Title :
Valvular closure prediction using anisotropic and hyperelastic tissue models and individualized anatomy derived from RT3DE
Author :
Sprouse, C. ; Mukherjee, Rohan ; Burlina, Philippe
Author_Institution :
Johns Hopkins Univ. Appl. Phys. Lab., Laurel, MD, USA
fDate :
Aug. 28 2012-Sept. 1 2012
Abstract :
We describe a method for modeling the closure of the Mitral Valve (MV) and to compute realistic strain and stresses in MV tissues. This informs preoperative planning by allowing a surgeon to evaluate various MV repairs options. The modeling method exploits individualized (patient-specific) anatomical structure recovered from real-time 3D echocardiography (RT3DE). This study utilizes hyperelastic models of the MV tissues and employs patient specific leaflets, chordal length assessment and annulus shapes. We report experiments on ten intraoperative test cases, where we compute strain and stresses using several different tissue models from MV empirical studies by May-Newman [1] and Holzapfel [2].
Keywords :
biological tissues; biomechanics; deformation; elasticity; electrocardiography; physiological models; stress effects; surgery; RT3DE; anisotropic tissue model; hyperelastic models; hyperelastic tissue model; individualized anatomy; mitral valve closure modeling; mitral valve repair options; mitral valve tissue strain; mitral valve tissue stress; patient specific anatomical structure; preoperative planning; real time 3D echocardiography; valvular closure prediction; Computational modeling; Heart; Predictive models; Strain; Stress; Surgery; Valves; Algorithms; Anisotropy; Computational Biology; Computer Simulation; Echocardiography, Three-Dimensional; Elasticity; Humans; Mitral Valve; Mitral Valve Insufficiency; Models, Cardiovascular; Models, Statistical; Software;
Conference_Titel :
Engineering in Medicine and Biology Society (EMBC), 2012 Annual International Conference of the IEEE
Conference_Location :
San Diego, CA
Print_ISBN :
978-1-4244-4119-8
Electronic_ISBN :
1557-170X
DOI :
10.1109/EMBC.2012.6347515
