Publication Type : Journal Article
Source : Physiological Measurement, 2022 [Q2, Impact factor - 3.068], DOI: 10.1088/1361-6579/ac4e6d
Url : https://pubmed.ncbi.nlm.nih.gov/35073532/
Keywords : arrhythmia; entropy; fetal ECG; fetal monitoring; signal quality.
Campus : Amritapuri
School : School for Sustainable Futures
Center : Amrita Center for Wireless Networks and Applications (AmritaWNA)
Year : 2022
Abstract : Objective.Fetal arrhythmias are a life-threatening disorder occurring in up to 2% of pregnancies. If identified, many fetal arrhythmias can be effectively treated using anti-arrhythmic therapies. In this paper, we present a novel method of detecting fetal arrhythmias in short length non-invasive fetal electrocardiography (NI-FECG) recordings.Approach.Our method consists of extracting a fetal heart rate time series from each NI-FECG recording and computing an entropy profile using a data-driven range of the entropy tolerance parameterr. To validate our approach, we apply our entropy profiling method to a large clinical data set of 318 NI-FECG recordings.Main Results.We demonstrate that our method (TotalSampEn) provides strong performance for classifying arrhythmic fetuses (AUC of 0.83) and outperforms entropy measures such asSampEn(AUC of 0.68) andFuzzyEn(AUC of 0.72). We also find that NI-FECG recordings incorrectly classified using the investigated entropy measures have significantly lower signal quality, and that excluding recordings of low signal quality (13.5% of recordings) increases the classification performance ofTotalSampEn(AUC of 0.90).Significance.The superior performance of our approach enables automated detection of fetal arrhythmias and warrants further investigation in a prospective clinical trial.
Cite this Research Publication : Emerson Keenan, Chandan Karmakar, Radhagayathri K Udhayakumar, Fiona C Brownfoot, Igor Lakhno, Vyacheslav Shulgin, Joachim A Behar, Marimuthu Palaniswami, Detection of fetal arrhythmias in non-invasive fetal ECG recordings using data-driven entropy profiling, Physiological Measurement, 2022 [Q2, Impact factor - 3.068], DOI: 10.1088/1361-6579/ac4e6d