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International Journal of Computer Assisted Radiology and Surgery
Published in:

Open Access 08-06-2024 | Multiple Sclerosis | Original Article

Self-supervised learning for classifying paranasal anomalies in the maxillary sinus

Authors: Debayan Bhattacharya, Finn Behrendt, Benjamin Tobias Becker, Lennart Maack, Dirk Beyersdorff, Elina Petersen, Marvin Petersen, Bastian Cheng, Dennis Eggert, Christian Betz, Anna Sophie Hoffmann, Alexander Schlaefer

Published in: International Journal of Computer Assisted Radiology and Surgery | Issue 9/2024

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Abstract

Purpose

Paranasal anomalies, frequently identified in routine radiological screenings, exhibit diverse morphological characteristics. Due to the diversity of anomalies, supervised learning methods require large labelled dataset exhibiting diverse anomaly morphology. Self-supervised learning (SSL) can be used to learn representations from unlabelled data. However, there are no SSL methods designed for the downstream task of classifying paranasal anomalies in the maxillary sinus (MS).

Methods

Our approach uses a 3D convolutional autoencoder (CAE) trained in an unsupervised anomaly detection (UAD) framework. Initially, we train the 3D CAE to reduce reconstruction errors when reconstructing normal maxillary sinus (MS) image. Then, this CAE is applied to an unlabelled dataset to generate coarse anomaly locations by creating residual MS images. Following this, a 3D convolutional neural network (CNN) reconstructs these residual images, which forms our SSL task. Lastly, we fine-tune the encoder part of the 3D CNN on a labelled dataset of normal and anomalous MS images.

Results

The proposed SSL technique exhibits superior performance compared to existing generic self-supervised methods, especially in scenarios with limited annotated data. When trained on just 10% of the annotated dataset, our method achieves an area under the precision-recall curve (AUPRC) of 0.79 for the downstream classification task. This performance surpasses other methods, with BYOL attaining an AUPRC of 0.75, SimSiam at 0.74, SimCLR at 0.73 and masked autoencoding using SparK at 0.75.

Conclusion

A self-supervised learning approach that inherently focuses on localizing paranasal anomalies proves to be advantageous, particularly when the subsequent task involves differentiating normal from anomalous maxillary sinuses. Access our code at https://​github.​com/​mtec-tuhh/​self-supervised-paranasal-anomaly.
Appendix
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Footnotes
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Metadata
Title
Self-supervised learning for classifying paranasal anomalies in the maxillary sinus
Authors
Debayan Bhattacharya
Finn Behrendt
Benjamin Tobias Becker
Lennart Maack
Dirk Beyersdorff
Elina Petersen
Marvin Petersen
Bastian Cheng
Dennis Eggert
Christian Betz
Anna Sophie Hoffmann
Alexander Schlaefer
Publication date
08-06-2024
Publisher
Springer International Publishing
Published in
International Journal of Computer Assisted Radiology and Surgery / Issue 9/2024
Print ISSN: 1861-6410
Electronic ISSN: 1861-6429
DOI
https://doi.org/10.1007/s11548-024-03172-5

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