利用深度神经拼凑技术自动检测头颅测量标志。

IF 2.9 2区医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE

Dento maxillo facial radiology Pub Date : 2023-09-01 Epub Date: 2023-07-03 DOI:10.1259/dmfr.20230059

Julia Vera Weingart, Stefan Schlager, Marc Christian Metzger, Leonard Simon Brandenburg, Anna Hein, Rainer Schmelzeisen, Fabian Bamberg, Suam Kim, Elias Kellner, Marco Reisert, Maximilian Frederik Russe

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引用次数: 0

摘要

研究目的本研究评估了基于深度学习的分割框架--深度神经补丁（DNP）--在 CT 扫描中自动识别 60 个头颅测量标志（骨标志、软组织标志和牙标志）的准确性。目的是确定 DNP 是否可用于正颌外科和正畸诊断和治疗规划中的常规三维头颅测量分析：将 30 名成年患者（18 名女性，12 名男性，平均年龄 35.6 岁）的全头颅 CT 扫描随机分为训练数据集和测试数据集（各 n = 15）。临床医生 A 在所有 30 张 CT 扫描中标注了 60 个地标。临床医生 B 仅在测试数据集中标注了 60 个地标。DNP 使用每个地标的邻近组织的球形分割进行训练。通过计算预测结果的质心，在单独的测试数据集中创建了自动地标预测。通过将这些注释与人工注释进行比较，评估了该方法的准确性：结果：通过训练，DNP 成功识别了所有 60 个地标。我们方法的平均误差为 1.94 毫米（标准差为 1.45 毫米），而人工标注的平均误差为 1.32 毫米（标准差为 1.08 毫米）。地标 ANS 1.11 毫米、SN 1.2 毫米和 CP_R 1.25 毫米的误差最小：结论：DNP 算法能够准确识别头测量地标，其平均误差为

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Automated detection of cephalometric landmarks using deep neural patchworks.

Objectives: This study evaluated the accuracy of deep neural patchworks (DNPs), a deep learning-based segmentation framework, for automated identification of 60 cephalometric landmarks (bone-, soft tissue- and tooth-landmarks) on CT scans. The aim was to determine whether DNP could be used for routine three-dimensional cephalometric analysis in diagnostics and treatment planning in orthognathic surgery and orthodontics.

Methods: Full skull CT scans of 30 adult patients (18 female, 12 male, mean age 35.6 years) were randomly divided into a training and test data set (each n = 15). Clinician A annotated 60 landmarks in all 30 CT scans. Clinician B annotated 60 landmarks in the test data set only. The DNP was trained using spherical segmentations of the adjacent tissue for each landmark. Automated landmark predictions in the separate test data set were created by calculating the center of mass of the predictions. The accuracy of the method was evaluated by comparing these annotations to the manual annotations.

Results: The DNP was successfully trained to identify all 60 landmarks. The mean error of our method was 1.94 mm (SD 1.45 mm) compared to a mean error of 1.32 mm (SD 1.08 mm) for manual annotations. The minimum error was found for landmarks ANS 1.11 mm, SN 1.2 mm, and CP_R 1.25 mm.

Conclusion: The DNP-algorithm was able to accurately identify cephalometric landmarks with mean errors <2 mm. This method could improve the workflow of cephalometric analysis in orthodontics and orthognathic surgery. Low training requirements while still accomplishing high precision make this method particularly promising for clinical use.

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来源期刊

Dento maxillo facial radiology 医学-核医学

CiteScore

5.60

自引率

9.10%

发文量

审稿时长

4-8 weeks

期刊介绍： Dentomaxillofacial Radiology (DMFR) is the journal of the International Association of Dentomaxillofacial Radiology (IADMFR) and covers the closely related fields of oral radiology and head and neck imaging. Established in 1972, DMFR is a key resource keeping dentists, radiologists and clinicians and scientists with an interest in Head and Neck imaging abreast of important research and developments in oral and maxillofacial radiology. The DMFR editorial board features a panel of international experts including Editor-in-Chief Professor Ralf Schulze. Our editorial board provide their expertise and guidance in shaping the content and direction of the journal. Quick Facts: - 2015 Impact Factor - 1.919 - Receipt to first decision - average of 3 weeks - Acceptance to online publication - average of 3 weeks - Open access option - ISSN: 0250-832X - eISSN: 1476-542X