Using 2D U-Net convolutional neural networks for automatic acetabular and proximal femur segmentation of hip MRI images and morphological quantification: a preliminary study in DDH.

IF 2.9 4区医学 Q3 ENGINEERING, BIOMEDICAL

BioMedical Engineering OnLine Pub Date : 2024-10-05 DOI:10.1186/s12938-024-01291-3

Dian Zhang, Hongyan Zhou, Tianli Zhou, Yan Chang, Lei Wang, Mao Sheng, Huihui Jia, Xiaodong Yang

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引用次数: 0

Abstract

Background: Developmental dysplasia of the hip (DDH) is a common pediatric orthopedic condition characterized by varying degrees of acetabular dysplasia and hip dislocation. Current 2D imaging methods often fail to provide sufficient anatomical detail for effective treatment planning, leading to higher rates of misdiagnosis and missed diagnoses. MRI, with its advantages of being radiation-free, multi-planar, and containing more anatomical information, can provide the crucial morphological and volumetric data needed to evaluate DDH. However, manual techniques for measuring parameters like the center-edge angle (CEA) and acetabular index (AI) are time-consuming. Automating these processes is essential for accurate clinical assessments and personalized treatment strategies.

Methods: This study employed a U-Net-based CNN model to automate the segmentation of hip MRI images in children. The segmentation process was validated using a leave-one-out method during training. Subsequently, the segmented hip joint images were utilized in clinical settings to perform automated measurements of key angles: AI, femoral neck angle (FNA), and CEA. This automated approach aimed to replace manual measurements and provide an objective reference for clinical assessments.

Results: The U-Net-based network demonstrates high effectiveness in hip segmentation compared to manual radiologist segmentations. In test data, it achieves average DSC values of 0.9109 (acetabulum) and 0.9244 (proximal femur), with a 91.76% segmentation success rate. The average ASD values are 0.3160 mm (acetabulum) and 0.6395 mm (proximal femur) in test data, with Ground Truth (GT) edge points and predicted segmentation maps having a mean distance of less than 1 mm. Using automated segmentation models for clinical hip angle measurements (CEA, AI, FNA) shows no statistical difference compared to manual measurements (p > 0.05).

Conclusion: Utilizing U-Net-based image segmentation and automated measurement of morphological parameters significantly enhances the accuracy and efficiency of DDH assessment. These methods improve precision in automatic measurements and provide an objective basis for clinical diagnosis and treatment of DDH.

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使用二维 U-Net 卷积神经网络自动分割髋关节 MRI 图像的髋臼和股骨近端并进行形态学量化：对 DDH 的初步研究。

背景：髋关节发育不良（DDH）是一种常见的小儿骨科疾病，其特点是不同程度的髋臼发育不良和髋关节脱位。目前的二维成像方法往往无法提供足够的解剖细节以进行有效的治疗规划，导致误诊和漏诊率较高。核磁共振成像具有无辐射、多平面、包含更多解剖信息等优点，可提供评估 DDH 所需的重要形态学和容积数据。然而，手动测量中心边缘角（CEA）和髋臼指数（AI）等参数的技术非常耗时。这些过程的自动化对于准确的临床评估和个性化治疗策略至关重要：本研究采用基于 U-Net 的 CNN 模型自动分割儿童髋关节 MRI 图像。在训练过程中，采用 "leave-one-out "方法对分割过程进行了验证。随后，将分割后的髋关节图像用于临床，对关键角度进行自动测量：AI、股骨颈角 (FNA) 和 CEA。这种自动化方法旨在取代人工测量，为临床评估提供客观参考：结果：与放射科医生的人工分割相比，基于 U-Net 的网络在髋关节分割方面表现出很高的效率。在测试数据中，它的平均 DSC 值为 0.9109（髋臼）和 0.9244（股骨近端），分割成功率为 91.76%。测试数据的平均 ASD 值为 0.3160 毫米（髋臼）和 0.6395 毫米（股骨近端），地面实况（GT）边缘点和预测分割图的平均距离小于 1 毫米。使用自动分割模型进行临床髋关节角度测量（CEA、AI、FNA）与人工测量相比没有统计学差异（P > 0.05）：结论：利用基于 U-Net 的图像分割和形态学参数的自动测量可显著提高 DDH 评估的准确性和效率。这些方法提高了自动测量的精确度，为 DDH 的临床诊断和治疗提供了客观依据。

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

BioMedical Engineering OnLine 工程技术-工程：生物医学

CiteScore

6.70

自引率

2.60%

发文量

审稿时长

1 months

期刊介绍： BioMedical Engineering OnLine is an open access, peer-reviewed journal that is dedicated to publishing research in all areas of biomedical engineering. BioMedical Engineering OnLine is aimed at readers and authors throughout the world, with an interest in using tools of the physical and data sciences and techniques in engineering to understand and solve problems in the biological and medical sciences. Topical areas include, but are not limited to: Bioinformatics- Bioinstrumentation- Biomechanics- Biomedical Devices & Instrumentation- Biomedical Signal Processing- Healthcare Information Systems- Human Dynamics- Neural Engineering- Rehabilitation Engineering- Biomaterials- Biomedical Imaging & Image Processing- BioMEMS and On-Chip Devices- Bio-Micro/Nano Technologies- Biomolecular Engineering- Biosensors- Cardiovascular Systems Engineering- Cellular Engineering- Clinical Engineering- Computational Biology- Drug Delivery Technologies- Modeling Methodologies- Nanomaterials and Nanotechnology in Biomedicine- Respiratory Systems Engineering- Robotics in Medicine- Systems and Synthetic Biology- Systems Biology- Telemedicine/Smartphone Applications in Medicine- Therapeutic Systems, Devices and Technologies- Tissue Engineering