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Abstract

Accounting for the non-Newtonian blood viscosity by the Quemada descriptive viscosity equation, we deduced velocity profiles and volumetric capillary flows from the Navier-Stokes-equation. An arbitrary axial and/or radial hematocrit profile can be chosen. The hematocrit dependence of the intrinsic viscosities k_o (H) (characterizing, at least in part, the RBC aggregation) and k_∞ (H) (describing orientation/deformation of RBC) was taken into account.

Velocity profiles for pressure gradients of 4-4000 Pa/cm show a distinct flattening, if a pronounced axial migration of RBC is assumed. The higher the axial concentration, the higher the flow at the same pressure gradient. Small deviations (≤ 10%) of the capillary number per dialyzer or of the radius of capillaries lead to a strong change of the pressure gradient with the same dialyzer flow. Whereas small hydraulic conductivities do not significantly change this gradient, high conductivities decrease the pressure gradient by about 10%. Impaired blood flow properties (hemoconcentration) result in a slight deviation from the linear axial pressure drop.

Keywords

Hemodialysis Hollow-fibre Membranes Blood purification Velocity profile Blood viscosity

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References

Lerche

Temporal and local concentration changes in diffusion layers at cellulose membranes due to concentration differences between the solutions on both sides of the membrane. J Membr Biol 1976; 27: 193–205.

Vassilieff

CHS

, Leonhard

, Stepner

. The mechanism of cell rejection in membrane plasmapheresis. Clin Hemorheol 1985; 5: 7–14.

Papenfuss

, Gross

, Sanchez-Ruiz

Application of boundary-layer theory to ultrafiltration through flat semipermeable membranes. AJChE Symposium Series 1978; 74: 218–25.

Lerche

, Lüders

, Flieger

Microvasc Res 1991 (in preparation).

Lerche

, Oehlke

, Pardemann

, Flieger

Non-Newtonian blood properties, fluid exchange and streaming velocity profiles in capillaries (hollow fibers). Biorheol 1989; 26: 500.

Quemada

A rheological model for studying the hematocrit dependence of red cell - red cell interaction in blood. Biorheol 1981; 18: 501–13.

Lerche

, Lüders

Modulation of tube velocity profiles and hematocrit depending non-Newtonian blood properties. In: Tsuchiya

, Asano

, Mishima

, Oda

, eds. Microcirculation - an update. Amsterdam: Elsevier Science Publishers B.V., 1987; 521–2.

Cokelet

. The rheology and tube flow of blood. In: Skalak

, Chien

, eds. Handbook of bioengineering. New York, Tokyo, Toronto: McGraw-Hill Book Company, 1987; 14.1–14.17.

Bilsker

, Waters

ChM

, Kippenhan

, Eckstein

. A freeze-capture method for the study of platelet-sized particle distributions. Biorheol 1989; 26: 1031–40.

10.

Nair

, Hellmus

, Olson

. Prediction of oxygen transport rates in blood flowing in large capillaries. Microvasc Res 1989; 38: 269–85.

Theoretical Model of Blood Flow through Hollow Fibres considering Hematocrit-Dependent,Non-Newtonian Blood Properties

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