An analysis of turbulent shear stresses in leakage flow through a bileaflet mechanical prostheses.

In this work, estimates of turbulence were made from pulsatile flow laser Doppler velocimetry measurements using traditional phase averaging and averaging after the removal of cyclic variation. These estimates were compared with estimates obtained from steady leakage flow LDV measurements and an analytical method. The results of these studies indicate that leakage jets which are free and planar in shape may be more unstable than other leakage jets, and that cyclic variation does not cause a gross overestimation of the Reynolds stresses at large distances from the leakage jet orifice.

[1]  R. M. Privette,et al.  Cycle-to-cycle variation effects on turbulent shear stress measurements in pulsatile flows , 1988 .

[2]  J D Hellums,et al.  Morphological, biochemical, and functional changes in human platelets subjected to shear stress. , 1975, The Journal of laboratory and clinical medicine.

[3]  P K Paulsen,et al.  Estimation of turbulent shear stresses in pulsatile flow immediately downstream of two artificial aortic valves in vitro. , 1990, Journal of biomechanics.

[4]  R M Hochmuth,et al.  Shear-induced aggregation and lysis of platelets. , 1976, Transactions - American Society for Artificial Internal Organs.

[5]  H. Goldsmith,et al.  Aggregation of human platelets in an annular vortex distal to a tubular expansion. , 1979, Microvascular research.

[6]  M Grigioni,et al.  On the monodimensional approach to the estimation of the highest reynolds shear stress in a turbulent flow. , 2000, Journal of biomechanics.

[7]  L. J. S. Bradbury,et al.  The structure of a self-preserving turbulent plane jet , 1965, Journal of Fluid Mechanics.

[8]  T. Gross,et al.  The epidemiology of prosthetic heart valves in the United States. , 1995, Texas Heart Institute journal.

[9]  W G Tiederman,et al.  Two-component laser velocimeter measurements downstream of heart valve prostheses in pulsatile flow. , 1986, Journal of biomechanical engineering.

[10]  A P Yoganathan,et al.  An in vitro investigation of the retrograde flow fields of two bileaflet mechanical heart valves. , 1996, The Journal of heart valve disease.

[11]  N H Hwang,et al.  Human red blood cell hemolysis in a turbulent shear flow: contribution of Reynolds shear stresses. , 1984, Biorheology.

[12]  H. Goldsmith,et al.  Role of blood cell-wall interactions in thrombogenesis and atherogenesis: a microrheological study. , 1984, Biorheology.

[13]  S H Chu,et al.  Turbulence characteristics downstream of bileaflet aortic valve prostheses. , 2000, Journal of biomechanical engineering.

[14]  Wolfgang Rodi,et al.  The Turbulent Wall Jet Measurements and Modeling , 1983 .

[15]  H Schmid-Schönbein,et al.  Towards a concept of thrombosis in accelerated flow: rheology, fluid dynamics, and biochemistry. , 1985, Biorheology.

[16]  M. Glauert The wall jet , 1956, Journal of Fluid Mechanics.

[17]  H Reul,et al.  Leakage flow at mechanical heart valve prostheses: improved washout or increased blood damage? , 1999, The Journal of heart valve disease.

[18]  D B Geselowitz,et al.  Effects of tilting disk heart valve gap width on regurgitant flow through an artificial heart mitral valve. , 2008, Artificial organs.

[19]  A P Yoganathan,et al.  Velocity measurements and flow patterns within the hinge region of a Medtronic Parallel bileaflet mechanical valve with clear housing. , 1996, The Journal of heart valve disease.

[20]  S Einav,et al.  An experimental study of pulsatile pipe flow in the transition range. , 1993, Journal of biomechanical engineering.

[21]  A P Yoganathan,et al.  A comparison of the hinge and near-hinge flow fields of the St Jude medical hemodynamic plus and regent bileaflet mechanical heart valves. , 2000, The Journal of thoracic and cardiovascular surgery.