Numerical simulation of unsteady laminar flow through a tilting disk heart valve: prediction of vortex shedding.

Heart valves induce flow disturbances which play a role in blood cell activation and damage, but questions of the magnitude and spatial distribution of fluid stresses (wall shear stress and turbulent stress) cannot be readily addressed with current experimental techniques. Therefore, a numerical simulation procedure for flow through artificial heart valves is presented. The algorithm employed is based on the Navier-Stokes equations in generalized curvilinear coordinates with artificial compressibility for coupling of velocity and pressure. The algorithm applies a finite-difference technique on a body-conforming composite grid around the heart valve disk on which the numerical simulations are performed. Steady laminar flow over a backward-facing step and unsteady laminar flow inside a square driven cavity are computed to validate the algorithm. Two-dimensional, time-accurate simulation of flow through a tilting disk valve with a steady upstream Reynolds number as high as 1000 reveals the complex behavior of 'vortex shedding'. By scaling the results at the Reynolds number of 1000 to peak systolic flow conditions, the maximum value of shear stress on the valve disk is estimated to be 770 dyn cm-2. The 'apparent' Reynolds stress associated with vortex shedding is estimated to be as high as 3900 dyn cm-2 with a vortex shedding frequency of about 26 Hz. The 'apparent' Reynolds stress value is of similar magnitude as reported in experiments but would not be expected to damage blood cells because the spatial scales associated with vortex shedding are much larger than blood cell dimensions.

[1]  K. DenhamM,et al.  Laminar flow over a downstream-facing step in a two-dimensional flow channel. , 1974 .

[2]  C. Peskin,et al.  A three-dimensional computational method for blood flow in the heart. 1. Immersed elastic fibers in a viscous incompressible fluid , 1989 .

[3]  K. Chandran,et al.  Steady flow development past valve prostheses in a model human aorta. II. Tilting disc valves. , 1983, Journal of biomechanics.

[4]  Thomas H. Pulliam,et al.  On implicit finite-difference simulations of three-dimensional flow , 1978 .

[5]  B Khalighi,et al.  Experimental study of physiological pulsatile flow past valve prosthesis in a model of human aorta--II. Tilting disc valves and the effect of orientation. , 1985, Journal of biomechanics.

[6]  G Rosenberg,et al.  Pulsed ultrasonic Doppler velocity measurements inside a left ventricular assist device. , 1986, Journal of biomechanical engineering.

[7]  Charles S. Peskin,et al.  Modeling prosthetic heart valves for numerical analysis of blood flow in the heart , 1980 .

[8]  Woo Yr,et al.  In vitro pulsatile flow velocity and turbulent shear stress measurements in the vicinity of mechanical aortic heart valve prostheses. , 1985 .

[9]  T. Reif,et al.  Design Considerations for the Omniscience Pivoting Disc Cardiac Valve Prosthesis , 1983, The International journal of artificial organs.

[10]  Joe F. Thompson,et al.  Numerical grid generation , 1985 .

[11]  B. Armaly,et al.  Experimental and theoretical investigation of backward-facing step flow , 1983, Journal of Fluid Mechanics.

[12]  John W. Goodrich,et al.  Unsteady solution of incompressible Navier-Stokes equations , 1988 .

[13]  D B Geselowitz,et al.  Mean flow velocity patterns within a ventricular assist device. , 1989, ASAIO transactions.

[14]  A P Yoganathan,et al.  Numerical simulation of steady turbulent flow through trileaflet aortic heart valves--I. Computational scheme and methodology. , 1985, Journal of biomechanics.

[15]  W. V. Snyder,et al.  Algorithm 531: Contour Plotting [J6] , 1978, TOMS.

[16]  A P Yoganathan,et al.  In vitro velocity measurements in the vicinity of aortic prostheses. , 1979, Journal of biomechanics.

[17]  Stuart E. Rogers,et al.  Numerical solution of the incompressible Navier-Stokes equations for steady-state and time-dependent problems , 1989 .

[18]  D B Geselowitz,et al.  Estimation of Reynolds stresses within the Penn State left ventricular assist device. , 1990, ASAIO transactions.

[19]  Application of Runge-Kutta schemes to incompressible flows , 1986 .

[20]  G Rosenberg,et al.  Hot-film wall shear probe measurements inside a ventricular assist device. , 1988, Journal of biomechanical engineering.

[21]  B Khalighi,et al.  Laser anemometry measurements of pulsatile flow past aortic valve prostheses. , 1983, Journal of biomechanics.

[22]  B. Lieber The decomposition of apparent stresses in disturbed pulsatile flow in the presence of large scale organized structures. , 1990, Journal of biomechanics.

[23]  E. Papoutsakis,et al.  Fluid-mechanical damage of animal cells in bioreactors. , 1991, Trends in biotechnology.

[24]  C S Peskin,et al.  Computer-assisted design of pivoting disc prosthetic mitral valves. , 1983, The Journal of thoracic and cardiovascular surgery.

[25]  N H Hwang,et al.  Estimation of the rotational undamped natural frequency of bileaflet cardiac valve prostheses. , 1990, Journal of biomechanical engineering.

[26]  K B Chandran,et al.  Effect of prosthetic mitral valve geometry and orientation on flow dynamics in a model human left ventricle. , 1989, Journal of biomechanics.