BACKGROUND AND AIMS: Expanded polytetrafluoroethylene (ePTFE) suture has been used clinically for replacement of ruptured mitral valve chordae tendineae. The purpose of this study was to assess mitral valve function after posterior chordal replacement with ePTFE suture. METHODS: A three-dimensional finite element computer model of the mitral valve was used, which incorporated geometry, regional tissue thickness, collagen fiber orientation, and anisotropic material properties for the leaflets, interface, and chordae tendineae. To simulate chordal rupture, four marginal and four basal chordae were removed from the posterior leaflet. Chordal replacement was simulated using two elements with the physical and material properties of 2-0 ePTFE suture. Systolic loading pressures were applied. RESULTS: The chordal rupture model demonstrated posterior leaflet prolapse, abnormal stress concentrations, potential regurgitation, and elevated chordal stress. Conversely, the chordal replacement model corrected the prolapse and returned chordal stress to normal levels. However, stress concentrations were shown at suture attachment points. CONCLUSIONS: This integrated mitral valve finite element model provides a tool to investigate the performance of the valve system. In this study, we have shown that 2-0 ePTFE suture replacement of ruptured posterior chordae tendineae returns the valve to a near normal state, in terms of leaflet stress and coaptation, and chordal stresses.
BACKGROUND AND AIMS: Expanded polytetrafluoroethylene (ePTFE) suture has been used clinically for replacement of ruptured mitral valve chordae tendineae. The purpose of this study was to assess mitral valve function after posterior chordal replacement with ePTFE suture. METHODS: A three-dimensional finite element computer model of the mitral valve was used, which incorporated geometry, regional tissue thickness, collagen fiber orientation, and anisotropic material properties for the leaflets, interface, and chordae tendineae. To simulate chordal rupture, four marginal and four basal chordae were removed from the posterior leaflet. Chordal replacement was simulated using two elements with the physical and material properties of 2-0 ePTFE suture. Systolic loading pressures were applied. RESULTS: The chordal rupture model demonstrated posterior leaflet prolapse, abnormal stress concentrations, potential regurgitation, and elevated chordal stress. Conversely, the chordal replacement model corrected the prolapse and returned chordal stress to normal levels. However, stress concentrations were shown at suture attachment points. CONCLUSIONS: This integrated mitral valve finite element model provides a tool to investigate the performance of the valve system. In this study, we have shown that 2-0 ePTFE suture replacement of ruptured posterior chordae tendineae returns the valve to a near normal state, in terms of leaflet stress and coaptation, and chordal stresses.
Authors: Milan Toma; Morten Ø Jensen; Daniel R Einstein; Ajit P Yoganathan; Richard P Cochran; Karyn S Kunzelman Journal: Ann Biomed Eng Date: 2015-07-17 Impact factor: 3.934
Authors: Charles H Bloodworth; Eric L Pierce; Thomas F Easley; Andrew Drach; Amir H Khalighi; Milan Toma; Morten O Jensen; Michael S Sacks; Ajit P Yoganathan Journal: Ann Biomed Eng Date: 2016-10-03 Impact factor: 3.934
Authors: Milan Toma; Charles H Bloodworth; Eric L Pierce; Daniel R Einstein; Richard P Cochran; Ajit P Yoganathan; Karyn S Kunzelman Journal: Ann Biomed Eng Date: 2016-09-13 Impact factor: 3.934
Authors: Milan Toma; Daniel R Einstein; Charles H Bloodworth; Richard P Cochran; Ajit P Yoganathan; Karyn S Kunzelman Journal: Int J Numer Method Biomed Eng Date: 2016-07-28 Impact factor: 2.747
Authors: Katharina Vellguth; Jan Brüning; Leonid Goubergrits; Lennart Tautz; Anja Hennemuth; Ulrich Kertzscher; Franziska Degener; Marcus Kelm; Simon Sündermann; Titus Kuehne Journal: Int J Comput Assist Radiol Surg Date: 2018-07-14 Impact factor: 2.924