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 Wodzinski; Mateusz Daniol; 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

doi:10.1016/j.media.2023.102865

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 Wodzinski, Mateusz Daniol, Daria Hemmerling, Hamza Mahdi, Allison Clement, Evan Kim, Zachary Fishman, Cari M. Whyne, James G. Mainprize, Michael R. Hardisty, Shashwat Pathak, Chitimireddy SindhuraRama 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^*

^*Corresponding author for this work

Institute of Computer Graphics and Vision (7100)

Research output: Contribution to journal › Short survey › peer-review

Abstract

Cranial implants are commonly used for surgical repair of craniectomy-induced skull defects. These implants are usually generated offline and may require days to weeks to be available. An automated implant design process combined with onsite manufacturing facilities can guarantee immediate implant availability and avoid secondary intervention. To address this need, the AutoImplant II challenge was organized in conjunction with MICCAI 2021, catering for the unmet clinical and computational requirements of automatic cranial implant design. The first edition of AutoImplant (AutoImplant I, 2020) demonstrated the general capabilities and effectiveness of data-driven approaches, including deep learning, for a skull shape completion task on synthetic defects. The second AutoImplant challenge (i.e., AutoImplant II, 2021) built upon the first by adding real clinical craniectomy cases as well as additional synthetic imaging data. The AutoImplant II challenge consisted of three tracks. Tracks 1 and 3 used skull images with synthetic defects to evaluate the ability of submitted approaches to generate implants that recreate the original skull shape. Track 3 consisted of the data from the first challenge (i.e., 100 cases for training, and 110 for evaluation), and Track 1 provided 570 training and 100 validation cases aimed at evaluating skull shape completion algorithms at diverse defect patterns. Track 2 also made progress over the first challenge by providing 11 clinically defective skulls and evaluating the submitted implant designs on these clinical cases. The submitted designs were evaluated quantitatively against imaging data from post-craniectomy as well as by an experienced neurosurgeon. Submissions to these challenge tasks made substantial progress in addressing issues such as generalizability, computational efficiency, data augmentation, and implant refinement. This paper serves as a comprehensive summary and comparison of the submissions to the AutoImplant II challenge. Codes and models are available at https://github.com/Jianningli/Autoimplant_II.

Original language	English
Article number	102865
Journal	Medical Image Analysis
Volume	88
DOIs	https://doi.org/10.1016/j.media.2023.102865
Publication status	Published - Aug 2023

Keywords

AutoImplant II
Cranial implant design
Craniectomy
Cranioplasty
Deep learning
Shape completion
Sparse convolutional neural networks

ASJC Scopus subject areas

Radiological and Ultrasound Technology
Radiology Nuclear Medicine and imaging
Computer Vision and Pattern Recognition
Health Informatics
Computer Graphics and Computer-Aided Design

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10.1016/j.media.2023.102865

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Li, J., Ellis, D. G., Kodym, O., Rauschenbach, L., Rieß, C., Sure, U., Wrede, K. H., Alvarez, C. M., Wodzinski, M., Daniol, M., Hemmerling, D., Mahdi, H., Clement, A., Kim, E., Fishman, Z., Whyne, C. M., Mainprize, J. G., Hardisty, M. R., Pathak, S., ... Egger, J. (2023). Towards clinical applicability and computational efficiency in automatic cranial implant design: An overview of the AutoImplant 2021 cranial implant design challenge. Medical Image Analysis, 88, Article 102865. https://doi.org/10.1016/j.media.2023.102865

Li, J, Ellis, DG, Kodym, O, Rauschenbach, L, Rieß, C, Sure, U, Wrede, KH, Alvarez, CM, Wodzinski, M, Daniol, M, Hemmerling, D, Mahdi, H, Clement, A, Kim, E, Fishman, Z, Whyne, CM, Mainprize, JG, Hardisty, MR, Pathak, S, Sindhura, C, Gorthi, RKSS, Kiran, DV, Gorthi, S, Yang, B, Fang, K, Li, X, Kroviakov, A, Yu, L, Jin, Y, Pepe, A, Gsaxner, C, Herout, A, Alves, V, Španěl, M, Aizenberg, MR, Kleesiek, J & Egger, J 2023, 'Towards clinical applicability and computational efficiency in automatic cranial implant design: An overview of the AutoImplant 2021 cranial implant design challenge', Medical Image Analysis, vol. 88, 102865. https://doi.org/10.1016/j.media.2023.102865

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title = "Towards clinical applicability and computational efficiency in automatic cranial implant design: An overview of the AutoImplant 2021 cranial implant design challenge",

abstract = "Cranial implants are commonly used for surgical repair of craniectomy-induced skull defects. These implants are usually generated offline and may require days to weeks to be available. An automated implant design process combined with onsite manufacturing facilities can guarantee immediate implant availability and avoid secondary intervention. To address this need, the AutoImplant II challenge was organized in conjunction with MICCAI 2021, catering for the unmet clinical and computational requirements of automatic cranial implant design. The first edition of AutoImplant (AutoImplant I, 2020) demonstrated the general capabilities and effectiveness of data-driven approaches, including deep learning, for a skull shape completion task on synthetic defects. The second AutoImplant challenge (i.e., AutoImplant II, 2021) built upon the first by adding real clinical craniectomy cases as well as additional synthetic imaging data. The AutoImplant II challenge consisted of three tracks. Tracks 1 and 3 used skull images with synthetic defects to evaluate the ability of submitted approaches to generate implants that recreate the original skull shape. Track 3 consisted of the data from the first challenge (i.e., 100 cases for training, and 110 for evaluation), and Track 1 provided 570 training and 100 validation cases aimed at evaluating skull shape completion algorithms at diverse defect patterns. Track 2 also made progress over the first challenge by providing 11 clinically defective skulls and evaluating the submitted implant designs on these clinical cases. The submitted designs were evaluated quantitatively against imaging data from post-craniectomy as well as by an experienced neurosurgeon. Submissions to these challenge tasks made substantial progress in addressing issues such as generalizability, computational efficiency, data augmentation, and implant refinement. This paper serves as a comprehensive summary and comparison of the submissions to the AutoImplant II challenge. Codes and models are available at https://github.com/Jianningli/Autoimplant_II.",

keywords = "AutoImplant II, Cranial implant design, Craniectomy, Cranioplasty, Deep learning, Shape completion, Sparse convolutional neural networks",

author = "Jianning Li and Ellis, {David G.} and Old{\v r}ich Kodym and Laur{\`e}l Rauschenbach and Christoph Rie{\ss} and Ulrich Sure and Wrede, {Karsten H.} and Alvarez, {Carlos M.} and Marek Wodzinski and Mateusz Daniol and Daria Hemmerling and Hamza Mahdi and Allison Clement and Evan Kim and Zachary Fishman and Whyne, {Cari M.} and Mainprize, {James G.} and Hardisty, {Michael R.} and Shashwat Pathak and Chitimireddy Sindhura and Gorthi, {Rama Krishna Sai S.} and Kiran, {Degala Venkata} and Subrahmanyam Gorthi and Bokai Yang and Ke Fang and Xingyu Li and Artem Kroviakov and Lei Yu and Yuan Jin and Antonio Pepe and Christina Gsaxner and Adam Herout and Victor Alves and Michal {\v S}pan{\v e}l and Aizenberg, {Michele R.} and Jens Kleesiek and Jan Egger",

note = "Publisher Copyright: {\textcopyright} 2023 Elsevier B.V.",

year = "2023",

month = aug,

doi = "10.1016/j.media.2023.102865",

language = "English",

volume = "88",

journal = "Medical Image Analysis",

issn = "1361-8415",

publisher = "Elsevier B.V.",

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TY - JOUR

T1 - Towards clinical applicability and computational efficiency in automatic cranial implant design

T2 - An overview of the AutoImplant 2021 cranial implant design challenge

AU - Li, Jianning

AU - Ellis, David G.

AU - Kodym, Oldřich

AU - Rauschenbach, Laurèl

AU - Rieß, Christoph

AU - Sure, Ulrich

AU - Wrede, Karsten H.

AU - Alvarez, Carlos M.

AU - Wodzinski, Marek

AU - Daniol, Mateusz

AU - Hemmerling, Daria

AU - Mahdi, Hamza

AU - Clement, Allison

AU - Kim, Evan

AU - Fishman, Zachary

AU - Whyne, Cari M.

AU - Mainprize, James G.

AU - Hardisty, Michael R.

AU - Pathak, Shashwat

AU - Sindhura, Chitimireddy

AU - Gorthi, Rama Krishna Sai S.

AU - Kiran, Degala Venkata

AU - Gorthi, Subrahmanyam

AU - Yang, Bokai

AU - Fang, Ke

AU - Li, Xingyu

AU - Kroviakov, Artem

AU - Yu, Lei

AU - Jin, Yuan

AU - Pepe, Antonio

AU - Gsaxner, Christina

AU - Herout, Adam

AU - Alves, Victor

AU - Španěl, Michal

AU - Aizenberg, Michele R.

AU - Kleesiek, Jens

AU - Egger, Jan

PY - 2023/8

Y1 - 2023/8

N2 - Cranial implants are commonly used for surgical repair of craniectomy-induced skull defects. These implants are usually generated offline and may require days to weeks to be available. An automated implant design process combined with onsite manufacturing facilities can guarantee immediate implant availability and avoid secondary intervention. To address this need, the AutoImplant II challenge was organized in conjunction with MICCAI 2021, catering for the unmet clinical and computational requirements of automatic cranial implant design. The first edition of AutoImplant (AutoImplant I, 2020) demonstrated the general capabilities and effectiveness of data-driven approaches, including deep learning, for a skull shape completion task on synthetic defects. The second AutoImplant challenge (i.e., AutoImplant II, 2021) built upon the first by adding real clinical craniectomy cases as well as additional synthetic imaging data. The AutoImplant II challenge consisted of three tracks. Tracks 1 and 3 used skull images with synthetic defects to evaluate the ability of submitted approaches to generate implants that recreate the original skull shape. Track 3 consisted of the data from the first challenge (i.e., 100 cases for training, and 110 for evaluation), and Track 1 provided 570 training and 100 validation cases aimed at evaluating skull shape completion algorithms at diverse defect patterns. Track 2 also made progress over the first challenge by providing 11 clinically defective skulls and evaluating the submitted implant designs on these clinical cases. The submitted designs were evaluated quantitatively against imaging data from post-craniectomy as well as by an experienced neurosurgeon. Submissions to these challenge tasks made substantial progress in addressing issues such as generalizability, computational efficiency, data augmentation, and implant refinement. This paper serves as a comprehensive summary and comparison of the submissions to the AutoImplant II challenge. Codes and models are available at https://github.com/Jianningli/Autoimplant_II.

AB - Cranial implants are commonly used for surgical repair of craniectomy-induced skull defects. These implants are usually generated offline and may require days to weeks to be available. An automated implant design process combined with onsite manufacturing facilities can guarantee immediate implant availability and avoid secondary intervention. To address this need, the AutoImplant II challenge was organized in conjunction with MICCAI 2021, catering for the unmet clinical and computational requirements of automatic cranial implant design. The first edition of AutoImplant (AutoImplant I, 2020) demonstrated the general capabilities and effectiveness of data-driven approaches, including deep learning, for a skull shape completion task on synthetic defects. The second AutoImplant challenge (i.e., AutoImplant II, 2021) built upon the first by adding real clinical craniectomy cases as well as additional synthetic imaging data. The AutoImplant II challenge consisted of three tracks. Tracks 1 and 3 used skull images with synthetic defects to evaluate the ability of submitted approaches to generate implants that recreate the original skull shape. Track 3 consisted of the data from the first challenge (i.e., 100 cases for training, and 110 for evaluation), and Track 1 provided 570 training and 100 validation cases aimed at evaluating skull shape completion algorithms at diverse defect patterns. Track 2 also made progress over the first challenge by providing 11 clinically defective skulls and evaluating the submitted implant designs on these clinical cases. The submitted designs were evaluated quantitatively against imaging data from post-craniectomy as well as by an experienced neurosurgeon. Submissions to these challenge tasks made substantial progress in addressing issues such as generalizability, computational efficiency, data augmentation, and implant refinement. This paper serves as a comprehensive summary and comparison of the submissions to the AutoImplant II challenge. Codes and models are available at https://github.com/Jianningli/Autoimplant_II.

KW - AutoImplant II

KW - Cranial implant design

KW - Craniectomy

KW - Cranioplasty

KW - Deep learning

KW - Shape completion

KW - Sparse convolutional neural networks

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U2 - 10.1016/j.media.2023.102865

DO - 10.1016/j.media.2023.102865

M3 - Short survey

AN - SCOPUS:85162086381

SN - 1361-8415

VL - 88

JO - Medical Image Analysis

JF - Medical Image Analysis

M1 - 102865

ER -

Towards clinical applicability and computational efficiency in automatic cranial implant design: An overview of the AutoImplant 2021 cranial implant design challenge

Abstract

Keywords

ASJC Scopus subject areas

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