Szczegóły publikacji

Opis bibliograficzny

Improving the automatic cranial implant design in cranioplasty by linking different datasets / Marek WODZIŃSKI, Mateusz DANIOŁ, Daria HEMMERLING // W: Towards the automatization of cranial implant design in cranioplasty II : second challenge : AutoImplant 2021 : held in conjunction with MICCAI 2021 : Strasbourg, France, October 1, 2021 : proceedings / eds. Jianning Li, Jan Egger. — Cham : Springer, cop. 2021. — (Lecture Notes in Computer Science ; ISSN 0302-9743 ; LNCS 13123. Image Processing, Computer Vision, Pattern Recognition, and Graphics). — ISBN: 978-3-030-92651-9; e-ISBN: 978-3-030-92652-6. — S. 29–44. — Bibliogr., Abstr. — Publikacja dostępna online od: 2021-12-03. — M. Wodziński – dod. afiliacja: University of Applied Sciences Western Switzerland (HES-SO Valais) Sierre, Switzerland

Autorzy (3)

Słowa kluczowe

image segmentationcranial implantdeep learningMICCAI challengeAutoImplant

Dane bibliometryczne

ID BaDAP138225
Data dodania do BaDAP2021-12-15
DOI10.1007/978-3-030-92652-6_4
Rok publikacji2021
Typ publikacjimateriały konferencyjne (aut.)
Otwarty dostęptak
WydawcaSpringer
KonferencjaMedical Image Computing and Computer-Assisted Intervention 2021
Czasopismo/seriaLecture Notes in Computer Science

Abstract

The automatic design of cranial implants is an important and challenging task. The implants must be designed according to the individual characterization of the patient’s defect. This makes the process tedious and time consuming. However, if possible, the personalized implants should be designed and fabricated during the surgical procedure that requires the implant modeling to be as efficient as possible. The design of the cranial implants may be improved and accelerated by deep learning-based segmentation networks. This approach transfers the computational burden to the training phase, allowing a real-time inference. Moreover, the practical method should be fully automatic, without the need for manual parameter tuning related to the defect characterization. Therefore, a single, universal model is desirable during practical usage. Nevertheless, deep learning-based solutions require large amount of training data that is difficult to acquire and annotate. To address this problem, we propose a method to connect the two training sets from the AutoImplant challenge, together with a dedicated U-Net based segmentation network. The datasets are combined by the affine and non-rigid registration, and then are further augmented by random affine transformations. The segmentation method consists of two sequential networks responsible for general structure modelling and the preservation of fine details respectively. We evaluate the proposed results using test sets for all tasks from the AutoImplant 2021 challenge. Three evaluation metrics are used: Dice Score, Boundary Dice Score, and the 95th percentile of the Hausdorff distance. The method achieves mean Dice Score close to and above 0.9 for Task 1 and 3 respectively. The mean Hausdorff distance is close to 1.5 mm. This shows the method good accuracy and robustness. The qualitative results for Task 2 are unavailable at the moment of writing the manuscript.

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artykuł
#143473Data dodania: 15.11.2022
Deep learning-based framework for automatic cranial defect reconstruction and implant modeling / Marek WODZIŃSKI, Mateusz DANIOŁ, Mirosław SOCHA, Daria HEMMERLING, Maciej STANUCH, Andrzej SKALSKI // Computer Methods and Programs in Biomedicine ; ISSN  0169-2607 . — 2022 — vol. 226 art. no. 107173, s. 1–13. — Bibliogr. s. 12–13, Abstr. — Publikacja dostępna online od: 2022-10-11. — M. Wodziński - dod. afiliacje: MedApp S A., Krakow ; University of Applied Sciences Western Switzerland, Sierre, Switzerland; M. Danioł, M. Stanuch, A. Skalski - dod. afiliacja: MedApp S A., Krakow
artykuł
#147862Data dodania: 8.9.2023
Towards clinical applicability and computational efficiency in automatic cranial implant design: an overview of the AutoImplant 2021 cranial implant design challenge / Jianning Li, David G. Ellis, Oldřich Kodym, Laurèl Rauschenbach, Christoph Rieß, Ulrich Sure, Karsten H. Wrede, Carlos M. Alvarez, Marek WODZIŃSKI, Mateusz DANIOŁ, Daria HEMMERLING, Hamza Mahdi, Allison Clement, Evan Kim, Zachary Fishman, Cari M. Whyne, James G. Mainprize, Michael R. Hardisty, Shashwat Pathak, Chitimireddy Sindhura, Rama Krishna Sai S. Gorthi, Degala Venkata Kiran, Subrahmanyam Gorthi, Bokai Yang, Ke Fang, Xingyu Li, Artem Kroviakov, Lei Yu, Yuan Jin, Antonio Pepe, Christina Gsaxner, Adam Herout, Victor Alves, Michal Španěl, Michele R. Aizenberg, Jens Kleesiek, Jan Egger // Medical Image Analysis ; ISSN 1361-8415. — 2023 — vol. 88 art. no. 102865, s. 1–15. — Bibliogr. s. 14–15, Abstr. — Publikacja dostępna online od: 2023-06-09. — M. Wodziński - dod. afiliacja: University of Applied Sciences Western Switzerland (HES-SO Valais), Information Systems Institute, Sierre, Switzerland