基于人工智能的全景片上颌埋伏尖牙的自动预处理和分类。
Artificial intelligence-based automated preprocessing and classification of impacted maxillary canines in panoramic radiographs.
机构信息
Department of Orthodontics, Hamdan Bin Mohammed College of Dental Medicine, Mohammed Bin Rashid University of Medicine and Health Sciences, Dubai, 505055, United Arab Emirates.
Oudari Consultancy, West Bengal, 712246, India.
出版信息
Dentomaxillofac Radiol. 2024 Mar 25;53(3):173-177. doi: 10.1093/dmfr/twae005.
OBJECTIVES
Automating the digital workflow for diagnosing impacted canines using panoramic radiographs (PRs) is challenging. This study explored feature extraction, automated cropping, and classification of impacted and nonimpacted canines as a first step.
METHODS
A convolutional neural network with SqueezeNet architecture was first trained to classify two groups of PRs (91with and 91without impacted canines) on the MATLAB programming platform. Based on results, the need to crop the PRs was realized. Next, artificial intelligence (AI) detectors were trained to identify specific landmarks (maxillary central incisors, lateral incisors, canines, bicuspids, nasal area, and the mandibular ramus) on the PRs. Landmarks were then explored to guide cropping of the PRs. Finally, improvements in classification of automatically cropped PRs were studied.
RESULTS
Without cropping, the area under the curve (AUC) of the receiver operating characteristic (ROC) curve for classifying impacted and nonimpacted canine was 84%. Landmark training showed that detectors could correctly identify upper central incisors and the ramus in ∼98% of PRs. The combined use of the mandibular ramus and maxillary central incisors as guides for cropping yielded the best results (∼10% incorrect cropping). When automatically cropped PRs were used, the AUC-ROC improved to 96%.
CONCLUSIONS
AI algorithms can be automated to preprocess PRs and improve the identification of impacted canines.
目的
使用全景放射照片(PR)自动诊断阻生犬是具有挑战性的。本研究探索了特征提取、自动裁剪和分类的方法,以作为第一步。
方法
首先在 MATLAB 编程平台上使用 SqueezeNet 架构的卷积神经网络对两组 PR(91 张有和 91 张无阻生犬的 PR)进行分类。根据结果,实现了裁剪 PR 的需求。接下来,训练人工智能(AI)探测器以识别 PR 上的特定地标(上颌中切牙、侧切牙、犬牙、双尖牙、鼻区和下颌支)。然后探索地标以指导 PR 的裁剪。最后,研究了自动裁剪 PR 的分类改进。
结果
不裁剪时,用于分类阻生和非阻生犬的接收器操作特征(ROC)曲线下面积(AUC)为 84%。地标训练表明,探测器可以正确识别上颌中切牙和下颌支中的约 98%的 PR。将下颌支和上颌中切牙联合用作裁剪指南可获得最佳效果(约 10%裁剪错误)。当使用自动裁剪的 PR 时,AUC-ROC 提高到 96%。
结论
可以自动化 AI 算法来预处理 PR 并提高阻生犬的识别能力。
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