TY - JOUR
T1 - Personalized mitral valve closure computation and uncertainty analysis from 3D echocardiography
AU - Grbic, Sasa
AU - Easley, Thomas F.
AU - Mansi, Tommaso
AU - Bloodworth, Charles H.
AU - Pierce, Eric L.
AU - Voigt, Ingmar
AU - Neumann, Dominik
AU - Krebs, Julian
AU - Yuh, David D.
AU - Jensen, Morten O.
AU - Comaniciu, Dorin
AU - Yoganathan, Ajit P.
N1 - Funding Information:
This study was supported by grants from the Food and Drug Administration ( FDA-SOL-1119843 and FDA-SOL-1119844).
Publisher Copyright:
© 2016 Elsevier B.V.
Copyright:
Copyright 2018 Elsevier B.V., All rights reserved.
PY - 2017/1/1
Y1 - 2017/1/1
N2 - Intervention planning is essential for successful Mitral Valve (MV) repair procedures. Finite-element models (FEM) of the MV could be used to achieve this goal, but the translation to the clinical domain is challenging. Many input parameters for the FEM models, such as tissue properties, are not known. In addition, only simplified MV geometry models can be extracted from non-invasive modalities such as echocardiography imaging, lacking major anatomical details such as the complex chordae topology. A traditional approach for FEM computation is to use a simplified model (also known as parachute model) of the chordae topology, which connects the papillary muscle tips to the free-edges and select basal points. Building on the existing parachute model a new and comprehensive MV model was developed that utilizes a novel chordae representation capable of approximating regional connectivity. In addition, a fully automated personalization approach was developed for the chordae rest length, removing the need for tedious manual parameter selection. Based on the MV model extracted during mid-diastole (open MV) the MV geometric configuration at peak systole (closed MV) was computed according to the FEM model. In this work the focus was placed on validating MV closure computation. The method is evaluated on ten in vitro ovine cases, where in addition to echocardiography imaging, high-resolution μCT imaging is available for accurate validation.
AB - Intervention planning is essential for successful Mitral Valve (MV) repair procedures. Finite-element models (FEM) of the MV could be used to achieve this goal, but the translation to the clinical domain is challenging. Many input parameters for the FEM models, such as tissue properties, are not known. In addition, only simplified MV geometry models can be extracted from non-invasive modalities such as echocardiography imaging, lacking major anatomical details such as the complex chordae topology. A traditional approach for FEM computation is to use a simplified model (also known as parachute model) of the chordae topology, which connects the papillary muscle tips to the free-edges and select basal points. Building on the existing parachute model a new and comprehensive MV model was developed that utilizes a novel chordae representation capable of approximating regional connectivity. In addition, a fully automated personalization approach was developed for the chordae rest length, removing the need for tedious manual parameter selection. Based on the MV model extracted during mid-diastole (open MV) the MV geometric configuration at peak systole (closed MV) was computed according to the FEM model. In this work the focus was placed on validating MV closure computation. The method is evaluated on ten in vitro ovine cases, where in addition to echocardiography imaging, high-resolution μCT imaging is available for accurate validation.
KW - Finite-element biomechanical models
KW - Mitral valve modeling
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U2 - 10.1016/j.media.2016.03.011
DO - 10.1016/j.media.2016.03.011
M3 - Article
C2 - 27475910
AN - SCOPUS:84979658367
SN - 1361-8415
VL - 35
SP - 238
EP - 249
JO - Medical image analysis
JF - Medical image analysis
ER -