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Viscous motion of disk-shaped particles through parallel-sided channels with near-minimal widths

Published online by Cambridge University Press:  26 April 2006

D. Halpern1  and
T. W. Secomb
D. Halpern1
Affiliation:
Biomedical Engineering Department, Northwestern University, Evanston IL 60208. USA
T. W. Secomb
Affiliation:
Department of Physiology, University of Arizona, Tucson, AZ 85724. USA
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Abstract

The motion of a rigid disk-shaped particle with rounded edges, which fits closely in the space between two parallel flat plates, and which is suspended in a viscous fluid subject to an imposed pressure gradient, is analysed. This problem is relevant to the squeezing of red blood cells through narrow slot-like channels which are found in certain tissues. Mammalian red cells, although highly flexible, conserve volume and surface area as they deform. Consequently, a red cell cannot pass intact through a channel which is narrower than some minimum width. In channels that are just wide enough to permit cell passage, the cell is deformed into its ‘critical’ shape: a disk with rounded edges. In this paper, the fluid mechanical aspects of such motions are considered, and the particle is assumed to be rigid with the critical shape. The channel cross-section is assumed to be rectangular. The flow of the suspending fluid is described using lubrication theory. Use of lubrication theory is justified by considering the motion of a circular cylinder between parallel plates. For disk-shaped particles, approximate solutions are obtained by applying lubrication equations throughout the flow domain. In the region beyond the particle, this is equivalent to assuming a Hele-Shaw flow. More accurate solutions are obtained by including effects of boundary layers around the particle and at the sides of the channel. Pressure distributions and particle velocities are computed as functions of geometrical parameters, and it is shown that the particle may move faster or slower than the mean velocity of the surrounding fluid, depending on the channel dimensions.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 231 , October 1991 , pp. 545 - 560
Copyright
© 1991 Cambridge University Press

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References

Batchelor, G. K. 1967 An Introduction to Fluid Dynamics. Cambridge University Press.
Cameron, A. 1966 The Principles of Lubrication Theory. Longmans Green.
Dvinsky, A. S. & Popel, A. S. 1987a Motion of a rigid cylinder between parallel plates in Stokes flow. Part 1: Motion in a quiescent fluid and sedimentation. Comput. Fluids 15, 385404.Google Scholar
Dvinsky, A. S. & Popel, A. S. 1987b Motion of a rigid cylinder between parallel plates in Stokes flow. Part 2: Poiseuille and Couette flow. Comput. Fluids 15, 405419.Google Scholar
Gibson, J. G., Seligman, A. M., Peacock, W. C., Aub, J. C., Fine, J. & Evans, R. D. 1946 The distribution of red cells and plasma in large and minute vessels of the normal dog, determined by radioactive isotopes of iron and iodine. J. Clin. Invest. 25, 848857.Google Scholar
Halpern, D. 1989 The squeezing of red blood cells through tubes and channels of near-critical dimensions. PhD dissertation. University of Arizona, Tucson.
Halpern, D. & Secomb, T. W. 1989 The squeezing of red blood cells through capillaries with near-minimal diameters. J. Fluid Mech. 203, 381400.Google Scholar
Hele-Shaw, H. J. S. 1898 The flow of water. Nature 58, 3436.Google Scholar
Howland, R. C. J. 1934 Potential functions with periodicity in one coordinate. Proc. Camb. Phil. Soc. 30, 315326.Google Scholar
Özkaya, N. 1986 Viscous flow of particles in tubes: Lubrication theory and finite element models. PhD dissertation, Columbia University, New York.
Özkaya, N. & Shalak, R. 1983 The steady flow of particles in a tube. In 1983 Advances in Bioengineering (ed. D. L., Bartel), pp. 910. ASME, New York.
Secomb, T. W., Skalak, R., Özkaya, N. & Gross, J. F. 1986 Flow of axisymmetric red blood cells in narrow capillaries. J. Fluid Mech. 163, 405423.Google Scholar
Sommerfeld, A. 1904 Zur hydrodynamischen theorie der schmiermittelreibung. Z. Math. Phys. 40, 97155.Google Scholar