Biomedical Engineering Reference
In-Depth Information
8. Kudo, M., Yozu, R., Kokaji, K., Iwanaga, S.: Feasibility of mitral valve repair using the loop
technique. Ann. Thorac. Cardiovasc. Surg.
13
, 21-26 (2007)
9. Votta, E., Le, T.B., Stevanella, M., Fusini, L., Caiani, E.G., Redaelli, A., et al.: Toward patient-
specific simulations of cardiac valves: state-of-the-art and future directions. J. Biomech.
46
,
217-228 (2013)
10. Kunzelman, K., Reimink, M.S., Verrier, E.D., Cochran, R.P.: Replacement of mitral valve
posterior chordae tendineae with expanded polytetrafluoroethylene suture: a finite element
study. J. Card. Surg.
11
, 136-145 (1996)
11. Rim, Y., Laing, S.T., McPherson, D.D., Kim, H.: Mitral valve repair using ePTFE sutures for
ruptured mitral chordae tendineae: a computational simulation study. Ann. Biomed. Eng.
42
,
139-148 (2014)
12. Stevanella, M., Maffessanti, F., Conti, C., Votta, E., Arnoldi, A., Lombardi, M., et al.: Mitral
valve patient-specific finite element modeling from cardiacMRI: application to an annuloplasty
procedure. cardiovasc. Eng. Technol.
2
, 66-76 (2011)
13. Degandt, A.A., Weber, P.A., Saber, H.A., Duran, C.M.: Mitral valve basal chordae: comparative
anatomy and terminology. Ann. Thorac. Surg.
84
, 1250-1255 (2007)
14. Lam, J.H., Ranganathan, N., Wigle, E.D., Silver, M.D.: Morphology of the human mitral valve
I Chordae tendineae: a new classification. Circulation
41
, 449-458 (1970)
15. May-Newman, K., Yin, F.C.: A constitutive law for mitral valve tissue. J. Biomech. Eng.
120
,
38-47 (1998)
16. Kunzelman, K.S., Einstein, D.R., Cochran, R.P.: Fluid-structure interactionmodels of themitral
valve: function in normal and pathological states. Philos. Trans. R. Soc. Lond. B. Biol. Sci.
362
, 1393-1406 (2007)
17. Kunzelman, K.S., Cochran, R.P.: Mechanical properties of basal and marginal mitral valve
chordae tendineae. ASAIO. Trans.
36
, M405-408 (1990)
18. Votta, E., Maisano, F., Bolling, S.F., Alfieri, O., Montevecchi, F.M., Redaelli, A.: The Geoform
disease-specific annuloplasty system: a finite element study. Ann. Thorac. Surg.
84
, 92-101
(2007)
19. Dang, M.C., Thacker, J.G., Hwang, J.C., Rodeheaver, G.T., Melton, S.M., Edlich, R.F.: Some
biomechanical considerations of polytetrafluoroethylene sutures. Arch. Surg.
125
, 647-650
(1990)
20. Tesler, U.F., Cerin, G., Novelli, E., Popa, A., Diena, M.: Evolution of surgical techniques for
mitral valve repair. Tex. Heart. Inst. J.
36
, 438-440 (2009)
21. Falk, V., Seeburger, J., Czesla, M., Borger, M.A., Willige, J., Kuntze, T., et al.: How does the
use of polytetrafluoroethylene neochordae for posterior mitral valve prolapse (loop technique)
compare with leaflet resection? A prospective randomized trial. J. Thorac. Cardiovasc. Surg.
136
, 1205 (2008). [discussion-6]
22. Paterson-Brown, S., Cheslyn-Curtis, S., Biglin, J., Dye, J., Easmon, C.S., Dudley, H.A.: Suture
materials in contaminated wounds: a detailed comparison of a new suture with those currently
in use. Br. J. Surg.
74
, 734-735 (1987)
23. Calafiore, A.M.: Choice of artificial chordae length according to echocardiographic criteria.
Ann. Thorac. Surg.
81
, 375-377 (2006)
24. Sarsam, M.A.: Simplified technique for determining the length of artificial chordae in mitral
valve repair. Ann. Thorac. Surg.
73
, 1659-1660 (2002)
25. Scorsin, M., Al-Attar, N., Lessana, A.: A novel technique of utilizing artificial chordae for
repair of mitral valve prolapse. J. Thorac. Cardiovasc. Surg.
134
, 1072-1073 (2007)
26. Maselli, D., De Paulis, R., Weltert, L., Salica, A., Scaffa, R., Bellisario, A., et al.: A newmethod
for artificial chordae length "tuning" in mitral valve repair: preliminary experience. J. Thorac.
Cardiovasc. Surg.
134
, 454-459 (2007)
27. Mandegar, M.H., Yousefnia, M.A., Roshanali, F.: Preoperative determination of artificial chor-
dae length. Ann. Thorac. Surg.
84
, 680-682 (2007)
