Automatic standard plane and diagnostic usability classification in obstetric ultrasounds

WFUMB Ultrasound Open Pub Date : 2024-06-17 DOI:10.1016/j.wfumbo.2024.100050

Adam Lim , Mohamed Abdalla , Farbod Abolhassani , Wyanne Law , Benjamin Fine , Dafna Sussman

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Abstract

Objective

This study introduces an innovative end-to-end deep learning pipeline designed to automatically classify and order fetal ultrasound standard planes in alignment with the guidelines of the Canadian Association of Radiologists, while also assessing the diagnostic usability of each view. The primary objective is to address the manual and cumbersome challenges that interpreting radiologists encounter in the existing obstetric ultrasound workflow.

Methods

We compiled a diverse dataset, comprising 33,561 de-identified two-dimensional obstetrical ultrasound images acquired from January 1, 2010, to June 1, 2020. This dataset was categorized into 19 distinct classes associated with standard planes and further partitioned into training, validation, and testing subsets via a 60:20:20 stratified split. The standard plane and diagnostic usability networks are founded on a convolutional neural network framework and employ the benefits of transfer learning.

Results

The standard plane classification network demonstrated promising results by achieving 99.4 % and 98.7 % for accuracy and F1 score, respectively. Subsequently, the diagnostic usability network demonstrated strong performance, registering 80 % accuracy and an 82 % F1 score. Notably, this study is the first to investigate whether deep learning methods can surpass sonographers in the standard plane labeling task, with some instances revealing the algorithm's capacity to rectify sonographer mislabeled planes.

Conclusion

The results highlight the algorithm's potential to be integrated into a clinical setting by serving as a reliable assistive tool, alleviating the cognitive workload faced by radiologists and enhancing efficiency and diagnostic outcomes in the current obstetric ultrasound process.

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产科超声波的自动标准平面和诊断可用性分类

本研究引入了一种创新的端到端深度学习管道，旨在根据加拿大放射医师协会的指南对胎儿超声标准平面进行自动分类和排序，同时评估每个视图的诊断可用性。主要目的是解决放射科医生在现有产科超声波工作流程中遇到的手工操作和繁琐的难题。方法我们编制了一个多样化的数据集，其中包括从 2010 年 1 月 1 日至 2020 年 6 月 1 日期间获取的 33,561 张去标识化二维产科超声波图像。该数据集被分为与标准平面相关的 19 个不同类别，并通过 60:20:20 的分层方法进一步划分为训练子集、验证子集和测试子集。标准平面和诊断可用性网络建立在卷积神经网络框架上，并利用了迁移学习的优势。结果标准平面分类网络的准确率和 F1 分数分别达到 99.4% 和 98.7%，显示出良好的效果。随后，可用性诊断网络表现出强劲的性能，准确率达到 80%，F1 分数达到 82%。值得注意的是，这项研究首次探讨了深度学习方法是否能在标准平面标注任务中超越超声技师，其中一些实例揭示了该算法纠正超声技师错误标注平面的能力。结论：研究结果凸显了该算法作为一种可靠的辅助工具融入临床环境的潜力，可减轻放射医师面临的认知工作量，提高当前产科超声流程的效率和诊断结果。

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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WFUMB Ultrasound Open

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