[1]FIANE A E. Longterm left ventricle assist device (LVAD) therapy with rotary pumps[J]. Scandinavian cardiovascular journal, 2009,43(6):357-359.
[2]NOS YUKIHIKO. Design and development strategy for the rotary blood pump[J]. Artificial organs, 1998, 22(6):438-446.
[3]BEHBAHANI M, BEHR M, HORMES M, et al. A review of computational fluid dynamics analysis of blood pumps[J]. European journal of applied mathematics, 2009, 20(3):363-397.
[4]MAY-NEWMAN K. Computational fluid dynamics models of ventricular assist devices[M]. Springer, 2010:297-316.
[5]SONG X, THROCKMORTON A L, WOOD H G, et al. Computational fluid dynamics prediction of blood damage in a centrifugal pump.[J]. Artificial organs, 2003, 27(10):938-941.
[6]FRASER K H, TASKIN M E, GRIFFITH B P, et al. The use of computational fluid dynamics in the development of ventricular assist devices[J]. Medical engineering & physics, 2010, 33(3):263-80.
[7]APEL J, NEUDEL F, REUL H. Computational fluid dynamics and experimental validation of a microaxial blood pump[J]. Asaio journal, 2001, 47(5):552-558.
[8]DAY S W, MCDANIEL J C, WOOD H G, et al. A prototype heartquest ventricular assist device for particle image velocimetry measurements[J]. Artificial organs, 2002, 26(11):1002-1005.
[9]BURGREEN G W,LOREE H M,BOURQUEK, et al. Computational fluid dynamics analysis of a maglev centrifugal left ventricular assist device[J]. Artificial organs, 2004,28:874-880.
[10]MAJIDI K. Numerical study of unsteady flow in a centrifugal pump[J]. Journal of turbomachinery, 2005, 127(2):805-814.
[11]SONG X, THROCKMORTON A L, WOOD H G, et al. Transient and quasisteady computational fluid dynamics study of a left ventricular assist device[J]. Asaio journal, 2004, 50(5):410-417.
[12]GARON A, FARINAS M I. Fast threedimensional numerical hemolysis approximation[J]. Artificial organs, 2004, 28(11):1016-1025. |