Deep learning for the identification of ridge deficiency around dental implants

IF 3.7 2区 医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE Clinical Implant Dentistry and Related Research Pub Date : 2023-12-27 DOI:10.1111/cid.13301
Cheng-Hung Lin, Hom-Lay Wang, Li-Wen Yu, Po-Yung Chou, Hao-Chieh Chang, Chin-Hao Chang, Po-Chun Chang
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Abstract

Objectives

This study aimed to use a deep learning (DL) approach for the automatic identification of the ridge deficiency around dental implants based on an image slice from cone-beam computerized tomography (CBCT).

Materials and methods

Single slices crossing the central long-axis of 630 mandibular and 845 maxillary virtually placed implants (4–5 mm diameter, 10 mm length) in 412 patients were used. The ridges were classified based on the intraoral bone-implant support and sinus floor location. The slices were either preprocessed by alveolar ridge homogenizing prior to DL (preprocessed) or left unpreprocessed. A convolutional neural network with ResNet-50 architecture was employed for DL.

Results

The model achieved an accuracy of >98.5% on the unpreprocessed image slices and was found to be superior to the accuracy observed on the preprocessed slices. On the mandible, model accuracy was 98.91 ± 1.45%, and F1 score, a measure of a model's accuracy in binary classification tasks, was lowest (97.30%) on the ridge with a combined horizontal-vertical defect. On the maxilla, model accuracy was 98.82 ± 1.11%, and the ridge presenting an implant collar-sinus floor distance of 5–10 mm with a dehiscence defect had the lowest F1 score (95.86%). To achieve >90% model accuracy, ≥441 mandibular slices or ≥592 maxillary slices were required.

Conclusions

The ridge deficiency around dental implants can be identified using DL from CBCT image slices without the need for preprocessed homogenization. The model will be further strengthened by implementing more clinical expertise in dental implant treatment planning and incorporating multiple slices to classify 3-dimensional implant-ridge relationships.

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深度学习用于识别牙科植入物周围的牙脊缺损。
研究目的本研究旨在使用深度学习(DL)方法,根据锥形束计算机断层扫描(CBCT)图像切片自动识别牙科种植体周围的牙脊缺损:使用了 412 名患者的 630 个下颌种植体和 845 个上颌种植体(直径 4-5 毫米,长度 10 毫米)的横跨中心长轴的单个切片。根据口内骨-种植体支撑和窦底位置对脊进行分类。切片在进行 DL(预处理)之前通过牙槽嵴均质化进行预处理,或者不进行预处理。采用 ResNet-50 架构的卷积神经网络进行 DL:结果:在未经处理的图像切片上,该模型的准确率大于 98.5%,优于在预处理切片上观察到的准确率。在下颌骨上,模型的准确率为 98.91 ± 1.45%,在具有水平和垂直联合缺损的脊上,衡量模型在二元分类任务中准确率的 F1 分数最低(97.30%)。在上颌骨上,模型准确率为 98.82 ± 1.11%,种植体领口-窦底距离为 5-10 mm 且存在开裂缺损的牙脊的 F1 得分最低(95.86%)。要达到大于 90% 的模型准确率,需要≥441 个下颌切片或≥592 个上颌切片:结论:使用 CBCT 图像切片的 DL 可以识别牙种植体周围的牙脊缺损,而无需预处理均质化。通过在牙科种植治疗规划中采用更多临床专业知识,并结合多切片对三维种植体-牙槽嵴关系进行分类,该模型将得到进一步加强。
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来源期刊
CiteScore
6.00
自引率
13.90%
发文量
103
审稿时长
4-8 weeks
期刊介绍: The goal of Clinical Implant Dentistry and Related Research is to advance the scientific and technical aspects relating to dental implants and related scientific subjects. Dissemination of new and evolving information related to dental implants and the related science is the primary goal of our journal. The range of topics covered by the journals will include but be not limited to: New scientific developments relating to bone Implant surfaces and their relationship to the surrounding tissues Computer aided implant designs Computer aided prosthetic designs Immediate implant loading Immediate implant placement Materials relating to bone induction and conduction New surgical methods relating to implant placement New materials and methods relating to implant restorations Methods for determining implant stability A primary focus of the journal is publication of evidenced based articles evaluating to new dental implants, techniques and multicenter studies evaluating these treatments. In addition basic science research relating to wound healing and osseointegration will be an important focus for the journal.
期刊最新文献
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