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Development of a semi‐automated method for mitral valve modeling with medial axis representation using 3D ultrasound
Author(s) -
M. Pouch Alison,
A. Yushkevich Paul,
M. Jackson Benjamin,
S. Jassar Arminder,
Vergnat Mathieu,
H. Gorman Joseph,
C. Gorman Robert,
M. Sehgal Chandra
Publication year - 2012
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.3673773
Subject(s) - segmentation , 3d ultrasound , artificial intelligence , mitral valve , computer science , computer vision , mitral regurgitation , image segmentation , ultrasound , biomedical engineering , medicine , radiology , surgery
Purpose: Precise 3D modeling of the mitral valve has the potential to improve our understanding of valve morphology, particularly in the setting of mitral regurgitation (MR). Toward this goal, the authors have developed a user‐initialized algorithm for reconstructing valve geometry from transesophageal 3D ultrasound (3D US) image data. Methods: Semi‐automated image analysis was performed on transesophageal 3D US images obtained from 14 subjects with MR ranging from trace to severe. Image analysis of the mitral valve at midsystole had two stages: user‐initialized segmentation and 3D deformable modeling with continuous medial representation (cm‐rep). Semi‐automated segmentation began with user‐identification of valve location in 2D projection images generated from 3D US data. The mitral leaflets were then automatically segmented in 3D using the level set method. Second, a bileaflet deformable medial model was fitted to the binary valve segmentation by Bayesian optimization. The resulting cm‐rep provided a visual reconstruction of the mitral valve, from which localized measurements of valve morphology were automatically derived. The features extracted from the fitted cm‐rep included annular area, annular circumference, annular height, intercommissural width, septolateral length, total tenting volume, and percent anterior tenting volume. These measurements were compared to those obtained by expert manual tracing. Regurgitant orifice area (ROA) measurements were compared to qualitative assessments of MR severity. The accuracy of valve shape representation with cm‐rep was evaluated in terms of the Dice overlap between the fitted cm‐rep and its target segmentation. Results: The morphological features and anatomic ROA derived from semi‐automated image analysis were consistent with manual tracing of 3D US image data and with qualitative assessments of MR severity made on clinical radiology. The fitted cm‐reps accurately captured valve shape and demonstrated patient‐specific differences in valve morphology among subjects with varying degrees of MR severity. Minimal variation in the Dice overlap and morphological measurements was observed when different cm‐rep templates were used to initialize model fitting. Conclusions: This study demonstrates the use of deformable medial modeling for semi‐automated 3D reconstruction of mitral valve geometry using transesophageal 3D US. The proposed algorithm provides a parametric geometrical representation of the mitral leaflets, which can be used to evaluate valve morphology in clinical ultrasound images.