Fast Automatic Liver Tumor Radiofrequency Ablation Planning via Learned Physics Model
Meister F, Audigier C, Passerini T, Lluch È, Mihalef V, Maier A, Tommaso M (2022)
Publication Type: Conference contribution
Publication year: 2022
Journal
Original Authors: Felix Meister, Chloé Audigier, Tiziano Passerini, Èric Lluch, Viorel Mihalef, Andreas Maier, Tommaso Mansi
Publisher: Springer Link
Series: Medical Image Computing and Computer Assisted Intervention – MICCAI 2022
City/Town: Singapore
Pages Range: 167-176
Conference Proceedings Title: 25th International Conference, Singapore, September 18–22, 2022, Proceedings, Part VII
Event location: Singapore
ISBN: 9783031164484
DOI: 10.1007/978-3-031-16449-1_17
Abstract
Radiofrequency ablation is a minimally-invasive therapy recommended for the treatment of primary and secondary liver cancer in early stages and when resection or transplantation is not feasible. To significantly reduce chances of local recurrences, accurate planning is required, which aims at finding a safe and feasible needle trajectory to an optimal electrode position achieving full coverage of the tumor as well as a safety margin. Computer-assisted algorithms, as an alternative to the time-consuming manual planning performed by the clinicians, commonly neglect the underlying physiology and rely on simplified, spherical or ellipsoidal ablation estimates. To drastically speed up biophysical simulations and enable patient-specific ablation planning, this work investigates the use of non-autoregressive operator learning. The proposed architecture, trained on 1,800 biophysics-based simulations, is able to match the heat distribution computed by a finite-difference solver with a root mean squared error of 0.51 ± .50 ∘C and the estimated ablation zone with a mean dice score of 0.93 ± 0.05, while being over 100 times faster. When applied to single electrode automatic ablation planning on retrospective clinical data, our method achieves patient-specific results in less than 4 mins and closely matches the finite-difference-based planning, while being at least one order of magnitude faster. Run times are comparable to those of sphere-based planning while accounting for the perfusion of liver tissue and the heat sink effect of large vessels.
Authors with CRIS profile
Felix Meister
Lehrstuhl für Informatik 5 (Mustererkennung)
Andreas Maier
Lehrstuhl für Informatik 5 (Mustererkennung)
Involved external institutions
Siemens AG, Healthcare Sector
Germany (DE)
Siemens Corporate Research
United States (USA) (US)
Siemens Healthineers
Germany (DE)
Germany (DE)
Siemens Corporate Research
United States (USA) (US)
Siemens Healthineers
Germany (DE)
How to cite
APA:
Meister, F., Audigier, C., Passerini, T., Lluch, È., Mihalef, V., Maier, A., & Tommaso, M. (2022). Fast Automatic Liver Tumor Radiofrequency Ablation Planning via Learned Physics Model. In Springerf (Eds.), 25th International Conference, Singapore, September 18–22, 2022, Proceedings, Part VII (pp. 167-176). Singapore: Singapore: Springer Link.
MLA:
Meister, Felix, et al. "Fast Automatic Liver Tumor Radiofrequency Ablation Planning via Learned Physics Model." Proceedings of the Medical Image Computing and Computer Assisted Intervention – MICCAI 2022, Singapore Ed. Springerf, Singapore: Springer Link, 2022. 167-176.
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