Abnormal maxillary sinus diagnosing on CBCT images via object detection and ‘straight‐forward’ classification deep learning strategy

BackgroundPathological maxillary sinus would affect implant treatment and even result in failure of maxillary sinus lift and implant surgery. However, the maxillary sinus abnormalities are challenging to be diagnosed through CBCT images, especially for young dentists or dentists in grassroots medica...

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Bibliographic Details
Published in:Journal of oral rehabilitation 2023-12, Vol.50 (12), p.1465-1480
Main Authors: Zeng, Peisheng, Song, Rihui, Lin, Yixiong, Li, Haopeng, Chen, Shijie, Shi, Mengru, Cai, Gengbin, Gong, Zhuohong, Huang, Kai, Chen, Zetao
Format: Article
Language:English
Subjects:
Classification
Deep learning
Dental implants
Dentists
Maxillary sinus
Sinuses
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Summary:BackgroundPathological maxillary sinus would affect implant treatment and even result in failure of maxillary sinus lift and implant surgery. However, the maxillary sinus abnormalities are challenging to be diagnosed through CBCT images, especially for young dentists or dentists in grassroots medical institutions without systematical education of general medicine.ObjectivesTo develop a deep‐learning‐based screening model incorporating object detection and ‘straight‐forward’ classification strategy to screen out maxillary sinus abnormalities on CBCT images.MethodsThe large area of background noise outside maxillary sinus would affect the generalisation and prediction accuracy of the model, and the diversity and imbalanced distribution of imaging manifestations may bring challenges to intellectualization. Thus we adopted an object detection to limit model's observation zone and ‘straight‐forward’ classification strategy with various tuning methods to adapt to dental clinical need and extract typical features of diverse manifestations so that turn the task into a ‘normal‐or‐not’ classification.ResultsWe successfully constructed a deep‐learning model consist of well‐trained detector and diagnostor module. This model achieved ideal AUROC and AUPRC of 0.953 and 0.887, reaching more than 90% accuracy at optimal cut‐off. McNemar and Kappa test verified no statistical difference and high consistency between the prediction and ground truth. Dentist‐model comparison test showed the model's statistically higher diagnostic performance than dental students. Visualisation method confirmed the model's effectiveness in region recognition and feature extraction.ConclusionThe deep‐learning model incorporating object detection and straightforward classification strategy could achieve satisfying predictive performance for screening maxillary sinus abnormalities on CBCT images.
ISSN:0305-182X
1365-2842
DOI:10.1111/joor.13585