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Journal Abstract Search

120 related items for PubMed ID: 6591969

  • 1. In vitro blood flows through small tubes.
    Bitoun JP, Ly DP, Bellet D.
    Biorheology Suppl; 1984; 1():151-3. PubMed ID: 6591969
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  • 2. A theoretical analysis of the effects of varying fibrinogen concentration and haematocrit on the flow characteristics of blood in cylindrical tubes.
    Rampling MW, Challoner T.
    Biorheology; 1983; 20(2):141-52. PubMed ID: 6871430
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  • 3. Flow-dependent rheological properties of blood in capillaries.
    Secomb TW.
    Microvasc Res; 1987 Jul; 34(1):46-58. PubMed ID: 3657604
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  • 4. Perturbation of red blood cell flow in small tubes by white blood cells.
    Thompson TN, La Celle PL, Cokelet GR.
    Pflugers Arch; 1989 Feb; 413(4):372-7. PubMed ID: 2928089
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  • 6. A two-fluid model for blood flow through small diameter tubes.
    Chaturani P, Upadhya VS.
    Biorheology; 1979 Feb; 16(1-2):109-118. PubMed ID: 476292
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  • 7. Reply to the comments on - a two-fluid model for blood flow through small diameter tubes.
    Chaturani P, Biswas D, Mahajan SP.
    Biorheology; 1983 Feb; 20(6):807-9. PubMed ID: 6661531
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  • 8. Two-phase pulsatile flows through porous conical tubes of small diameters. Modelisation of the blood microcirculation.
    Zeggwagh G, Bellet D.
    Biorheology; 1987 Feb; 24(5):427-40. PubMed ID: 3446294
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  • 9. Inversion of Fahraeus effect and effect of mainstream flow on capillary hematocrit.
    Yen RT, Fung YC.
    J Appl Physiol Respir Environ Exerc Physiol; 1977 Apr; 42(4):578-86. PubMed ID: 863819
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  • 19. Effect of shear rate variation on apparent viscosity of human blood in tubes of 29 to 94 microns diameter.
    Reinke W, Johnson PC, Gaehtgens P.
    Circ Res; 1986 Aug; 59(2):124-32. PubMed ID: 3742742
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