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Plasma motions in narrow capillary flow

Published online by Cambridge University Press:  29 March 2006

J. M. Fitz-Gerald
Affiliation:
Department of Mathematics, University of Queensland

Abstract

Plasma motions in the gaps between successive red cells in narrow-capillary blood flow are obtained in an idealized model, using a series of eigenfunctions to represent the disturbance to a basic Poiseuille flow created by the cells. The flow is matched, in the narrow entry and exit regions, to the lubrication flow in the constricted zone around the red cell (Fitz-Gerald 1969). Basically, the circulating toroidal motion predicted by Prothero & Burton (1961) is obtained in a reference frame in which the cells are considered stationary. Small secondary circulations are also found near the axis and close to the red cells, whose intensity is controlled by the amount of leakback past the cells. Zones of high shear are found along the capillary wall and in some cases on part of the red-cell face; implications of this for mass transport are discussed (see §4). Because of the unusual behaviour of the slowest-decaying dominant eigenfunction circulation and wall shear increase as the cell spacing decreases, contrary to expectation, until the spacing becomes very small indeed.

Type
Research Article
Copyright
© 1972 Cambridge University Press

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References

Aroesty, J. & Gross J. F.1970 Microvascular Res. 2, 247.
Bloch E. H.1962 Am. J. Anat. 110, 125.
Bloor M. I. G.1968 Phys. Med. Biol. 13, 443.
Brånemark, P. I. & Lindström J.1963 Biorheology, 1, 139.
Bugliarello, O. & Hsiao G. C.1970 Biorheology, 7, 5.
Davidson, M. R. & Fitz-Gerald J. M.1972 J. Fluid Mech. (to appear).
Fitz-Gerald J. M.1969 Proc. Roy. Soc. B 174, 193.
Fitz-Gerald J. M.1970 J. Appl. Physiol. 27, 912.
Fitz-Gerald J. M.1972 In Cardiovascular Fluid Dynamics (ed. D. Bergel). Academic.
Guest M. M., Bond T. P., Cooper, R. G. & Derrick J. R.1963 Science, 142, 1319.
Landis, E. M. & Pappenheimer J. R.1963 In Handbook of Physiology, p. 961. Washington: Am. Physiol. Soc..
Lee, H. S. & Fung Y. C.1969 Biorheology, 6, 109.
Lee, H. S. & Fung Y. C.1970 Biophys. J. 10, 80.
Lighthill M. J.1968 J. Fluid Mech. 34, 113.
Lighthill M. J.1969 CIBA Symposium on Circulatory and Respiratory Mass Transport, p. 85. London: ChurchillM.
Luft J. H.1966 Federation Proc. 25, 1773.
Palmer A. A.1959 Quart. J. Expt. Physiol. 44, 149.
Prothero, J. W. & Burton A. C.1961 Biophys. J. 1, 565.
Prothero, J. W. & Burton A. C.1962 Biophys. J. 2, 199.
Scarton H. A.1970 Ph.D. thesis, Carnegie-Melton University, Pittsburgh.
Scarton, H. A. & Rouleau W. T.1971a (To be published.)
Scarton, H. A. & Rouleau W. T.1971b (To be published.)
Wang, H. & Skalak R.1969 J. Fluid Mech. 38, 75.
Zidan M. von1969 Rheologica Acta, 8, 89.