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多普勒超声胎儿心率变异性测量的估计与可辨别性

Estimation and Discriminability of Doppler Ultrasound Fetal Heart Rate Variability Measures.

作者信息

Vargas-Calixto Johann, Warrick Philip, Kearney Robert

机构信息

Department of Biomedical Engineering, McGill University, Montreal, QC, Canada.

PeriGen Inc., Montreal, QC, Canada.

出版信息

Front Artif Intell. 2021 Aug 20;4:674238. doi: 10.3389/frai.2021.674238. eCollection 2021.

DOI:10.3389/frai.2021.674238
PMID:34490419
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8417534/
Abstract

Continuous electronic fetal monitoring and the access to databases of fetal heart rate (FHR) data have sparked the application of machine learning classifiers to identify fetal pathologies. However, most fetal heart rate data are acquired using Doppler ultrasound (DUS). DUS signals use autocorrelation (AC) to estimate the average heartbeat period within a window. In consequence, DUS FHR signals loses high frequency information to an extent that depends on the length of the AC window. We examined the effect of this on the estimation bias and discriminability of frequency domain features: low frequency power (LF: 0.03-0.15 Hz), movement frequency power (MF: 0.15-0.5 Hz), high frequency power (HF: 0.5-1 Hz), the LF/(MF + HF) ratio, and the nonlinear approximate entropy (ApEn) as a function of AC window length and signal to noise ratio. We found that the average discriminability loss across all evaluated AC window lengths and SNRs was 10.99% for LF 14.23% for MF, 13.33% for the HF, 10.39% for the LF/(MF + HF) ratio, and 24.17% for ApEn. This indicates that the frequency domain features are more robust to the AC method and additive noise than the ApEn. This is likely because additive noise increases the irregularity of the signals, which results in an overestimation of ApEn. In conclusion, our study found that the LF features are the most robust to the effects of the AC method and noise. Future studies should investigate the effect of other variables such as signal drop, gestational age, and the length of the analysis window on the estimation of fHRV features and their discriminability.

摘要

连续电子胎儿监护以及胎儿心率(FHR)数据库的获取,引发了机器学习分类器在识别胎儿病变方面的应用。然而,大多数胎儿心率数据是通过多普勒超声(DUS)获取的。DUS信号使用自相关(AC)来估计窗口内的平均心跳周期。因此,DUS FHR信号会在一定程度上丢失高频信息,该程度取决于AC窗口的长度。我们研究了这对频域特征估计偏差和可辨别性的影响:低频功率(LF:0.03 - 0.15赫兹)、运动频率功率(MF:0.15 - 0.5赫兹)、高频功率(HF:0.5 - 1赫兹)、LF/(MF + HF)比值以及非线性近似熵(ApEn),它们是AC窗口长度和信噪比的函数。我们发现,在所有评估的AC窗口长度和信噪比下,LF的平均可辨别性损失为10.99%,MF为14.23%,HF为13.33%,LF/(MF + HF)比值为10.39%,ApEn为24.17%。这表明频域特征比ApEn对AC方法和加性噪声更具鲁棒性。这可能是因为加性噪声增加了信号的不规则性,导致ApEn被高估。总之,我们的研究发现LF特征对AC方法和噪声的影响最具鲁棒性。未来的研究应调查其他变量,如信号丢失、孕周和分析窗口长度对fHRV特征估计及其可辨别性的影响。

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