Reference : Real-time tumor ablation simulation based on the dynamic mode decomposition method
Scientific journals : Article
Human health sciences : Multidisciplinary, general & others
Computational Sciences
http://hdl.handle.net/10993/21260
Real-time tumor ablation simulation based on the dynamic mode decomposition method
English
Bourantas, Georgios mailto [MOSAIC Group, Max Planck Institute of Molecular Cell Biology and Genetics]
Ghommem, Mehdi [King Abdullah University of Science and Technology (KAUST) > Center for Numerical Porous Media (NumPor)]
Kagadis, George [School of Medicine, University of Patras > Department of Medical Physics > > ; The University of Texas MD Anderson Cancer Center > Department of Imaging Physics]
Katsanos, Konstantinos [King's College London, Division of Endovascular, Spine & Interventional Oncology, St Thomas' Hospital]
Loukopoulos, Vassilis [University of Patras > Department of Physics]
Burganos, Vasilis [nstitute of Chemical Engineering Sciences-Foundation for Research and Technology]
Nikiforidid, George [School of Medicine, University of Patras > Department of Medical Physics]
1-May-2014
Medical Physics
41
5
Yes (verified by ORBilu)
International
0094-2405
[en] Bioheat equation ; Eulerian ; Meshless method ; Moving Least Squares ; Thermal Ablation
[en] The Dynamic Mode Decomposition (DMD) method is used to provide a reliable forecasting of tumor ablation treatment simulation in real time, which is quite needed in medical practice. To achieve this, an extended Pennes bioheat model must be employed, taking into account both the water evaporation phenomenon and the tissue damage during tumor ablation.
http://hdl.handle.net/10993/21260

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