International audienceThe distribution of Red Blood Cells in a confined channel flow is inhomogeneous and shows a marked depletion near the walls due to a competition between migration away from the walls and shear-induced diffusion resulting from interactions between particles. We investigated the lift of RBCs in a shear flow near a wall and measured a significant lift velocity despite the tumbling motion of cells. We also provide values for the collective and anisotropic shear-induced diffusion of a cloud of RBCs, both in the direction of shear and in the direction of vorticity. A generic down-gradient subdiffusion characterized by an exponent 1/3 is highlighted
The rheology of dense red blood cell suspensions is investigated via computer simulations based on t...
International audienceThe problem of understanding the movement of red blood cells (RBCs) is at the ...
\u3cp\u3eDriven or active suspensions can display fascinating collective behavior, where coherent mo...
International audienceIn this work, we compared the dynamics of motion in a linear shear flow of ind...
Blood is a complex suspension of deformable particles, red blood cells, which exhibits a sophisticat...
International audienceThe lateral migration of red blood cells (RBCs) in confined channel flows is a...
In blood microvessels, the finite size of the red blood cell relative to the vessel diameter gives r...
Blood is a complex suspension of deformable particles, red blood cells, which exhibits a sophisticat...
Tank-treading (TT) motion is established in optically trapped, live red blood cells (RBCs) held in s...
The transport of cells and substances in dense suspensions like blood heavily depends on the microst...
Red blood cell (RBC) migration effects and RBC–plasma interactions occurring in microvessel blood fl...
Blood viscosity decreases with shear stress, a property essential for an efficient perfusion of the ...
AbstractTank-treading (TT) motion is established in optically trapped, live red blood cells (RBCs) h...
An exhaustive description of the dynamics under shear flow of a large number of red blood cells in a...
We study the flow properties of red blood cells in confined channels, when the channel width is comp...
The rheology of dense red blood cell suspensions is investigated via computer simulations based on t...
International audienceThe problem of understanding the movement of red blood cells (RBCs) is at the ...
\u3cp\u3eDriven or active suspensions can display fascinating collective behavior, where coherent mo...
International audienceIn this work, we compared the dynamics of motion in a linear shear flow of ind...
Blood is a complex suspension of deformable particles, red blood cells, which exhibits a sophisticat...
International audienceThe lateral migration of red blood cells (RBCs) in confined channel flows is a...
In blood microvessels, the finite size of the red blood cell relative to the vessel diameter gives r...
Blood is a complex suspension of deformable particles, red blood cells, which exhibits a sophisticat...
Tank-treading (TT) motion is established in optically trapped, live red blood cells (RBCs) held in s...
The transport of cells and substances in dense suspensions like blood heavily depends on the microst...
Red blood cell (RBC) migration effects and RBC–plasma interactions occurring in microvessel blood fl...
Blood viscosity decreases with shear stress, a property essential for an efficient perfusion of the ...
AbstractTank-treading (TT) motion is established in optically trapped, live red blood cells (RBCs) h...
An exhaustive description of the dynamics under shear flow of a large number of red blood cells in a...
We study the flow properties of red blood cells in confined channels, when the channel width is comp...
The rheology of dense red blood cell suspensions is investigated via computer simulations based on t...
International audienceThe problem of understanding the movement of red blood cells (RBCs) is at the ...
\u3cp\u3eDriven or active suspensions can display fascinating collective behavior, where coherent mo...