Huang Zhuya, Yu Junsheng, Shan Ying
School of Electronic Engineering, Beijing University of Posts and Telecommunications, Beijing, China.
Beijing Health State Monitoring & Consulting Co. Limited, Beijing, China.
Biomed Tech (Berl). 2024 Nov 4;70(2):183-194. doi: 10.1515/bmt-2024-0334. Print 2025 Apr 28.
This study aims to develop a multimodal deep learning-based algorithm for detecting specific fetal heart rate (FHR) events, to enhance automatic monitoring and intelligent assessment of fetal well-being.
We analyzed FHR and uterine contraction signals by combining various feature extraction techniques, including morphological features, heart rate variability features, and nonlinear domain features, with deep learning algorithms. This approach enabled us to classify four specific FHR events (bradycardia, tachycardia, acceleration, and deceleration) as well as four distinct deceleration patterns (early, late, variable, and prolonged deceleration). We proposed a multi-model deep neural network and a pre-fusion deep learning model to accurately classify the multimodal parameters derived from Cardiotocography signals.
These accuracy metrics were calculated based on expert-labeled data. The algorithm achieved a classification accuracy of 96.2 % for acceleration, 94.4 % for deceleration, 90.9 % for tachycardia, and 85.8 % for bradycardia. Additionally, it achieved 67.0 % accuracy in classifying the four distinct deceleration patterns, with 80.9 % accuracy for late deceleration and 98.9 % for prolonged deceleration.
The proposed multimodal deep learning algorithm serves as a reliable decision support tool for clinicians, significantly improving the detection and assessment of specific FHR events, which are crucial for fetal health monitoring.
本研究旨在开发一种基于多模态深度学习的算法,用于检测特定的胎儿心率(FHR)事件,以加强对胎儿健康的自动监测和智能评估。
我们通过将包括形态学特征、心率变异性特征和非线性域特征在内的各种特征提取技术与深度学习算法相结合,分析FHR和子宫收缩信号。这种方法使我们能够对四种特定的FHR事件(心动过缓、心动过速、加速和减速)以及四种不同的减速模式(早期、晚期、变异和延长减速)进行分类。我们提出了一种多模型深度神经网络和一种预融合深度学习模型,以准确分类从胎心监护信号中导出的多模态参数。
这些准确率指标是基于专家标注的数据计算得出的。该算法对加速的分类准确率为96.2%,对减速的分类准确率为94.4%,对心动过速的分类准确率为90.9%,对心动过缓的分类准确率为85.8%。此外,它对四种不同减速模式的分类准确率为67.0%,对晚期减速的分类准确率为80.9%,对延长减速的分类准确率为98.9%。
所提出的多模态深度学习算法为临床医生提供了一个可靠的决策支持工具,显著提高了对特定FHR事件的检测和评估,这对胎儿健康监测至关重要。
