Enhanced diagnosis of pes planus and pes cavus using deep learning-based segmentation of weight-bearing lateral foot radiographs: a comparative observer study.

IF 3.2 4区医学 Q2 ENGINEERING, BIOMEDICAL Biomedical Engineering Letters Pub Date : 2024-11-05 eCollection Date: 2025-01-01 DOI:10.1007/s13534-024-00439-3

Seung Min Ryu, Keewon Shin, Soo Wung Shin, Sun Ho Lee, Su Min Seo, Seung Hong Koh, Seung-Ah Ryu, Ki-Hong Kim, Jeong Hwan Ko, Chang Hyun Doh, Young Rak Choi, Namkug Kim

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Abstract

A weight-bearing lateral radiograph (WBLR) of the foot is a gold standard for diagnosing adult-acquired flatfoot deformity. However, it is difficult to measure the major axis of bones in WBLR without using auxiliary lines. Herein, we develop semantic segmentation with a deep learning model (DLm) on the WBLR of the foot for enhanced diagnosis of pes planus and pes cavus. We used 300 consecutive WBLRs from young Korean males. The semantic segmentation model was developed based on U²-Net. An expert orthopedic surgeon manually labeled ground truths. We used 200 radiographs for training, 100 for internal validation, and two external datasets for external validation. The model was trained using a hybrid loss function, combining Dice Loss and boundary-based loss, to enhance both overall segmentation accuracy and precise delineation of boundary regions between pes planus and pes cavus. Angle measurement errors with minimum moment of inertia (MMI) and ellipsoidal fitting (EF) based on the segmentation results were evaluated. The DLm exhibited better results than human observers. For internal validation, the absolute angle errors of the DLm using MMI and EF were 0.92 ± 1.32° and 1.34 ± 2.07°, respectively. In external validation, these errors were 1.17 ± 1.60° and 1.60 ± 2.42° for AMC's dataset, and 1.23 ± 1.39° and 1.68 ± 1.98° for the LERA dataset, respectively. The DLm showed higher overall diagnostic accuracy than human observers in identifying flatfoot angles, regardless of the measurement methods. The absolute angle errors and diagnostic accuracy of the developed DLm are superior to those of the three human observers. Furthermore, when comparing the angle measurement methods within the DLm, the MMI method proves to be more accurate than EF. Finally, the proposed deep learning model, particularly with the implementation of the U²-Net demonstrates enhanced boundary segmentation and achieves sufficient external validation results, affirming its applicability in the real clinical setting.

Supplementary information: The online version contains supplementary material available at 10.1007/s13534-024-00439-3.

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利用基于深度学习的负重侧足x线片分割增强平足和足弓足的诊断：一项比较观察研究。

足部负重侧位x线片（WBLR）是诊断成人获得性扁平足畸形的金标准。然而，如果不使用辅助线，则很难测量WBLR的骨长轴。在此，我们利用足部WBLR的深度学习模型（DLm）开发语义分割，以增强对平足和足弓足的诊断。我们使用了来自韩国年轻男性的300个连续wblr。基于u2net开发了语义分割模型。一位专业的整形外科医生手动标注了事实真相。我们使用200张x光片进行培训，100张用于内部验证，两个外部数据集用于外部验证。该模型使用混合损失函数进行训练，结合Dice loss和基于边界的损失，以提高整体分割精度和对足跖和足跖之间边界区域的精确描绘。对基于分割结果的最小转动惯量（MMI）和椭球体拟合（EF）测角误差进行了评价。DLm表现出比人类观察者更好的结果。内部验证，MMI和EF的绝对角度误差分别为0.92±1.32°和1.34±2.07°。在外部验证中，AMC数据集的误差分别为1.17±1.60°和1.60±2.42°，LERA数据集的误差分别为1.23±1.39°和1.68±1.98°。无论采用何种测量方法，DLm在识别平足角度方面都比人类观察者显示出更高的总体诊断准确性。开发的DLm的绝对角度误差和诊断精度优于三个人的观察者。此外，通过对DLm内角度测量方法的比较，证明了MMI方法比EF方法更精确。最后，本文提出的深度学习模型，特别是在实现了U2-Net之后，表现出了增强的边界分割，并取得了足够的外部验证结果，肯定了其在实际临床环境中的适用性。补充信息：在线版本包含补充资料，下载地址：10.1007/s13534-024-00439-3。

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来源期刊

Biomedical Engineering Letters ENGINEERING, BIOMEDICAL-

CiteScore

6.80

自引率

0.00%

发文量

期刊介绍： Biomedical Engineering Letters (BMEL) aims to present the innovative experimental science and technological development in the biomedical field as well as clinical application of new development. The article must contain original biomedical engineering content, defined as development, theoretical analysis, and evaluation/validation of a new technique. BMEL publishes the following types of papers: original articles, review articles, editorials, and letters to the editor. All the papers are reviewed in single-blind fashion.