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Journal Abstract Search

119 related items for PubMed ID: 1201370

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  • 3. Decreased hydrodynamic resistance in the two-phase flow of blood through small vertical tubes at low flow rates.
    Cokelet GR, Goldsmith HL.
    Circ Res; 1991 Jan; 68(1):1-17. PubMed ID: 1984854
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  • 5. The viscosity of erythrocyte suspensions. A review of theory.
    HAYNES RH.
    Biophys J; 1962 Jan; 2(1):95-103. PubMed ID: 13905677
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  • 6. Effect of velocity of distribution on red cell distribution in capillary blood vessels.
    Yen RT, Fung YC.
    Am J Physiol; 1978 Aug; 235(2):H251-7. PubMed ID: 686194
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  • 7. Osmolality- and hematocrit-mediated flow behavior of RBC suspensions in 33 micrometer ID tubes.
    McKay CB, Meiselman HJ.
    Biorheology; 1989 Aug; 26(4):863-74. PubMed ID: 2611376
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  • 9. Flows of red blood cell suspensions through narrow two-dimensional channels.
    Chan T, Jaffrin MY, Seshadri V, Mc Kay C.
    Biorheology; 1982 Aug; 19(1/2):253-67. PubMed ID: 6807368
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  • 11. Effects of sedimentation of small red blood cell aggregates on blood flow in narrow horizontal tubes.
    Murata T.
    Biorheology; 1996 Aug; 33(3):267-83. PubMed ID: 8935183
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  • 14. Flow dynamics of erythrocytes in microvessels of isolated rabbit mesentery: cell-free layer and flow resistance.
    Tateishi N, Suzuki Y, Soutani M, Maeda N.
    J Biomech; 1994 Sep; 27(9):1119-25. PubMed ID: 7929461
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  • 18. Nonuniform red cell distribution in 20 to 100 micrometers bifurcations.
    Fenton BM, Carr RT, Cokelet GR.
    Microvasc Res; 1985 Jan; 29(1):103-26. PubMed ID: 2580216
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  • 19. Capillary pore rheology of erythrocytes. V. The glass capillary array--effect of velocity and haematocrit in long bore tubes.
    Lingard PS.
    Microvasc Res; 1979 May; 17(3 Pt 1):272-89. PubMed ID: 459940
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  • 20. Osmolality-mediated Fahraeus and Fahraeus-Lindqvist effects for human RBC suspensions.
    McKay CB, Meiselman HJ.
    Am J Physiol; 1988 Feb; 254(2 Pt 2):H238-49. PubMed ID: 3344815
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