Artificial intelligent-driven decision-making for automating root fracture detection in periapical radiographs.

IF 2.5 Q2 DENTISTRY, ORAL SURGERY & MEDICINE

BDJ Open Pub Date : 2024-10-01 DOI:10.1038/s41405-024-00260-1

Riem Abdelazim, Eman M Fouad

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引用次数: 0

Abstract

Background: The detection and early diagnosis of root fractures can be challenging; this difficulty applies particularly to newly qualified dentists. Aside from clinical examination, diagnosis often requires radiographic assessment. Nonetheless, human fallibility can introduce errors due to a lack of experience.

Aim: The proposed system aimed to assist in detecting root fractures through the integration of artificial intelligence techniques into the diagnosis process as a step for automating dental diagnosis and decision-making processes.

Materials and method: A total of 400 radiographic images of fractured and unfractured teeth were obtained for the present research. Data handling techniques were implemented to balance the distribution of the samples. The AI-based system used the voting technique for five different pretrained models namely, VGG16, VGG19, ResNet50. DenseNet121, and DenseNet169 to perform the analysis. The parameters used for the analysis of the models are loss and accuracy curves.

Results: VGG16 exhibited notable success with low training and validation losses (0.09% and 0.18%, respectively), high specificity, sensitivity, and positive predictive value (PPV). VGG19 showed potential overfitting concerns, while ResNet50 displayed progress in minimizing loss but exhibited bias toward unfractured cases. DenseNet121 effectively addressed overfitting and noise issues, achieving balanced metrics and impressive PPVs for both fractured and unfractured cases (0.933 and 0.898 respectively). With increased depth, DenseNet169 demonstrated enhanced generalization capability.

Conclusion: The proposed AI- based system demonstrated high precision and sensitivity for detecting root fractures in endodontically treated teeth by utilizing the voting method.

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人工智能驱动决策，自动检测根尖周X光片中的根部断裂。

背景：牙根折断的检测和早期诊断具有挑战性；这一困难尤其适用于刚获得资格的牙科医生。除了临床检查外，诊断通常还需要进行放射评估。目的：所提议的系统旨在通过将人工智能技术整合到诊断过程中来协助检测牙根断裂，作为牙科诊断和决策过程自动化的一个步骤：本研究共获取了 400 张折断和未折断牙齿的放射影像。采用数据处理技术平衡样本分布。基于人工智能的系统使用了五种不同预训练模型的投票技术，即 VGG16、VGG19、ResNet50、DenseNet121 和 DenseNet121。DenseNet121 和 DenseNet169 进行分析。用于分析模型的参数是损失曲线和准确率曲线：VGG16 取得了显著的成功，训练和验证损失较低（分别为 0.09% 和 0.18%），特异性、灵敏度和阳性预测值（PPV）较高。VGG19 显示出潜在的过拟合问题，而 ResNet50 在最大限度减少损失方面取得了进展，但表现出偏向于未骨折病例。DenseNet 121 有效地解决了过拟合和噪声问题，实现了均衡的指标，并为断裂和未断裂病例提供了令人印象深刻的 PPV 值（分别为 0.933 和 0.898）。随着深度的增加，DenseNet169 显示出更强的泛化能力：本文提出的基于人工智能的系统利用投票法检测牙髓治疗牙根折断的精确度和灵敏度都很高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BDJ Open Dentistry-Dentistry (all)

CiteScore

3.70

自引率

3.30%

发文量

审稿时长

30 weeks