Abstract
Extraction of mandibular third molars is a common procedure in oral and maxillofacial surgery. There are studies that simultaneously predict the extraction difficulty of mandibular third molar and the complications that may occur. Thus, we propose a method of automatically detecting mandibular third molars in the panoramic radiographic images and predicting the extraction difficulty and likelihood of inferior alveolar nerve (IAN) injury. Our dataset consists of 4903 panoramic radiographic images acquired from various dental hospitals. Seven dentists annotated detection and classification labels. The detection model determines the mandibular third molar in the panoramic radiographic image. The region of interest (ROI) includes the detected mandibular third molar, adjacent teeth, and IAN, which is cropped in the panoramic radiographic image. The classification models use ROI as input to predict the extraction difficulty and likelihood of IAN injury. The achieved detection performance was 99.0% mAP over the intersection of union (IOU) 0.5. In addition, we achieved an 83.5% accuracy for the prediction of extraction difficulty and an 81.1% accuracy for the prediction of the likelihood of IAN injury. We demonstrated that a deep learning method can support the diagnosis for extracting the mandibular third molar.
Highlights
IntroductionDeep learning is frequently applied in the medical field and shows high performance [4,5,6]
We propose a model that uses a deep neural network to predict the extraction difficulty of mandibular third molars and the likelihood of inferior alveolar nerve (IAN) injury
The detection performance of the mandibular third molar is indicated in the panoramic radiographic image by the values mean average precision (mAP) [0.5], mAP [0.7], and mAP = [0.5:0.95]
Summary
Deep learning is frequently applied in the medical field and shows high performance [4,5,6]. Deep learning is widely used to predict and diagnose diseases through image data such as MRI and CT images and signal data such as EEGs [7,8,9]. It can be applied in the field of dentistry for the automatic diagnosis of various diseases [10,11,12,13]. This has been applied to many studies, such as classifying cystic lesions in cone beam computed tomography (CBCT) images and estimating a person’s age through their teeth [14,15]
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