The deformation behavior of multiple red blood cells in a capillary vessel

Journal of Biomechanical Engineering

Volumn 131, Issue 7, 2009, Pages

  Gong, Xiaobo ^a   Sugiyama, Kazuyasu ^b   Takagi, Shu ^a,b   Matsumoto, Yoichiro ^b  

^a RIKEN   (Japan)

^b UNIVERSITY OF TOKYO   (Japan)

Author keywords

Biomembrane; Capillary blood flow; Immersed boundary method; Microcirculatory system; Red blood cell

Indexed keywords

BIOMEMBRANES; CAPILLARY BLOOD FLOW; IMMERSED BOUNDARY METHODS; MICROCIRCULATORY SYSTEM; RED BLOOD CELL;

BLOOD VESSELS; CAPILLARITY; CAPILLARY FLOW; CELLS; DEFORMATION; HEMOGLOBIN OXYGEN SATURATION; MICROCIRCULATION; NUMERICAL ANALYSIS; TURBULENT FLOW;

BLOOD;

ARTICLE; BLOOD PRESSURE; BLOOD VISCOSITY; CAPILLARY; CAPILLARY FLOW; CELL INTERACTION; ERYTHROCYTE DEFORMABILITY; MEMBRANE; SENSITIVITY ANALYSIS; SHEAR FLOW; BIOLOGICAL MODEL; BLOOD FLOW VELOCITY; CELL CULTURE; CELL SIZE; COMPUTER SIMULATION; CYTOLOGY; ERYTHROCYTE; ERYTHROCYTE MEMBRANE; PHYSIOLOGY; SHEAR STRENGTH; YOUNG MODULUS;

BLOOD FLOW VELOCITY; BLOOD PRESSURE; CAPILLARIES; CELL SIZE; CELLS, CULTURED; COMPUTER SIMULATION; ELASTIC MODULUS; ERYTHROCYTE MEMBRANE; ERYTHROCYTES; MODELS, CARDIOVASCULAR; SHEAR STRENGTH;

EID: 70349921164     PISSN: 01480731     EISSN: 15288951     Source Type: Journal    
DOI: 10.1115/1.3127255     Document Type: Article

References (18)

1. Boryczko, K., Dzwinel, W., and Yuen, D., 2003, "Dynamical Clustering of Red Blood Cells in Capillary Vessels," J. Mol. Model., 9, pp. 16-33.
2. Tanaka, M., and Koshizuka, S., 2007, "Simulation of Red Blood Cell Deformation Using a Particle Method," Nagare, 26, pp. 49-55 (in Japanese).
3. Noguchi, H., and Gompper, G., 2005, "Shape Transitions of Fluid Vesicles and Red Blood Cells in Capillary Flows," Proc. Natl. Acad. Sci. U.S.A., 102(40), pp. 14159-14164.
4. Dupin, M., Halliday, I., Care, C., Alboul, L., Munn, L., 2007, "Modeling the Flow of Dense Suspension of Deformable Particles in Three Dimensions," Phys. Rev. E, 75(6), p. 066707.
5. Lefebvre, A., and Maury, B., 2005, "Apparent Viscosity of a Mixture of a Newtonian Fluid and Interacting Particles," C. R. Mec., 333(12), pp. 923-933.
6. Pozrikidis, C., 2005, "Axisymmetric Motion of a File of Red Blood Cells Through Capillaries," Phys. Fluids, 17(3), p. 031503.
7. Bagchi, P., 2007, "Mesoscale Simulation of Blood Flow in Small Vessels," Biophys. J., 92(6), pp. 1858-1877. (Pubitemid 46495252)
8. Peskin, C., 1977, "Numerical Analysis of Blood Flows in the Heart," J. Comput. Phys., 25, pp. 220-252.
9. Unverdi, S., and Tryggvason, G., 1992, "A Front-Tracking Method for Viscous, Incompressible, Multi-Fluid Flows," J. Comput. Phys., 100, pp. 25-37.
10. Tryggvason, G., Bunner, B., Esmaeeli, A., Juric, D., Al-Rawahi, N., Tauber, W., Han, J., Nas, S., and Jan, Y., 2001, "A Front-Tracking Method for the Computations of Multiphase Flow," J. Comput. Phys., 169, pp. 708-759.
11. Pozrikidis, C., 2001, "Effect of Membrane Bending Stiffness on the Deformation of Capsules in Simple Shear Flow," J. Fluid Mech., 440, pp. 269-291. (Pubitemid 32739695)
12. Skalak, R., Tozeren, A., Zarda, R., and Chien, S., 1973, "Strain Energy Function of Red Blood Cell Membranes," Biophys. J., 13, pp. 245-264.
13. Takagi, S., Yamada, T., Gong, X., and Matsumoto, Y., 2009, "The Deformation of a Vesicle in a Linear Shear Flow," ASME J. Appl. Mech., 76(2), p. 021207.
14. Evans, E., and Fung, Y., 1972, "Improved Measurement of the Erythrocyte Geometry," Microvasc. Res., 4, pp. 335-347.
15. Fischer, T., and Schmid-Schonbein, H., 1977, "Tank Tread Motion of Red Cell Membranes in Viscometric Flow: Behavior of Intracellular and Extracellular Markers," Blood Cells, 3, pp. 351-365.
16. Pozrikidis, C., 2003, "Numerical Simulation of the Flow-Induced Deformation of Red Blood Cells," Ann. Biomed. Eng., 31, pp. 1194-1205.
17. Chien, S., Sung, L., Lee, M., and Skalak, R., 1992, "Red Cell Membrane Elasticity as Dertermind by Flow Channel Technique," Biorheology, 29, pp. 467-478. (Pubitemid 23104931)
18. Chien, S., Sung, L., Skalak, R., Usami, S., and Tozeren, A., 1978, "Theoretical and Experimental Studies on Viscoelastic Properties of Erythrocyte Membrane," Biophys. J., 24, pp. 463-487.