基于深度学习关键点检测网络的 X 光片胫骨畸形角度自动测量方法

IF 3 4区 计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Ning Zhao, Cheng Chang, Yuanyuan Liu, Xiao Li, Zicheng Song, Yue Guo, Jianwen Chen, Hao Sun
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引用次数: 0

摘要

在平行外固定器的临床应用中,医生需要量化畸形参数以制定矫正策略。然而,人工测量畸形角度是一个复杂且耗时的过程,容易受到主观因素的影响,导致测量结果不可重复。因此,本研究提出了一种基于深度学习的自动测量方法,包括三个阶段:胫骨段定位、胫骨轮廓点检测和畸形角度计算。首先,采用以 ResNet50 和 FPN 为骨干的 Faster R-CNN 物体检测模型,实现闭塞和非闭塞条件下胫骨节段的精确定位。随后,添加了相对位置约束损失函数,并使用 ResNet101 作为骨干,形成了改进的 RTMPose 关键点检测模型,实现了对胫骨轮廓点的精确检测。最终,根据轮廓点坐标确定了每个胫骨节段的骨轴,并计算出了畸形角。增强型关键点检测模型 Con_RTMPose 将关键点正确率 (PCK) 从初始模型的 63.94% 提高到 87.17%,显著提高了关键点定位精度。与医疗专业人员进行的人工测量相比,该方法的平均误差为 0.52°,最大误差为 1.15°,标准偏差为 0.07,从而满足了骨科评估所需的精确度标准。测量时间约为 12 秒,而人工测量约需 15 分钟,大大缩短了所需时间。此外,模型的稳定性也通过 K 倍交叉验证实验得到了验证。所提出的方法符合骨科应用的精度要求,能提供客观、可重复的结果,大大减轻了医务人员的工作量,并极大地提高了工作效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An Automatic Measurement Method of the Tibial Deformity Angle on X-Ray Films Based on Deep Learning Keypoint Detection Network

In the clinical application of the parallel external fixator, medical practitioners are required to quantify deformity parameters to develop corrective strategies. However, manual measurement of deformity angles is a complex and time-consuming process that is susceptible to subjective factors, resulting in nonreproducible results. Accordingly, this study proposes an automatic measurement method based on deep learning, comprising three stages: tibial segment localization, tibial contour point detection, and deformity angle calculation. First, the Faster R-CNN object detection model, combined with ResNet50 and FPN as the backbone, was employed to achieve accurate localization of tibial segments under both occluded and nonoccluded conditions. Subsequently, a relative position constraint loss function was added, and ResNet101 was used as the backbone, resulting in an improved RTMPose keypoint detection model that achieved precise detection of tibial contour points. Ultimately, the bone axes of each tibial segment were determined based on the coordinates of the contour points, and the deformity angles were calculated. The enhanced keypoint detection model, Con_RTMPose, elevated the Percentage of Correct Keypoints (PCK) from 63.94% of the initial model to 87.17%, markedly augmenting keypoint localization precision. Compared to manual measurements conducted by medical professionals, the proposed methodology demonstrates an average error of 0.52°, a maximum error of 1.15°, and a standard deviation of 0.07, thereby satisfying the requisite accuracy standards for orthopedic assessments. The measurement time is approximately 12 s, whereas manual measurement requires about 15 min, greatly reducing the time required. Additionally, the stability of the models was verified through K-fold cross-validation experiments. The proposed method meets the accuracy requirements for orthopedic applications, provides objective and reproducible results, significantly reduces the workload of medical professionals, and greatly improves efficiency.

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来源期刊
International Journal of Imaging Systems and Technology
International Journal of Imaging Systems and Technology 工程技术-成像科学与照相技术
CiteScore
6.90
自引率
6.10%
发文量
138
审稿时长
3 months
期刊介绍: The International Journal of Imaging Systems and Technology (IMA) is a forum for the exchange of ideas and results relevant to imaging systems, including imaging physics and informatics. The journal covers all imaging modalities in humans and animals. IMA accepts technically sound and scientifically rigorous research in the interdisciplinary field of imaging, including relevant algorithmic research and hardware and software development, and their applications relevant to medical research. The journal provides a platform to publish original research in structural and functional imaging. The journal is also open to imaging studies of the human body and on animals that describe novel diagnostic imaging and analyses methods. Technical, theoretical, and clinical research in both normal and clinical populations is encouraged. Submissions describing methods, software, databases, replication studies as well as negative results are also considered. The scope of the journal includes, but is not limited to, the following in the context of biomedical research: Imaging and neuro-imaging modalities: structural MRI, functional MRI, PET, SPECT, CT, ultrasound, EEG, MEG, NIRS etc.; Neuromodulation and brain stimulation techniques such as TMS and tDCS; Software and hardware for imaging, especially related to human and animal health; Image segmentation in normal and clinical populations; Pattern analysis and classification using machine learning techniques; Computational modeling and analysis; Brain connectivity and connectomics; Systems-level characterization of brain function; Neural networks and neurorobotics; Computer vision, based on human/animal physiology; Brain-computer interface (BCI) technology; Big data, databasing and data mining.
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