A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge

Jianning Li; Antonio Pepe; Christina Schwarz-Gsaxner; Gord von Campe; Jan Egger

doi:https://doi.org/10.1007/978-3-030-60946-7_8

A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge

Jianning Li, Antonio Pepe, Christina Schwarz-Gsaxner, Gord von Campe, Jan Egger

Institute of Computer Graphics and Vision (7100)

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › peer-review

Abstract

In this study, we present a baseline approach for AutoImplant (https://autoimplant.grand-challenge.org/) – the cranial implant design challenge, which can be formulated as a volumetric shape learning task. In this task, the defective skull, the complete skull and the cranial implant are represented as binary voxel grids. To accomplish this task, the implant can be either reconstructed directly from the defective skull or obtained by taking the difference between a defective skull and a complete skull. In the latter case, a complete skull has to be reconstructed given a defective skull, which defines a volumetric shape completion problem. Our baseline approach for this task is based on the former formulation, i.e., a deep neural network is trained to predict the implants directly from the defective skulls. The approach generates high-quality implants in two steps: First, an encoder-decoder network learns a coarse representation of the implant from downsampled, defective skulls; The coarse implant is only used to generate the bounding box of the defected region in the original high-resolution skull. Second, another encoder-decoder network is trained to generate a fine implant from the bounded area. On the test set, the proposed approach achieves an average dice similarity score (DSC) of 0.8555 and Hausdorff distance (HD) of 5.1825 mm. The codes are available at https://github.com/Jianningli/autoimplant.

Original language	English
Title of host publication	Multimodal Learning for Clinical Decision Support and Clinical Image-Based Procedures
Subtitle of host publication	10th International Workshop, ML-CDS 2020, and 9th International Workshop, CLIP 2020, Held in Conjunction with MICCAI 2020, Proceedings
Editors	Tanveer Syeda-Mahmood, Klaus Drechsler, Hayit Greenspan, Anant Madabhushi, Alexandros Karargyris, Cristina Oyarzun Laura, Stefan Wesarg, Marius George Linguraru, Raj Shekhar, Marius Erdt, Miguel Ángel González Ballester
Publisher	Springer, Cham
Pages	75-84
Number of pages	10
Volume	12445
Edition	1
ISBN (Electronic)	978-3-030-60946-7
ISBN (Print)	978-3-030-60945-0
DOIs	https://doi.org/10.1007/978-3-030-60946-7_8
Publication status	Published - 1 Jan 2020
Event	2020 Workshop on Clinical Image-Based Procedures: in Conjunction with MICCAI 2020 - Virtual, Virtuell, Peru Duration: 4 Oct 2020 → 8 Oct 2020 https://miccai-clip.org/

Publication series

Name	Lecture Notes in Computer Science
Volume	12445
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Conference

Conference	2020 Workshop on Clinical Image-Based Procedures
Abbreviated title	CLIP 2020
Country/Territory	Peru
City	Virtuell
Period	4/10/20 → 8/10/20
Internet address	https://miccai-clip.org/

Keywords

deep learning
skull reconstruction
shape completion
Deep learning
Shape learning
Cranial implant design
Cranioplasty
Skull reconstruction
Volumetric shape completion

ASJC Scopus subject areas

Theoretical Computer Science
General Computer Science

Access to Document

https://doi.org/10.1007/978-3-030-60946-7_8

Cite this

Li, J., Pepe, A., Schwarz-Gsaxner, C., von Campe, G., & Egger, J. (2020). A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge. In T. Syeda-Mahmood, K. Drechsler, H. Greenspan, A. Madabhushi, A. Karargyris, C. Oyarzun Laura, S. Wesarg, M. G. Linguraru, R. Shekhar, M. Erdt, & M. Á. González Ballester (Eds.), Multimodal Learning for Clinical Decision Support and Clinical Image-Based Procedures : 10th International Workshop, ML-CDS 2020, and 9th International Workshop, CLIP 2020, Held in Conjunction with MICCAI 2020, Proceedings (1 ed., Vol. 12445, pp. 75-84). (Lecture Notes in Computer Science ; Vol. 12445 ). Springer, Cham. https://doi.org/10.1007/978-3-030-60946-7_8

A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge. / Li, Jianning; Pepe, Antonio; Schwarz-Gsaxner, Christina et al.
Multimodal Learning for Clinical Decision Support and Clinical Image-Based Procedures : 10th International Workshop, ML-CDS 2020, and 9th International Workshop, CLIP 2020, Held in Conjunction with MICCAI 2020, Proceedings. ed. / Tanveer Syeda-Mahmood; Klaus Drechsler; Hayit Greenspan; Anant Madabhushi; Alexandros Karargyris; Cristina Oyarzun Laura; Stefan Wesarg; Marius George Linguraru; Raj Shekhar; Marius Erdt; Miguel Ángel González Ballester. Vol. 12445 1. ed. Springer, Cham, 2020. p. 75-84 (Lecture Notes in Computer Science ; Vol. 12445 ).

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › peer-review

Li, J, Pepe, A, Schwarz-Gsaxner, C, von Campe, G & Egger, J 2020, A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge. in T Syeda-Mahmood, K Drechsler, H Greenspan, A Madabhushi, A Karargyris, C Oyarzun Laura, S Wesarg, MG Linguraru, R Shekhar, M Erdt & MÁ González Ballester (eds), Multimodal Learning for Clinical Decision Support and Clinical Image-Based Procedures : 10th International Workshop, ML-CDS 2020, and 9th International Workshop, CLIP 2020, Held in Conjunction with MICCAI 2020, Proceedings. 1 edn, vol. 12445, Lecture Notes in Computer Science , vol. 12445 , Springer, Cham, pp. 75-84, 2020 Workshop on Clinical Image-Based Procedures, Virtuell, Peru, 4/10/20. https://doi.org/10.1007/978-3-030-60946-7_8

Li J, Pepe A, Schwarz-Gsaxner C, von Campe G, Egger J. A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge. In Syeda-Mahmood T, Drechsler K, Greenspan H, Madabhushi A, Karargyris A, Oyarzun Laura C, Wesarg S, Linguraru MG, Shekhar R, Erdt M, González Ballester MÁ, editors, Multimodal Learning for Clinical Decision Support and Clinical Image-Based Procedures : 10th International Workshop, ML-CDS 2020, and 9th International Workshop, CLIP 2020, Held in Conjunction with MICCAI 2020, Proceedings. 1 ed. Vol. 12445. Springer, Cham. 2020. p. 75-84. (Lecture Notes in Computer Science ). doi: https://doi.org/10.1007/978-3-030-60946-7_8

Li, Jianning ; Pepe, Antonio ; Schwarz-Gsaxner, Christina et al. / A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge. Multimodal Learning for Clinical Decision Support and Clinical Image-Based Procedures : 10th International Workshop, ML-CDS 2020, and 9th International Workshop, CLIP 2020, Held in Conjunction with MICCAI 2020, Proceedings. editor / Tanveer Syeda-Mahmood ; Klaus Drechsler ; Hayit Greenspan ; Anant Madabhushi ; Alexandros Karargyris ; Cristina Oyarzun Laura ; Stefan Wesarg ; Marius George Linguraru ; Raj Shekhar ; Marius Erdt ; Miguel Ángel González Ballester. Vol. 12445 1. ed. Springer, Cham, 2020. pp. 75-84 (Lecture Notes in Computer Science ).

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title = "A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge",

abstract = "In this study, we present a baseline approach for AutoImplant (https://autoimplant.grand-challenge.org/) – the cranial implant design challenge, which can be formulated as a volumetric shape learning task. In this task, the defective skull, the complete skull and the cranial implant are represented as binary voxel grids. To accomplish this task, the implant can be either reconstructed directly from the defective skull or obtained by taking the difference between a defective skull and a complete skull. In the latter case, a complete skull has to be reconstructed given a defective skull, which defines a volumetric shape completion problem. Our baseline approach for this task is based on the former formulation, i.e., a deep neural network is trained to predict the implants directly from the defective skulls. The approach generates high-quality implants in two steps: First, an encoder-decoder network learns a coarse representation of the implant from downsampled, defective skulls; The coarse implant is only used to generate the bounding box of the defected region in the original high-resolution skull. Second, another encoder-decoder network is trained to generate a fine implant from the bounded area. On the test set, the proposed approach achieves an average dice similarity score (DSC) of 0.8555 and Hausdorff distance (HD) of 5.1825 mm. The codes are available at https://github.com/Jianningli/autoimplant.",

keywords = "deep learning, skull reconstruction, shape completion, Deep learning, Shape learning, Cranial implant design, Cranioplasty, Skull reconstruction, Volumetric shape completion",

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N2 - In this study, we present a baseline approach for AutoImplant (https://autoimplant.grand-challenge.org/) – the cranial implant design challenge, which can be formulated as a volumetric shape learning task. In this task, the defective skull, the complete skull and the cranial implant are represented as binary voxel grids. To accomplish this task, the implant can be either reconstructed directly from the defective skull or obtained by taking the difference between a defective skull and a complete skull. In the latter case, a complete skull has to be reconstructed given a defective skull, which defines a volumetric shape completion problem. Our baseline approach for this task is based on the former formulation, i.e., a deep neural network is trained to predict the implants directly from the defective skulls. The approach generates high-quality implants in two steps: First, an encoder-decoder network learns a coarse representation of the implant from downsampled, defective skulls; The coarse implant is only used to generate the bounding box of the defected region in the original high-resolution skull. Second, another encoder-decoder network is trained to generate a fine implant from the bounded area. On the test set, the proposed approach achieves an average dice similarity score (DSC) of 0.8555 and Hausdorff distance (HD) of 5.1825 mm. The codes are available at https://github.com/Jianningli/autoimplant.

AB - In this study, we present a baseline approach for AutoImplant (https://autoimplant.grand-challenge.org/) – the cranial implant design challenge, which can be formulated as a volumetric shape learning task. In this task, the defective skull, the complete skull and the cranial implant are represented as binary voxel grids. To accomplish this task, the implant can be either reconstructed directly from the defective skull or obtained by taking the difference between a defective skull and a complete skull. In the latter case, a complete skull has to be reconstructed given a defective skull, which defines a volumetric shape completion problem. Our baseline approach for this task is based on the former formulation, i.e., a deep neural network is trained to predict the implants directly from the defective skulls. The approach generates high-quality implants in two steps: First, an encoder-decoder network learns a coarse representation of the implant from downsampled, defective skulls; The coarse implant is only used to generate the bounding box of the defected region in the original high-resolution skull. Second, another encoder-decoder network is trained to generate a fine implant from the bounded area. On the test set, the proposed approach achieves an average dice similarity score (DSC) of 0.8555 and Hausdorff distance (HD) of 5.1825 mm. The codes are available at https://github.com/Jianningli/autoimplant.

KW - deep learning

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KW - Shape learning

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KW - Cranioplasty

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A2 - Wesarg, Stefan

A2 - Linguraru, Marius George

A2 - Shekhar, Raj

A2 - Erdt, Marius

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PB - Springer, Cham

T2 - 2020 Workshop on Clinical Image-Based Procedures

Y2 - 4 October 2020 through 8 October 2020

ER -

A baseline approach for autoimplant: the MICCAI 2020 cranial implant design challenge

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

Access to Document

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