Annisa Darmawahyuni, Bambang Tutuko, Siti Nurmaini, Muhammad Naufal Rachmatullah, Muhammad Ardiansyah, Firdaus Firdaus, Ade Iriani Sapitri, Anggun Islami
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引用次数: 0
摘要
妊娠期胎儿心脏监测对先天性心脏病(CHD)的诊断具有重要意义。无创胎儿心电图(fECG)为胎儿心脏监测提供了额外的临床信息。迄今为止,尽管心电图技术取得了重大进展,但由于母体qrs复合物的取消,无创性fECG分析仍具有挑战性。胎儿qrs复合体在检测胎儿心律失常等胎儿异常时被高度重视。在这项研究中,我们提出了一个深度学习(DL)框架,该框架堆叠了卷积层和双向长短期记忆,用于胎儿qrs复合物的分类。首先使用离散小波变换(DWT)对fECG信号进行预处理以去除噪声或推断。接下来的步骤是节拍和qrs复合分割。最后一步是基于DL的胎儿qrs复合体分类。在Physionet/Computing In Cardiology Challenge 2013的实验中,本研究达到100%的准确度、灵敏度、特异性、精密度和f1评分。堆叠DL模型是一种有效的胎儿qrs复杂分类工具,有助于临床应用于母体和胎儿的长期监测。
Accurate Fetal QRS-Complex Classification from Abdominal Electrocardiogram Using Deep Learning
Abstract Fetal heart monitoring during pregnancy plays a critical role in diagnosing congenital heart disease (CHD). A noninvasive fetal electrocardiogram (fECG) provides additional clinical information for fetal heart monitoring. To date, the analysis of noninvasive fECG is challenging due to the cancellation of maternal QRS-complexes, despite significant advances in electrocardiography. Fetal QRS-complex is highly considered to measure fetal heart rate to detect some fetal abnormalities such as arrhythmia. In this study, we proposed a deep learning (DL) framework that stacked a convolutional layer and bidirectional long short-term memory for fetal QRS-complexes classification. The fECG signals are first preprocessed using discrete wavelet transform (DWT) to remove the noise or inferences. The following step beats and QRS-complex segmentation. The last step is fetal QRS-complex classification based on DL. In the experiment of Physionet/Computing in Cardiology Challenge 2013, this study achieved 100% accuracy, sensitivity, specificity, precision, and F1-score. A stacked DL model demonstrates an effective tool for fetal QRS-complex classification and contributes to clinical applications for long-term maternal and fetal monitoring.
期刊介绍:
The International Journal of Computational Intelligence Systems publishes original research on all aspects of applied computational intelligence, especially targeting papers demonstrating the use of techniques and methods originating from computational intelligence theory. The core theories of computational intelligence are fuzzy logic, neural networks, evolutionary computation and probabilistic reasoning. The journal publishes only articles related to the use of computational intelligence and broadly covers the following topics:
-Autonomous reasoning-
Bio-informatics-
Cloud computing-
Condition monitoring-
Data science-
Data mining-
Data visualization-
Decision support systems-
Fault diagnosis-
Intelligent information retrieval-
Human-machine interaction and interfaces-
Image processing-
Internet and networks-
Noise analysis-
Pattern recognition-
Prediction systems-
Power (nuclear) safety systems-
Process and system control-
Real-time systems-
Risk analysis and safety-related issues-
Robotics-
Signal and image processing-
IoT and smart environments-
Systems integration-
System control-
System modelling and optimization-
Telecommunications-
Time series prediction-
Warning systems-
Virtual reality-
Web intelligence-
Deep learning