在 CT 图像中检测脊柱骨折的创新深度学习方法。

IF 0.9 4区 医学 Q3 SURGERY
Haiting Wu, Qingsong Fu
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引用次数: 0

摘要

目的:脊柱骨折,尤其是椎体压缩性骨折,由于其尺度小,在计算机断层扫描(CT)中边界模糊,给医学成像带来了巨大挑战。然而,先进的深度学习模型,如 "你只看一次(YOLO)"V7 模型与高效层聚合网络(ELAN)和最大池化卷积(MPConv)架构的集成,可以大大减少计算处理过程中的小尺度信息损失,从而提高检测精度。本研究旨在开发一种创新的深度学习方法,用于检测CT图像中的脊柱骨折,尤其是椎体压缩性骨折:我们提出了一种使用 YOLO V7 模型作为分类器精确识别脊柱损伤的新方法。该模型通过整合 ELAN 和 MPConv 架构得到了增强,而 ELAN 和 MPConv 架构受到了感知场学习和聚合(RFLA)小对象识别框架的影响。标准归一化技术用于预处理 CT 图像。YOLO V7 模型与 ELAN 和 MPConv 架构集成,使用包含脊柱骨折注释的数据集进行训练。此外,为了减轻压缩性骨折的边界模糊性,还使用了基于高斯分布的理论感受野(TRF)和有效感受野(ERF),以更好地捕捉多尺度特征。此外,还采用了 Wasserstein 距离来优化模型的学习过程。本研究共纳入了240张来自宁波市第二医院的脊柱骨折患者的CT图像,确保为训练深度学习模型提供一个强大的数据集:与YOLO V7和YOLO V3等传统物体检测网络相比,我们的方法表现出更优越的性能。具体来说,在包含 200 张病理图像和 40 张正常脊柱图像的数据集上,我们的方法比 YOLO V7 的准确率提高了 3%:结论:所提出的方法为识别 CT 扫描中的椎体压缩性骨折提供了一种创新且更有效的方法。这些充满希望的研究结果表明,该方法具有实际临床应用的潜力,凸显了深度学习在医学影像领域加强患者护理和治疗的重要意义。未来的研究应结合交叉验证、独立验证和测试集,以评估模型的稳健性和普适性。此外,探索其他深度学习模型和方法可以进一步提高检测的准确性和可靠性,从而促进医学影像领域更有效诊断工具的开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An Innovative Deep Learning Approach to Spinal Fracture Detection in CT Images.

Aim: Spinal fractures, particularly vertebral compression fractures, pose a significant challenge in medical imaging due to their small-scale nature and blurred boundaries in Computed Tomography (CT) scans. However, advanced deep learning models, such as the integration of the You Only Look Once (YOLO) V7 model with Efficient Layer Aggregation Networks (ELAN) and Max-Pooling Convolution (MPConv) architectures, can substantially reduce the loss of small-scale information during computational processing, thus improving detection accuracy. The purpose of this study is to develop an innovative deep learning approach for detecting spinal fractures, particularly vertebral compression fractures, in CT images.

Methods: We proposed a novel method to precisely identify spinal injury using the YOLO V7 model as a classifier. This model was enhanced by integrating ELAN and MPConv architectures, which were influenced by the Receptive Field Learning and Aggregation (RFLA) small object recognition framework. Standard normalization techniques were utilized to preprocess the CT images. The YOLO V7 model, integrated with ELAN and MPConv architectures, was trained using a dataset containing annotated spinal fractures. Additionally, to mitigate boundary ambiguities in compressive fractures, a Theoretical Receptive Field (TRF) based on Gaussian distribution and an Effective Receptive Field (ERF) were used to capture multi-scale features better. Furthermore, the Wasserstein distance was employed to optimize the model's learning process. A total of 240 CT images from patients diagnosed with spinal fractures were included in this study, sourced from Ningbo No.2 Hospital, ensuring a robust dataset for training the deep learning model.

Results: Our method demonstrated superior performance over conventional object detection networks like YOLO V7 and YOLO V3. Specifically, with a dataset of 200 pathological images and 40 normal spinal images, our method achieved a 3% increase in accuracy compared to YOLO V7.

Conclusions: The proposed method offers an innovative and more effective approach for identifying vertebral compression fractures in CT scans. These promising findings suggest the method's potential for practical clinical applications, highlighting the significance of deep learning in enhancing patient care and treatment in medical imaging. Future research should incorporate cross-validation and independent validation and test sets to assess the model's robustness and generalizability. Additionally, exploring other deep learning models and methods could further enhance detection accuracy and reliability, contributing to the development of more effective diagnostic tools in medical imaging.

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来源期刊
CiteScore
0.90
自引率
12.50%
发文量
116
审稿时长
>12 weeks
期刊介绍: Annali Italiani di Chirurgia is a bimonthly journal and covers all aspects of surgery:elective, emergency and experimental surgery, as well as problems involving technology, teaching, organization and forensic medicine. The articles are published in Italian or English, though English is preferred because it facilitates the international diffusion of the journal (v.Guidelines for Authors and Norme per gli Autori). The articles published are divided into three main sections:editorials, original articles, and case reports and innovations.
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