Advances in cardiovascular fluid mechanics: Bench to bedside

Annals of the New York Academy of Sciences

Volumn 1161, Issue , 2009, Pages 1-25

  Dasi, Lakshmi P ^a   Sucosky, Philippe ^a   De Zelicourt, Diane ^a   Sundareswaran, Kartik ^a   Jimenez, Jorge ^a   Yoganathan, Ajit P ^a  

^a GEORGIA INSTITUTE OF TECHNOLOGY   (United States)

Author keywords

Aortic valve; Computational fluid dynamics; Fontan; Heart valve; Hemodynamics; Mechanical valve; Mechanobiology; Mitral valve; Particle image velocimetry

Indexed keywords

AORTA VALVE; ARTICLE; CARDIOVASCULAR DISEASE; CARDIOVASCULAR FUNCTION; CARDIOVASCULAR SYSTEM; COMPUTATIONAL FLUID DYNAMICS; CONGENITAL HEART MALFORMATION; CORONARY ARTERY BLOOD FLOW; FLUID FLOW; FONTAN PROCEDURE; HEART HEMODYNAMICS; HEART VALVE PROSTHESIS; HUMAN; IN VITRO STUDY; MEMBRANE LEAFLET; METHODOLOGY; MITRAL VALVE; NUCLEAR MAGNETIC RESONANCE IMAGING; SHEAR STRESS; SIMULATION; TISSUE CULTURE; TREATMENT PLANNING;

EID: 65249190872     PISSN: 00778923     EISSN: 17496632     Source Type: Book Series    
DOI: 10.1111/j.1749-6632.2008.04320.x     Document Type: Article

References (46)

1. de Zelicourt, D.A., K. Pekkan, J. Parks, et al. 2006. Flow study of an extracardiac connection with persistent left superior vena cava. J. Thorac. Cardiovasc. Surg. 131:785-791.
2. Pekkan, K. et al.. 2005. Total cavopulmonary connection flow with functional left pulmonary artery stenosis: angioplasty and fenestration in vitro. Circulation 112: 3264-3271.
3. Ensley, A. E. et al. 1999. Toward designing the optimal total cavopulmonary connection: an in vitro study. Ann. Thorac. Surg. 68: 1384-1390.
4. Pekkan, K. et al. 2005. Physics-driven CFD modeling of complex anatomical cardiovascular flows: a TCPC case study. Ann. Biomed. Eng 33: 284-300.
5. Ensley, A.E. et al. 2000. Fluid mechanic assessment of the total cavopulmonary connection using magnetic resonance phase velocity mapping and digital particle image velocimetry. Ann. Biomed. Eng 28: 1172-1183.
6. Sundareswaran K.S., M.A. Fogel, K.P. Pekkan, et al. 2006. Viscous dissipation power loss of the total cavopulmonary connection evaluated using phase contrast magnetic resonance imaging. Presented at the American Heart Association Annual Scientific Session 2006.
7. Frakes, D.H. et al. 2003. Application of an adaptive control grid interpolation technique to morphological vascular reconstruction. IEEE Trans. Biomed. Eng. 50: 197-206.
8. Frakes, D.H. et al. 2005. New techniques for the reconstruction of complex vascular anatomies from MRI images. J. Cardiovasc. Magn. Reson. 7: 425-432.
9. de Julien de Zélicourt, D.A., K. Pekkan, D.H. Frakes, et al. 2004. Fluid mechanical assessment of anatomical models of the total cavopulmonary connection. Presented at the Fourteenth European Society of Bioengineering Conference. Hertogenbosch, The Netherlands.
10. Pekkan K.S.D., W.J. Parks, H. Kitajima, et al. 2005. Pre-Fontan surgery computational fluid dynamic analysis of three Glenn stage anatomies: effects of innominate vein and upper-lobe RPA branch. Presented at the American Society of Mechanical Engineering Conference. Vail, Colorado.
11. Pekkan, K.S.D., D. Sorensen, H. Kitajima & A.P. Yoganathan. 2005. Surgical planning of the total cavopulmonary connection using MRI, computational and experimental fluid mechanics. Presented at the Third European Medical and Biological Engineering Conference. EMBEC, Prague, Czech Republic.
12. Rossignac, J.P.K., B. Whited, K. Kanter & A. Yoganathan. 2006. SURGEM: next generation CAD tools targeting anatomical complexity for patientspecific surgical planning. Presented at the ASME-Bio2006 Summer Bioengineering Conference. Florida.
13. Safonova, A. & J. Rossignac. 2003. Compressed piecewise-circular approximation of 3D curves. Computer-Aided Design 35: 533-547.
14. Ibarria, L., &J. Rossignac. 2003. Dynapack: space-time compression of the 3D animations of triangle meshes with fixed connectivity. Tech Report GIT-GVU-03-08. ACM Symposium on Computer Animation (SCA).
15. Dasi, L.P. et al. 2007. Vorticity dynamics of a bileaflet mechanical heart valve in an axisymmetric aorta. Phys. Fluids 19(6): 067105.
16. Ge, L. et al. 2003. Numerical simulation of flow in mechanical heart valves: grid resolution and the assumption of flow symmetry. J. Biomech. Eng Trans. ASME 125: 709-718.
17. Ge, L. et al. 2005. Flow in a mechanical bileaflet heart valve at laminar and near-peak systole flow rates: CFD simulations and experiments. J. Biomech. Eng. Trans. ASME. 127: 782-797.
18. Ge, L. & F Sotiropoulos. 2007. A numerical method for solving the 3D unsteady incompressible Navier-Stokes equations in curvilinear domains with complex immersed boundaries. J. Comp. Phys. 225(2): 1782-1809.
19. Gilmanov, A. & F. Sotiropoulos. 2005. A hybrid Cartesian/immersed boundary method for simulating flows with 3D, geometrically complex, moving bodies. J. Comp. Phys. 207: 457-492.
20. Gilmanov, A., F. Sotiropoulos & E. Balaras. 2003. A general reconstruction algorithm for simulating flows with complex 3D immersed boundaries on Cartesian grids. J. Comp. Phys. 191: 660-669.
21. Simon, H.A. et al. 2004. Comparison of the hinge flow fields of two bileaflet mechanical heart valves under aortic and mitral conditions. Ann. Biomed. Eng. 32: 1607-1617.
22. Leverett, L.B. et al. 1972. Red blood cell damage by shear stress. Biophys. J. 12: 257-273.
23. Borazjani, I., L. Ge &F Sotiropoulos. 2008. Curvilinear immersed boundary method for simulating fluid structure interaction with complex 3D rigid bodies. J. Comp. Phys. 227(16): 7587-7620.
24. Leo, H.L. et al. 2006. Effect of hinge gap width on the microflow structures in 27-mm bileaflet mechanical heart valves. J. Heart Valve Dis. 15: 800-808.
25. Leo, H.L. et al. 2002. Microflow fields in the hinge region of the CarboMedics bileaflet mechanical heart valve design. J. Thorac. Cardiovas. Surg. 124: 561-574.
26. Jimenez, J.H. et al. 2003. Effects of a saddle shaped annulus on mitral valve function and chordal force distribution: an in vitro study. Ann. Biomed. Eng 31: 1171-1181.
27. Salgo, I.S. et al. 2002. Effect of annular shape on leaflet curvature in reducing mitral leaflet stress. Circulation 106: 711-717.
28. Timek, T.A. & D.C. Miller. 2001. Experimental and clinical assessment of mitral annular area and dynamics: what are we actually measuring? Ann. Thoracic Surg. 72: 966-974.
29. Madu, E.C. et al. 2001. Papillary muscle contribution to ventricular ejection in normal and hypertrophic ventricles: a transesophageal echocardiographic study. Echocardiography 18: 633-638.
30. Toumanidis, S.T. et al. 1992. The role of mitral annulus motion in left-ventricular function. Acta Cardiologica. 47: 331-348.
31. Sacks, M.S. et al. 2002. Surface strains in the anterior leaflet of the functioning mitral valve. Ann. Biomed. Eng. 30: 1281-1290.
32. He, Z.M. et al. 2003. Effects of papillary muscle position on in-vitro dynamic strain on the porcine mitral valve. J. Heart Valve Dis. 12: 488-494.
33. Quick, D.W. et al. 1997. Collagen synthesis is upregulated in mitral valves subjected to altered stress. Asaio J. 43: 181-186.
34. Kunzelman, K.S., D.W. Quick & R.P. Cochran. 1998. Altered collagen concentration in mitral valve leaflets: biochemical and finite element analysis. Ann. Thoracic Surg. 66: S198-S205.
35. Taylor, P.M., S.P. Allen & M.H. Yacoub. 2000. Phenotypic and functional characterization of interstitial cells from human heart valves, pericardium and skin. J. Heart Valve Dis. 9: 150-158.
36. Chester, A.H., M. Misfeld & M.H. Yacoub. 2000. Receptor-mediated contraction of aortic valve leaflets. J. Heart Valve Dis. 9: 250-254.
37. Nielsen, S.L. et al. 2004. Miniature C-shaped transducers for chordae tendineae force measurements. Ann. Biomed. Eng 32: 1050-1057.
38. He, S.Q. et al. 2003. Mitral leaflet geometry perturbations with papillary muscle displacement and annular dilatation: an in-vitro study of ischemic mitral regurgitation. J. Heart Valve Dis. 12: 300-307.
39. Jimenez, J.H. et al. 2005. Effects of papillary muscle position on chordal force distribution: an in-vitro study. J. Heart Valve Dis. 14: 295-302.
40. Chappell, D.C. et al. 1998. Oscillatory shear stress stimulates adhesion molecule expression in cultured human endothelium. Circ. Res. 82: 532-539.
41. Butcher, J.T. et al. 2006. Transcriptional profiles of valvular and vascular endothelial cells reveal phenotypic differences: influence of shear stress. Arterioscler. Thromb. Vase. Biol. 26: 69-77.
42. Weston, M.W., D.V. LaBorde & A.P. Yoganathan. 1999. Estimation of the shear stress on the surface of an aortic valve leaflet. Ann. Biomed. Eng 27: 572-579.
43. Mooney, M. & R.H. Ewart. 1934. The conicylindrical viscometer. Physics 5: 350-354.
44. Sorescu, G.P. et al. 2003. Bone morphogenic protein 4 produced in endothelial cells by oscillatory shear stress stimulates an inflammatory response. J. Biol. Chem. 278:31128-31135.
45. Christie, G.W. & B.G. Barratt-Boyes. 1995. Age-dependent changes in the radial stretch of human aortic valve leaflets determined by biaxial testing. Ann. Thorac. Surg. 60: S156-158; discussion S159.
46. Thubrikar, M. 1990. The Aortic Valve. CRC Press. Boca Raton, FL.