluidity is less clear but becomes noticeable at very high shear rates, where contra-rotating vortices appear that cannot be reproduced with a capsule model. While the physiological significance of these complex flows within the plasma membrane remains uncertain, our study suggests that considering the fluidity of the lipid bilayer is still important. However, it is not the consideration of fluidity that is expensive in a vesicle model, but rather the rigorous consideration of the incompressibility constraint through a projection method in a space of surface divergence-free velocity fields. An alternative approach that would represent a good strategy and is already widely adopted in the vesicle community is to take into account the surface incompressibility constraint using a penalty method.

Our initial motivation for conducting this study was rooted in numerical modelling concerns. However, our research has unexpectedly yielded insights that could advance our understanding of the biophysics of RBCs. One such insight is the unresolved question of the reference shape of the cytoskeleton. Our study on tank-treading dynamics has revealed a new phenomenon that could serve as an indicator in resolving this issue. Experimental research by Minetti et al. (Reference Minetti, Audemar, Podgorski and Coupier2019) suggests that, in this regime, the RBC symmetry axis can be oriented in two ways – aligned with the vorticity axis or in the shear plane. We have investigated both configurations, and our findings indicate that a reference shape close to a sphere results in indistinguishable steady-state dynamics for both orientations. However, with a discocyte reference shape, the effect is considerably different and accentuated in a double-layer model compared with a simple capsule model. The oscillation amplitude increases when the symmetry axis is in the shear plane and decreases when aligned with the vorticity axis. Notably, the oscillation frequency is halved in the latter case for the capsule model, whereas the capsule–capsule model eliminates the oscillations, leading to a pure tank-treading dynamics. These observations suggest that the influence of reference shape on oscillation frequency is significant enough to warrant experimental verification.

Another point of interest is the fluidity of the lipid bilayer, which justifies the notion of a flow of its constituents and the associated friction on proteins linked to the cytoskeleton. Recent research has called into question the Singer and Nicolson model, particularly regarding the extent to which bilayer fluidity is constrained by the aggregation kinetics of its constituents and the corralling phenomenon (Kusumi et al. Reference Kusumi, Nakada, Ritchie, Murase, Suzuki, Murakoshi, Kasai, Kondo and Fujiwara2005; Krapf Reference Krapf2015). Surface viscosity and the possibility of vortices must be considered in this context. However, the limitation on the degree of sliding freedom of the cytoskeleton may not be immediately evident, since it involves the sliding of the corrals themselves, which warrants further investigation.

Acknowledgements

The project leading to this publication has received funding from France 2030, the French Government program managed by the French National Research Agency (ANR-16-CONV-0001) and from Excellence Initiative of Aix-Marseille University – A*MIDEX. Centre de Calcul Intensif d'Aix-Marseille is acknowledged for granting access to its high performance computing resources.

Declaration of interests

The authors report no conflict of interest.

References

Abbasi, M., Farutin, A., Nait-Ouhra, A., Ez-Zahraouy, H., Benyoussef, A. & Misbah, C. 2022 Dynamics and rheology of a single two-dimensional multilobe vesicle in a confined geometry. Phys. Rev. Fluids 7 (9), 093603.CrossRefGoogle Scholar
Boedec, G., Leonetti, M. & Jaeger, M. 2011 3D vesicle dynamics simulations with a linearly triangulated surface. J. Comput. Phys. 230, 10201034.CrossRefGoogle Scholar
Boedec, G., Leonetti, M. & Jaeger, M. 2017 Isogeometric FEM-BEM simulations of drop, capsule and vesicle dynamics in Stokes flow. J. Comput. Phys. 342, 117138.CrossRefGoogle Scholar
Brust, M., et al. 2014 The plasma protein fibrinogen stabilizes clusters of red blood cells in microcapillary flows. Sci. Rep. 4 (1), 4348.CrossRefGoogle ScholarPubMed
Chang, H.-Y., Li, X. & Karniadakis, G.E. 2017 Modeling of biomechanics and biorheology of red blood cells in type 2 diabetes mellitus. Biophys. J. 113 (2), 481490.CrossRefGoogle ScholarPubMed
Chang, H.-Y., Li, X., Li, H. & Karniadakis, G.E. 2016 MD/DPD multiscale framework for predicting morphology and stresses of red blood cells in health and disease. PLoS Comput. Biol. 12 (10), e1005173.CrossRefGoogle ScholarPubMed
Cirak, F. & Ortiz, M. 2001 Fully C1-conforming subdivision elements for finite deformation thin-shell analysis. Intl J. Numer. Meth. Engng 51 (7), 813833.CrossRefGoogle Scholar
Cirak, F., Ortiz, M. & Schröder, P. 2000 Subdivision surfaces: a new paradigm for thin-shell finite-element analysis. Intl J. Numer. Meth. Engng 47 (12), 20392072.3.0.CO;2-1>CrossRefGoogle Scholar
Cottrell, J.A., Hughes, T.J.R. & Bazilevs, Y. 2009 Isogeometric Analysis: Toward Integration of CAD and FEA. Wiley.CrossRefGoogle Scholar
Dahl, J.B., Narsimhan, V., Gouveia, B., Kumar, S., Shaqfeh, E.S.G. & Muller, S.J. 2016 Experimental observation of the asymmetric instability of intermediate-reduced-volume vesicles in extensional flow. Soft Matt. 12 (16), 37873796.CrossRefGoogle ScholarPubMed
Discher, D.E., Mohandas, N. & Evans, E.A. 1994 Molecular maps of red cell deformation: hidden elasticity and in situ connectivity. Science 266 (5187), 10321035.CrossRefGoogle ScholarPubMed
Dodson, W.R. & Dimitrakopoulos, P. 2010 Tank-treading of erythrocytes in strong shear flows via a nonstiff cytoskeleton-based continuum computational modeling. Biophys. J. 99 (9), 29062916.CrossRefGoogle Scholar
Evans, E.A. & Skalak, R. 1980 Mechanics and Thermodynamics of Biomembranes, 1st edn. CRC.Google Scholar
Fedosov, D.A., Noguchi, H. & Gompper, G. 2014 Multiscale modeling of blood flow: from single cells to blood rheology. Biomech. Model. Mechanobiol. 13 (2), 239258.CrossRefGoogle ScholarPubMed
Fischer, T.M. 1992 Is the surface area of the red cell membrane skeleton locally conserved? Biophys. J. 61 (2), 298305.CrossRefGoogle ScholarPubMed
Fischer, T.M. 2007 Tank-tread frequency of the red cell membrane: dependence on the viscosity of the suspending medium. Biophys. J. 93 (7), 25532561.CrossRefGoogle ScholarPubMed
Fischer, T.M. & Korzeniewski, R. 2013 Threshold shear stress for the transition between tumbling and tank-treading of red blood cells in shear flow: dependence on the viscosity of the suspending medium. J. Fluid Mech. 736, 351365.CrossRefGoogle Scholar
Freund, J.B. 2014 Numerical simulation of flowing blood cells. Annu. Rev. Fluid Mech. 46 (1), 6795.CrossRefGoogle Scholar
Gounley, J., Boedec, G., Jaeger, M. & Leonetti, M. 2016 Influence of surface viscosity on droplets in shear flow. J. Fluid Mech. 791, 464494.CrossRefGoogle Scholar
Gounley, J. & Peng, Y. 2015 Computational modeling of membrane viscosity of red blood cells. Commun. Comput. Phys. 17 (4), 10731087.CrossRefGoogle Scholar
Guglietta, F., Behr, M., Biferale, L., Falcucci, G. & Sbragaglia, M. 2020 On the effects of membrane viscosity on transient red blood cell dynamics. Soft Matt. 16 (26), 61916205.CrossRefGoogle ScholarPubMed
Hansen, J.C., Skalak, R., Chien, S. & Hoger, A. 1996 An elastic network model based on the structure of the red blood cell membrane skeleton. Biophys. J. 70 (1), 146166.CrossRefGoogle ScholarPubMed
Hoore, M., Yaya, F., Podgorski, T., Wagner, C., Gompper, G. & Fedosov, D.A. 2018 Effect of spectrin network elasticity on the shapes of erythrocyte doublets. Soft Matt. 14 (30), 62786289.CrossRefGoogle ScholarPubMed
Jeffery, G.B. 1922 The motion of ellipsoidal particles immersed in a viscous fluid. Proc. R. Soc. Lond. A 102 (715), 161179.Google Scholar
Kabacaoğlu, G. & Biros, G. 2019 Sorting same-size red blood cells in deep deterministic lateral displacement devices. J. Fluid Mech. 859, 433475.CrossRefGoogle Scholar
Kantsler, V., Segre, E. & Steinberg, V. 2007 Vesicle dynamics in time-dependent elongation flow: wrinkling instability. Phys. Rev. Lett. 99 (17), 178102.CrossRefGoogle ScholarPubMed
Kantsler, V., Segre, E. & Steinberg, V. 2008 Critical dynamics of vesicle stretching transition in elongational flow. Phys. Rev. Lett. 101 (4), 048101.CrossRefGoogle ScholarPubMed
Késmárky, G., Kenyeres, P., Rábai, M. & Tóth, K. 2008 Plasma viscosity: a forgotten variable. Clin. Hemorheol. Microcirc. 39, 243246.CrossRefGoogle ScholarPubMed
Kim, Y., Kim, K. & Park, Y. 2012 Measurement techniques for red blood cell deformability: recent advances. In Blood Cell – An Overview of Studies in Hematology (ed. T. Moschandreou). InTech.CrossRefGoogle Scholar
Krapf, D. 2015 Mechanisms underlying anomalous diffusion in the plasma membrane. In Lipid Domains (ed. A.K. Kenworthy), Current Topics in Membranes, vol. 75, pp. 167–207. Academic.CrossRefGoogle Scholar
Krishnaswamy, S. 1996 A cosserat-type model for the red blood cell wall. Intl J. Engng Sci. 34 (8), 873899.CrossRefGoogle Scholar
Kusumi, A., Nakada, C., Ritchie, K., Murase, K., Suzuki, K., Murakoshi, H., Kasai, R.S., Kondo, J. & Fujiwara, T. 2005 Paradigm shift of the plasma membrane concept from the two-dimensional continuum fluid to the partitioned fluid: high-speed single-molecule tracking of membrane molecules. Annu. Rev. Biophys. Biomol. 34 (1), 351378.CrossRefGoogle Scholar
Lenormand, G., Hénon, S., Richert, A., Siméon, J. & Gallet, F. 2001 Direct measurement of the area expansion and shear moduli of the human red blood cell membrane skeleton. Biophys. J. 81 (1), 4356.CrossRefGoogle ScholarPubMed
Lenormand, G., Hénon, S., Richert, A., Siméon, J. & Gallet, F. 2003 Elasticity of the human red blood cell skeleton. J. Biorheol. 40, 247251.Google ScholarPubMed
Levant, M. & Steinberg, V. 2016 Intermediate regime and a phase diagram of red blood cell dynamics in a linear flow. Phys. Rev. E 94 (6), 062412.CrossRefGoogle Scholar
Li, X., Lu, H. & Peng, Z. 2018 Continuum- and particle-based modeling of human red blood cells. In Handbook of Materials Modeling (ed. W. Andreoni & S. Yip), pp. 1–17. Springer International Publishing.CrossRefGoogle Scholar
Li, X, Peng, Z., Lei, H., Dao, M. & Karniadakis, G.E. 2014 Probing red blood cell mechanics, rheology and dynamics with a two-component multi-scale model. Phil. Trans. A Math. Phys. Engng Sci. 372 (2021), 20130389.Google ScholarPubMed
Li, X., Vlahovska, P.M. & Karniadakis, G.E. 2013 Continuum- and particle-based modeling of shapes and dynamics of red blood cells in health and disease. Soft Matt. 9 (1), 2837.CrossRefGoogle ScholarPubMed
Loop, C.T. 1987 Smooth subdivision surfaces based on triangles. Master's thesis, The University of Utah.Google Scholar
Lu, H. & Peng, Z. 2019 Boundary integral simulations of a red blood cell squeezing through a submicron slit under prescribed inlet and outlet pressures. Phys. Fluids 31 (3), 031902.CrossRefGoogle Scholar
Lu, L., Morse, M.J., Rahimian, A., Stadler, G. & Zorin, D. 2019 Scalable simulation of realistic volume fraction red blood cell flows through vascular networks. In Proceedings of the International Conference for High Performance Computing, Networking, Storage and Analysis, pp. 1–30. ACM.CrossRefGoogle Scholar
Lyu, J., Chen, P.G., Boedec, G., Leonetti, M. & Jaeger, M. 2018 Hybrid continuum–coarse-grained modeling of erythrocytes. C. R. Méc 346 (6), 439448.CrossRefGoogle Scholar
Lyu, J.M., Chen, P.G., Boedec, G., Leonetti, M. & Jaeger, M. 2021 An isogeometric boundary element method for soft particles flowing in microfluidic channels. Comput. Fluids 214, 104786.CrossRefGoogle Scholar
Mauer, J., Mendez, S., Lanotte, L., Nicoud, F., Abkarian, M., Gompper, G. & Fedosov, D.A. 2018 Flow-induced transitions of red blood cell shapes under shear. Phys. Rev. Lett. 121 (11), 118103.CrossRefGoogle ScholarPubMed
McWhirter, J.L., Noguchi, H. & Gompper, G. 2011 Deformation and clustering of red blood cells in microcapillary flows. Soft Matt. 7 (22), 10967.CrossRefGoogle Scholar
Mendez, S. & Abkarian, M. 2018 In-plane elasticity controls the full dynamics of red blood cells in shear flow. Phys. Rev. Fluids 3 (10), 101101.CrossRefGoogle Scholar
Minetti, C., Audemar, V., Podgorski, T. & Coupier, G. 2019 Dynamics of a large population of red blood cells under shear flow. J. Fluid Mech. 864, 408448.CrossRefGoogle Scholar
Mohandas, N. & Evans, E. 1994 Mechanical properties of the red cell membrane in relation to molecular structure and genetic defects. Annu. Rev. Biophys. Biomol. 23 (1), 787818.CrossRefGoogle ScholarPubMed
Mohandas, N. & Gallagher, P.G. 2008 Red cell membrane: past, present, and future. Blood 112 (10), 39393948.CrossRefGoogle ScholarPubMed
Narsimhan, V., Spann, A.P. & Shaqfeh, E.S.G. 2014 The mechanism of shape instability for a vesicle in extensional flow. J. Fluid Mech. 750, 144190.CrossRefGoogle Scholar
Noguchi, H. & Gompper, G. 2005 Shape transitions of fluid vesicles and red blood cells in capillary flows. Proc. Natl Acad. Sci. USA 102 (40), 1415914164.CrossRefGoogle ScholarPubMed
Omori, T., Ishikawa, T., Barthès-Biesel, D., Salsac, A.-V., Walter, J., Imai, Y. & Yamaguchi, T. 2011 Comparison between spring network models and continuum constitutive laws: application to the large deformation of a capsule in shear flow. Phys. Rev. E 83 (4), 041918.CrossRefGoogle Scholar
Peng, Z., Asaro, R.J. & Zhu, Q. 2010 Multiscale simulation of erythrocyte membranes. Phys. Rev. E 81 (3), 031904.CrossRefGoogle ScholarPubMed
Peng, Z., Asaro, R.J. & Zhu, Q. 2011 Multiscale modelling of erythrocytes in Stokes flow. J. Fluid Mech. 686, 299337.CrossRefGoogle Scholar
Peng, Z., Chen, Y.-L., Lu, H., Pan, Z. & Chang, H.-C. 2015 a Mesoscale simulations of two model systems in biophysics: from red blood cells to DNAs. Comput. Part. Mech. 2 (4), 339357.CrossRefGoogle Scholar
Peng, Z., Li, X., Pivkin, I.V., Dao, M., Karniadakis, G.E. & Suresh, S. 2013 Lipid bilayer and cytoskeletal interactions in a red blood cell. Proc. Natl Acad. Sci. USA 110 (33), 1335613361.CrossRefGoogle Scholar
Peng, Z., Mashayekh, A. & Zhu, Q. 2014 Erythrocyte responses in low-shear-rate flows: effects of non-biconcave stress-free state in the cytoskeleton. J. Fluid Mech. 742, 96118.CrossRefGoogle Scholar
Peng, Z., Salehyar, S. & Zhu, Q. 2015 b Stability of the tank treading modes of erythrocytes and its dependence on cytoskeleton reference states. J. Fluid Mech. 771, 449467.CrossRefGoogle Scholar
Peng, Z. & Zhu, Q. 2013 Deformation of the erythrocyte cytoskeleton in tank treading motions. Soft Matt. 9 (31), 7617.CrossRefGoogle Scholar
Pivkin, I.V., Peng, Z., Karniadakis, G.E., Buffet, P.A., Dao, M. & Suresh, S. 2016 Biomechanics of red blood cells in human spleen and consequences for physiology and disease. Proc. Natl Acad. Sci. USA 113 (28), 78047809.CrossRefGoogle ScholarPubMed
Pozrikidis, C. 1992 Boundary Integral and Singularity Methods for Linearized Viscous Flow. Cambridge Texts in Applied Mathematics, vol. 7. Cambridge University Press.CrossRefGoogle Scholar
Pozrikidis, C. 2002 A Practical Guide to Boundary Element Methods with the Software Library BEMLIB. Chapman & Hall/CRC.CrossRefGoogle Scholar
Prado, G., Farutin, A., Misbah, C. & Bureau, L. 2015 Viscoelastic transient of confined red blood cells. Biophys. J. 108 (9), 21262136.CrossRefGoogle ScholarPubMed
Salehyar, S. & Zhu, Q. 2016 Deformation and internal stress in a red blood cell as it is driven through a slit by an incoming flow. Soft Matt. 12 (13), 31563164.CrossRefGoogle Scholar
Sigüenza, J., Mendez, S. & Nicoud, F. 2017 How should the optical tweezers experiment be used to characterize the red blood cell membrane mechanics? Biomech. Model. Mechanobiol. 16 (5), 16451657.CrossRefGoogle ScholarPubMed
Skalak, R., Tozeren, A., Zarda, R.P. & Chien, S. 1973 Strain energy function of red blood cell membranes. Biophys. J. 13 (3), 245264.CrossRefGoogle ScholarPubMed
Tsubota, K. 2014 Short note on the bending models for a membrane in capsule mechanics: comparison between continuum and discrete models. J. Comput. Phys. 277, 320328.CrossRefGoogle Scholar
Tsubota, K. 2021 Elongation deformation of a red blood cell under shear flow as stretch testing. J. Mech. Phys. Solids 152, 104345.CrossRefGoogle Scholar
Vlahovska, P.M., Barthes-Biesel, D. & Misbah, C. 2013 Flow dynamics of red blood cells and their biomimetic counterparts. C. R. Phys. 14 (6), 451458.CrossRefGoogle Scholar
Williams, A.R. & Morris, D.R. 2009 The internal viscosity of the human erythrocyte may determine its lifespan in vivo. Scand. J. Haematol. 24 (1), 5762.CrossRefGoogle Scholar
Yazdani, A. & Bagchi, P. 2013 Influence of membrane viscosity on capsule dynamics in shear flow. J. Fluid Mech. 718, 569595.CrossRefGoogle Scholar
Zhang, Y., Huang, C., Kim, S., Golkaram, M., Dixon, M.W.A., Tilley, L., Li, J., Zhang, S. & Suresh, S. 2015 Multiple stiffening effects of nanoscale knobs on human red blood cells infected with Plasmodium falciparum malaria parasite. Proc. Natl Acad. Sci. USA 112 (19), 60686073.CrossRefGoogle ScholarPubMed
Zhao, H. & Shaqfeh, E.S.G. 2013 The shape stability of a lipid vesicle in a uniaxial extensional flow. J. Fluid Mech. 719, 345361.CrossRefGoogle Scholar
Zhu, Q., Salehyar, S., Cabrales, P. & Asaro, R.J. 2017 Prospects for human erythrocyte skeleton-bilayer dissociation during splenic flow. Biophys. J. 113 (4), 900912.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Schematic representation of the RBC models illustrating the relevant surface force densities on the respective layers. (a) Single-layer vesicle model with out-of-plane elasticity ($\boldsymbol {f}^{e\perp }$) and surface incompressibility ($\boldsymbol {f}^{\gamma }$). (b) Single-layer capsule model with in-plane ($\boldsymbol {f}^{e\parallel }$) and out-of-plane elasticities (surface incompressibility is approximatively considered). (c) Double-layer vesicle–capsule model with in-plane and out-of-plane elasticities, along with surface incompressibility. (d) Double-layer capsule–capsule model with in-plane and out-of-plane elasticities (surface incompressibility is approximatively considered). All models employ a single mesh, with the distinction that, in double-layer models, $\boldsymbol {v}^{BL} \neq \boldsymbol {v}^{SC}$ due to the differing assumed tangential kinematics of the two layers.

Figure 1

Table 1. Mechanical properties.

Figure 2

Figure 2. Shape evolution in the ($x^*, y^*$) plane perpendicular to the stretching direction for the axisymmetric extensional flow (capsule $=$, vesicle–capsule $=$, capsule–capsule $=$), for $t^* = 0$ ((a) initial shape – plotted in hereafter), $1$ (b), $3$ (c) and $6$ (d).

Figure 3

Figure 3. Shape evolution in the ($x^*,z^*$) stretch plane for the axisymmetric extensional flow (capsule $=$, vesicle–capsule $=$, capsule–capsule $=$), for $t^* = 0$ ((a) initial shape), $1$ (b), $3$ (c) and $6$ (d).

Figure 4

Figure 4. Shape evolution in the ($y^*,z^*$) stretch plane for the axisymmetric extensional flow (capsule $=$, vesicle–capsule $=$, capsule–capsule = ), for $t^* = 0$ ((a) initial shape), $1$ (b), $3$ (c) and $6$ (d).

Figure 5

Figure 5. Decrease of the sliding velocity $\delta {\boldsymbol {v}}^*=\boldsymbol {v}^{*BL} - \boldsymbol {v}^{*SC}$ for $t^*=1$, 2 and $6$ for the axisymmetric extensional flow (vesicle–capsule $=$, capsule–capsule $=$), as a function of $x^*$ in the ($x^*,y^*$) plane (a) and of $z^*$ in the ($y^*,z^*$) plane (b).

Figure 6

Figure 6. Relative cytoskeleton area change (represented by the colour code between $-0.25$ in blue and $0.25$ in red) for the axisymmetric extensional flow at $t^* = 6$. $C^{SK} = 80$ for the capsule model (a) and $C^{SK} = 2$ for the capsule representing the cytoskeleton in the vesicle–capsule model (b) and capsule–capsule model (c).

Figure 7

Figure 7. Elastic deformation energy ($\mathcal {W}^{BL}+\mathcal {W}^{SC}$) as a function of the RBC elongation, given by the normalised position of the RBC's tip $z^*_{max}$ at normalised time $t^*$ (capsule $=$, vesicle–capsule $=$, capsule–capsule $=$). Solid lines: total elastic energy (lipid bilayer $+$ cytoskeleton). Dashed lines: bending energy contribution ($\mathcal {W}^{H}$).

Figure 8

Figure 8. Schematic representation of the shear flow configuration (($x, y, z$) frame) with an RBC (($X, Y, Z$) frame). The angle $\phi$ is the orbit angle, i.e. the angle between the vorticity axis of the flow ($z$ axis) and the symmetry axis of the particle ($Z$ axis). The angle $\theta$ is the inclination angle between the direction of the velocity gradient ($y$ axis) and the projection in the shear plane of the particle's axis of symmetry ($Z$ axis).

Figure 9

Figure 9. (a) Time evolution of the inclination angles $\theta /{\rm \pi}$ in tumbling regime at $\lambda = 6.67, Ca(\dot {\gamma },\mu _s) = 5\times 10^{-3}$. Points: simulations (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$). Solid lines: Jeffery's theory (second equation of (4.1a,b)) for fitted $r$ on frequency criteria ($r = 2.25$ for capsule, $r = 2.35$ for vesicle–capsule, $r = 2.46$ for capsule–capsule and $r = 4.15$ for vesicle). (b) Time evolution of the deformation parameter $D$.

Figure 10

Figure 10. Shape evolutions ($(x^*,y^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transient phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), for the case when the RBC's symmetry axis is initially aligned with the axis of vorticity (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$).

Figure 11

Figure 11. Shape evolutions ($(y^*,z^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transient phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), for the case when the RBC's symmetry axis is initially aligned with the axis of vorticity (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$).

Figure 12

Figure 12. Shapes (3-D view) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transient phase at $t^* = 11$, for the case when the RBC's symmetry axis is initially aligned with the axis of vorticity. (a) Vesicle, (b) capsule, (c) vesicle–capsule, (d) capsule–capsule.

Figure 13

Figure 13. Shape evolutions ($(x^*,y^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transition phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), when the RBC's symmetry axis is in the shear plane at the start (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$).

Figure 14

Figure 14. Shape evolutions ($(y^*,z^*)$ plane sectional drawing) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transition phase at $t^* = 0$ (a), $t^* = 6$ (b), $t^* = 11$ (c) and $t^* = 15$ (d), when the RBC's symmetry axis is in the shear plane at the start (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$).

Figure 15

Figure 15. Shapes (3-D view) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$ in the transition phase at $t^* = 15$, when the RBC's symmetry axis is in the shear plane at the start (a) vesicle, (b) capsule, (c) vesicle–capsule, (d) capsule–capsule.

Figure 16

Figure 16. Time evolution of the inclination angle $\theta /{\rm \pi}$ (a) and the deformation parameter $D$ (b) in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, when the RBC's symmetry axis is initially in the shear plane (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$).

Figure 17

Figure 17. Shape evolution in the established tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, when the RBC's symmetry axis is initially in the shear plane. Left panel: $(x^*,y^*)$ plane sectional drawing at $t^* = 7$ (a), $t^* = 15$ (b), $t^* = 20$ (c) and $t^* = 33$ (d) (capsule $=$, vesicle–capsule $=$, capsule–capsule $=$). Right panel: corresponding 3-D views for capsule (left), vesicle–capsule (middle) and capsule–capsule (right).

Figure 18

Figure 18. Time evolution of the inclination angle $\theta /{\rm \pi}$ (a) and the deformation parameter $D$ (b) in the tumbling to tank-treading transition region at $\lambda = 0.417, Ca(\dot {\gamma },\mu _s) = 0.113$ (vesicle $=$ black, capsule $=$, vesicle–capsule $=$, capsule–capsule $=$).

Figure 19

Figure 19. Time evolution of the inclination angle $\theta /{\rm \pi}$ (a) and the deformation parameter $D$ (b) in the multilobe region at $\lambda = 6.67, Ca(\dot {\gamma },\mu _s) = 1.5$ (capsule $=$, vesicle–capsule $=$, capsule–capsule $=$). Inserted in (b) are $x$ and $y$ shape views for the capsule and vesicle–capsule models when $D$ is minimal and maximal.

Figure 20

Figure 20. The frequency ($\,f$) of the tank-treading motion of an RBC in shear flow plotted against the shear rate ($\dot {\gamma }$). Simulated results using various models are denoted by filled symbols, while experimental data from Fischer (2007) are represented by open circles. An exponential fit to the numerical results ($\,f\sim \dot {\gamma }^{0.92}$) is shown as a dashed line, and a linear fit ($\,f\sim \dot {\gamma }$) is depicted by the solid line.

Figure 21

Figure 21. Time evolution of the inclination angle $\theta /{\rm \pi}$ in the tumbling to tank-treading transition region at $\lambda = 0.417, Ca(\dot {\gamma },\mu _s) = 0.113$, for capsule () and capsule–capsule (), using the quasi-spherical (solid line) and discocyte (dotted line) reference shapes for the cytoskeleton.

Figure 22

Figure 22. Impact of switching from the quasi-spherical (a,c) to the discocyte (b,d) reference shape on inclination angle in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, for capsule () and capsule–capsule (). The RBC's axis of symmetry is initially in the shear plane (solid line) or aligned with the axis of vorticity (dotted line).

Figure 23

Figure 23. Impact of switching from the quasi-spherical (a) to the discocyte (b) reference shape on deformation in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, for capsule () and capsule–capsule (). The RBC's axis of symmetry is initially in the shear plane (solid line) or aligned with the axis of vorticity (dotted line).

Figure 24

Figure 24. Shape evolution ($(x^*,y^*)$ plane sectional drawing) with the discocyte reference shape in tank-treading regime at $\lambda = 0.4, Ca(\dot {\gamma },\mu _s) = 0.5$, for capsule () and capsule–capsule (), at $t^* = 48$ (a,c) and $t^* = 52$ (b,d). The RBC's axis of symmetry is initially in the shear plane (a,b) or aligned with the axis of vorticity (c,d).

Figure 25

Figure 25. Surface velocity fields in the multilobe region at $\lambda = 6.67, Ca(\dot {\gamma }, \mu _s) = 1.5$, for the capsule–capsule (a) and vesicle–capsule (c) models, when $D = D_{min}$. (b,d) The corresponding surface velocity field inside the concavity projected on a plane perpendicular to the concavity.