Interactive Training System for Interventional ...
Type de document :
Compte-rendu et recension critique d'ouvrage
Titre :
Interactive Training System for Interventional Electrocardiology Procedures
Auteur(s) :
Talbot, Hugo [Auteur]
Computational Anatomy and Simulation for Medicine [MIMESIS]
Spadoni, Federico [Auteur]
Analysis and Simulation of Biomedical Images [ASCLEPIOS]
Duriez, Christian [Auteur]
Deformable Robots Simulation Team [DEFROST ]
Sermesant, Maxime [Auteur]
Analysis and Simulation of Biomedical Images [ASCLEPIOS]
Cotin, Stéphane [Auteur]
Computational Anatomy and Simulation for Medicine [MIMESIS]
Delingette, Hervé [Auteur]
Analysis and Simulation of Biomedical Images [ASCLEPIOS]
Computational Anatomy and Simulation for Medicine [MIMESIS]
Spadoni, Federico [Auteur]
Analysis and Simulation of Biomedical Images [ASCLEPIOS]
Duriez, Christian [Auteur]
Deformable Robots Simulation Team [DEFROST ]
Sermesant, Maxime [Auteur]
Analysis and Simulation of Biomedical Images [ASCLEPIOS]
Cotin, Stéphane [Auteur]
Computational Anatomy and Simulation for Medicine [MIMESIS]
Delingette, Hervé [Auteur]
Analysis and Simulation of Biomedical Images [ASCLEPIOS]
Titre de la revue :
Medical Image Analysis
Pagination :
11-19
Éditeur :
Elsevier
Date de publication :
2016
ISSN :
1361-8415
Mot(s)-clé(s) en anglais :
Endovascular Navigation
Training Simulator
Interactive Simulation
Real-Time Electrophysiology
Training Simulator
Interactive Simulation
Real-Time Electrophysiology
Discipline(s) HAL :
Informatique [cs]/Modélisation et simulation
Résumé en anglais : [en]
Recent progress in cardiac catheterization and devices has allowed the development of new therapies for severe cardiac diseases like arrhythmias and heart failure. The skills required for such interventions are very ...
Lire la suite >Recent progress in cardiac catheterization and devices has allowed the development of new therapies for severe cardiac diseases like arrhythmias and heart failure. The skills required for such interventions are very challenging to learn, and are typically acquired over several years. Virtual reality simulators may reduce this burden by allowing trainees to practice such procedures without risk to patients. In this paper, we propose the first training system dedicated to cardiac electrophysiology, including pacing and ablation procedures. Our framework involves the simulation of a catheter navigation that reproduces issues intrinsic to intra-cardiac catheterization, and a graphics processing unit (GPU)-based electrophysiological model. A multi-threading approach is proposed to compute both physical simulations (navigation and electrophysiology) asynchronously. With this method, we reach computational performances that account for user interactions in real-time. Based on a scenario of cardiac arrhythmia, we demonstrate the ability of the user-guided simulator to navigate inside vessels and cardiac cavities with a catheter and to reproduce an ablation procedure involving: extra-cellular potential measurements, endocardial surface reconstruction, electrophysiol-ogy mapping, radio-frequency (RF) ablation, as well as electrical stimulation. A clinical evaluation assessing the different aspects of the simulation is presented. This works is a step towards computerized medical learning curriculum.Lire moins >
Lire la suite >Recent progress in cardiac catheterization and devices has allowed the development of new therapies for severe cardiac diseases like arrhythmias and heart failure. The skills required for such interventions are very challenging to learn, and are typically acquired over several years. Virtual reality simulators may reduce this burden by allowing trainees to practice such procedures without risk to patients. In this paper, we propose the first training system dedicated to cardiac electrophysiology, including pacing and ablation procedures. Our framework involves the simulation of a catheter navigation that reproduces issues intrinsic to intra-cardiac catheterization, and a graphics processing unit (GPU)-based electrophysiological model. A multi-threading approach is proposed to compute both physical simulations (navigation and electrophysiology) asynchronously. With this method, we reach computational performances that account for user interactions in real-time. Based on a scenario of cardiac arrhythmia, we demonstrate the ability of the user-guided simulator to navigate inside vessels and cardiac cavities with a catheter and to reproduce an ablation procedure involving: extra-cellular potential measurements, endocardial surface reconstruction, electrophysiol-ogy mapping, radio-frequency (RF) ablation, as well as electrical stimulation. A clinical evaluation assessing the different aspects of the simulation is presented. This works is a step towards computerized medical learning curriculum.Lire moins >
Langue :
Anglais
Vulgarisation :
Non
Projet Européen :
Collections :
Source :
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