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
N1 - Publisher Copyright:
© 2023 Elsevier B.V.
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
UR - http://www.scopus.com/inward/record.url?scp=85162086381&partnerID=8YFLogxK
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 -