about
Mechanical response of red blood cells entering a constriction.Mechanical perturbations trigger endothelial nitric oxide synthase activity in human red blood cells.Multiscale approach to link red blood cell dynamics, shear viscosity, and ATP release.Full dynamics of a red blood cell in shear flow.Sorting cells by their dynamical properties.A novel two-layer, coupled finite element approach for modeling the nonlinear elastic and viscoelastic behavior of human erythrocytes.A multiscale red blood cell model with accurate mechanics, rheology, and dynamics.Bedside practice of blood transfusion in a large teaching hospital in Uganda: An observational study.Tank-treading of erythrocytes in strong shear flows via a nonstiff cytoskeleton-based continuum computational modeling.Retrospective and Prospective Investigations about "Quatrefoil" Erythrocytes in Canine Blood SmearsTank treading of optically trapped red blood cells in shear flowOscillatory tank-treading motion of erythrocytes in shear flows.Tank-treading of swollen erythrocytes in shear flows.Biconcave shape of human red-blood-cell ghosts relies on density differences between the rim and dimple of the ghost's plasma membrane.Spatially variant red blood cell crenation in alternating current non-uniform fields.Mechanics and computational simulation of blood flow in microvessels.Multiscale modeling of blood flow: from single cells to blood rheology.Red blood cell: from its mechanics to its motion in shear flow.Prospects for Human Erythrocyte Skeleton-Bilayer Dissociation during Splenic Flow.Computational Biomechanics of Human Red Blood Cells in Hematological Disorders.Intermediate regime and a phase diagram of red blood cell dynamics in a linear flow.Local membrane length conservation in two-dimensional vesicle simulation using a multicomponent lattice Boltzmann equation method.Computational biorheology of human blood flow in health and diseaseRed blood cell membrane fluctuations and shape controlled by ATP-induced cytoskeletal defects.A simple model to understand the effect of membrane shear elasticity and stress-free shape on the motion of red blood cells in shear flow.Angle of inclination of tank-treading red cells: dependence on shear rate and suspending medium.Motion of red blood cells near microvessel walls: effects of a porous wall layer.Mechanical diagnosis of human erythrocytes by ultra-high speed manipulation unraveled critical time window for global cytoskeletal remodeling.Dynamic deformation and recovery response of red blood cells to a cyclically reversing shear flow: Effects of frequency of cyclically reversing shear flow and shear stress level.Effect of the natural state of an elastic cellular membrane on tank-treading and tumbling motions of a single red blood cell.Dynamics and rheology of a dilute suspension of vesicles: higher-order theory.Image-based model of the spectrin cytoskeleton for red blood cell simulation.Simulation of Deformation and Aggregation of Two Red Blood Cells in a Stenosed Microvessel by Dissipative Particle Dynamics.Creep and stress relaxation of human red cell membrane.Deformation and internal stress in a red blood cell as it is driven through a slit by an incoming flow.Dynamics of a single red blood cell in simple shear flow.Elastic behavior of a red blood cell with the membrane's nonuniform natural state: equilibrium shape, motion transition under shear flow, and elongation during tank-treading motion.Tension of red blood cell membrane in simple shear flow.Lateral migration and equilibrium shape and position of a single red blood cell in bounded Poiseuille flows.Reversibility of red blood cell deformation.
P2860
Q27332346-B9B00103-218B-4508-8099-1F17DE10A1B4Q27348997-6D912DA7-0350-44CC-828B-67C834073835Q30502249-D587F7E6-27BD-4F57-B4D1-189F107F73A6Q30530564-B7A4B135-A4A2-473C-BF0A-DF7068B4486CQ30818995-FFE7480B-04D5-4387-8F49-4258F558AF63Q33667014-CB98B387-2BE9-4F08-8A81-B8FC92B08718Q33858367-FEF96932-AAD9-4AF2-A494-BE59E10A8F78Q34061623-B072F1C5-96E7-4FDB-A520-8F70BE46C385Q34250841-F0FAF5EB-E9A6-42D4-A88F-5CEA6F5C21C9Q35089746-F3818A3E-380A-4876-B2C0-9A9D9DC58345Q35246351-8E76FD99-2DE9-4891-B0CF-555094673084Q36683392-0CC57896-6586-43DD-962F-EC31172E5583Q36746199-62ECCB1A-C3FF-47AE-9E59-EDA37AE617B9Q37534231-B74ED977-9F9E-48AB-BEDB-FF6F6A1C0557Q37688721-1F8EFD29-B001-4169-9895-036EEAB0D577Q37805167-94023B30-D8F3-453E-BD47-901E50A742E5Q38106647-F1BD16BB-11C2-412D-B806-603B6643A279Q38205944-4F46BDB5-6DE4-40B3-B534-96480A96ECFDQ38611558-BF5CF155-9D69-4144-9688-11D97616A255Q38998761-197EF2C1-1154-4FE3-88A9-5FBB8227BCBDQ39022227-A8720764-7C1D-4333-8334-AC55C9CDD5A7Q39391320-11AFEC78-FB89-4C52-859A-DA48D5823621Q40007790-416646B0-3FA5-4160-BA5D-1E4859BC49E1Q40320266-DDDE633B-5CE5-4BD6-A33A-B2AB28E2036AQ40559022-3F17C557-6F2A-485C-A048-B7A47683F9AEQ41159870-D2ADC813-9469-41B7-8FC5-E9DA4C48D1CBQ41342125-451501D8-1875-4A9A-B91E-0B1347454389Q41831950-6EF3E09A-0ABE-4005-85CA-1A694A6F4FC9Q42183705-DA5EC36D-5B56-4527-9776-54E5CE557D92Q45814314-785F4A4F-BC59-4F28-87DD-C32015000B85Q46905952-694384E2-A4BD-4BAB-8F21-8C1000EE8629Q47162034-FD3DC309-0BC9-46D1-BDB2-4813081BF89AQ50227767-935735C0-9251-4CD5-A85F-4B4CBFF25648Q50231271-2C3F9735-09B2-418D-A45D-5F6A76C73EE2Q50261290-89F913A4-2FB4-4E38-9174-FE91628A7B86Q50278110-DC29083E-3BA1-4912-A14A-C77FCD7714CBQ50485015-F5764DC7-EC29-4A0E-B6AA-F137CADF120FQ50499291-B4A9379A-CB95-4812-8BE8-998FD9740850Q50499294-B01CD46D-20FE-4521-803B-D1D743877FFBQ50503047-2179549C-61AD-4F27-8C1F-D3A50EFCB4BB
P2860
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Shape memory of human red blood cells.
@en
type
label
Shape memory of human red blood cells.
@en
prefLabel
Shape memory of human red blood cells.
@en
P2860
P1433
P1476
Shape memory of human red blood cells.
@en
P2093
Thomas M Fischer
P2860
P304
P356
10.1016/S0006-3495(04)74378-7
P407
P577
2004-05-01T00:00:00Z