| Literature DB >> 33744155 |
Joris F Ooms1, Dee Dee Wang2, Ronak Rajani3, Simon Redwood4, Stephen H Little5, Michael L Chuang6, Jeffrey J Popma6, Gry Dahle7, Michael Pfeiffer8, Brinder Kanda9, Magali Minet10, Alexander Hirsch11, Ricardo P Budde12, Peter P De Jaegere1, Bernard Prendergast3, William O'Neill2, Nicolas M Van Mieghem13.
Abstract
A plethora of catheter-based strategies have been developed to treat mitral valve disease. Evolving 3-dimensional (3D) multidetector computed tomography (MDCT) technology can accurately reconstruct the mitral valve by means of 3-dimensional computational modeling (3DCM) to allow virtual implantation of catheter-based devices. 3D printing complements computational modeling and offers implanting physician teams the opportunity to evaluate devices in life-size replicas of patient-specific cardiac anatomy. MDCT-derived 3D computational and 3D-printed modeling provides unprecedented insights to facilitate hands-on procedural planning, device training, and retrospective procedural evaluation. This overview summarizes current concepts and provides insight into the application of MDCT-derived 3DCM and 3D printing for the planning of transcatheter mitral valve replacement and closure of paravalvular leaks. Additionally, future directions in the development of 3DCM will be discussed.Entities:
Keywords: 3D printing; computational modeling; mitral annular calcification; multidetector computed tomography; paravalvular leakage closure; transcatheter mitral valve replacement
Year: 2021 PMID: 33744155 DOI: 10.1016/j.jcmg.2020.12.034
Source DB: PubMed Journal: JACC Cardiovasc Imaging ISSN: 1876-7591