Dynamics of a vesicle in general flow

Deschamps, Julien; Kantsler, Vasily; Segre, Enrico; Steinberg, Victor

doi:10.1073/pnas.0902657106

Cited by 112 publications

(135 citation statements)

References 27 publications

(62 reference statements)

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“…(4) becomes Jeffery's equation [62] for solid ellipsoidal objects, where φ is kept in the original position. These results show good agreement with recent experiments of lipid vesicles [7][8][9].…”

Section: A Fluid Vesiclesupporting

confidence: 93%

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Dynamic modes of microcapsules in steady shear flow: Effects of bending and shear elasticities

Noguchi

2010

Phys. Rev. E

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The dynamics of microcapsules in steady shear flow was studied using a theoretical approach based on three variables: The Taylor deformation parameter αD, the inclination angle θ, and the phase angle φ of the membrane rotation. It is found that the dynamic phase diagram shows a remarkable change with an increase in the ratio of the membrane shear and bending elasticities. A fluid vesicle (no shear elasticity) exhibits three dynamic modes: (i) Tank-treading (TT) at low viscosity ηin of internal fluid (αD and θ relaxes to constant values), (ii) Tumbling (TB) at high ηin (θ rotates), and (iii) Swinging (SW) at middle ηin and high shear rateγ (θ oscillates). All of three modes are accompanied by a membrane (φ) rotation. For microcapsules with low shear elasticity, the TB phase with no φ rotation and the coexistence phase of SW and TB motions are induced by the energy barrier of φ rotation. Synchronization of φ rotation with TB rotation or SW oscillation occurs with integer ratios of rotational frequencies. At high shear elasticity, where a saddle point in the energy potential disappears, intermediate phases vanish, and either φ or θ rotation occurs. This phase behavior agrees with recent simulation results of microcapsules with low bending elasticity.

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Section: A Fluid Vesiclesupporting

confidence: 93%

“…Recently, the dynamics of lipid vesicles in steady shear flow was intensively investigated [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22]. A lipid vesicle can be considered as a microcapsule in the small limit of the shear modulus µ → 0.…”

Section: Introductionmentioning

confidence: 99%

Dynamic modes of microcapsules in steady shear flow: Effects of bending and shear elasticities

Noguchi

2010

Phys. Rev. E

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“…see [11,28,53,16]. It has also been reported recently that a time-dependent flow with a switch in the direction of the velocity gradient can also lead to bud formation [6]. Here our flow field is far more complicated than the elongation flow.…”

Section: 3mentioning

confidence: 67%

“…Finken and Seifert [18] performed a mathematical analysis and derived analytical results both for the threshold value of the shear rate and for the critical wavelength of the wrinkling. Kantsler et al also found that vesicle wrinkling may occur in time-dependent elongation flow [19,6]. It has been suggested that the winkling phenomena are related to the dynamical instability induced by negative surface tension of the membrane [20].…”

Section: Introductionmentioning

confidence: 99%

“…As the principal components of living organisms, membranes contain a mixture of materials including lipids, proteins, and cholesterols that may decompose into coexisting domains of different phases [1,2,3]. To facilitate their biological functions such as solute and chemical transport [4], membranes interact with their fluid surroundings in surprising ways and exhibit rich shape transition behaviors [5,6]. At the continuum level, the mathematical description of morphological changes due to these coupled physical phenomena poses a highly challenging nonlinear moving boundary problem.…”

Section: Introductionmentioning

confidence: 99%

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Locomotion, wrinkling, and budding of a multicomponent vesicle in viscous fluids

Lowengrub

Voigt

2012

Communications in Mathematical Sciences

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Abstract. Recent experimental results on giant unilamellar vesicles (GUVs) show that mixed multiple lipid components on the surface of a membrane may decompose into coexisting phases with distinct compositions, with concomitant changes in the surface morphology. The driving forces for the evolution involves bending, line tension along the phase boundaries, inhomogeneous surface energy, and fluid forces. Here we are interested in exploring the emergent morphologies when the flow is present, and in particular when the surface tensions of the coexisting phases are different, which has not been considered previously. In this paper, we present a model capable of describing the nonlinear coupling among flow, membrane morphology, and the evolution of the surface phases. Using an energy variation approach, we derive a generalized surface tension and construct a constitutive equation connecting the surface tension and the phase variables. To investigate the nonlinear dynamics, we develop a numerical method that combines the immersed interface method to solve the flow equations, the level-set method to capture the interface motion, a non-stiff Eulerian algorithm to solve the phase field equations on the evolving surface, and a penalty term that enforces global inextensibility. Our numerical results suggest that the nonhomogeneous surface tension, together with the flow, introduces nontrivial vesicle dynamics including locomotion, wrinkling, and budding.

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Microfluidic Handling and Analysis of Giant Vesicles for Use as Artificial Cells: A Review

Robinson

2019

Adv. Biosys.

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One of the goals of synthetic biology is the bottom‐up construction of an artificial cell, the successful realization of which could shed light on how cellular life emerged and could also be a useful tool for studying the function of modern cells. Using liposomes as biomimetic containers is particularly promising because lipid membranes are biocompatible and much of the required machinery can be reconstituted within them. Giant lipid vesicles have been used extensively in other fields such as biophysics and drug discovery, but their use as artificial cells has only recently seen an increase. Despite the prevalence of giant vesicles, many experiments remain challenging or impossible due to their delicate nature compared to biological cells. This review aims to highlight the effectiveness of microfluidic technologies in handling and analyzing giant vesicles. The advantages and disadvantages of different microfluidic approaches and what new insights can be gained from various applications are introduced. Finally, future directions are discussed in which the unique combination of microfluidics and giant lipid vesicles can push forward the bottom‐up construction of artificial cells.

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Dynamics of a vesicle in general flow

Cited by 112 publications

References 27 publications

Dynamic modes of microcapsules in steady shear flow: Effects of bending and shear elasticities

Dynamic modes of microcapsules in steady shear flow: Effects of bending and shear elasticities

Locomotion, wrinkling, and budding of a multicomponent vesicle in viscous fluids

Microfluidic Handling and Analysis of Giant Vesicles for Use as Artificial Cells: A Review

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