Integration of multivariate empirical mode decomposition and independent component analysis for fetal ECG separation from abdominal signals

BACKGROUND: The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate(FHR) is commonly used for diagnosing certain abnormalities in the formation of the heart. Usually, non-invasive abdominal electrocardiogram (AbECG) signals are obtained...

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Published inTechnology and health care Vol. 24; no. 6; pp. 783 - 794
Main Authors Thanaraj, Palani, Roshini, Mable, Balasubramanian, Parvathavarthini
Format Journal Article
LanguageEnglish
Published London, England SAGE Publications 14.11.2016
Subjects
Adult
Algorithms
Electrocardiography - methods
Electrocardiography - statistics & numerical data
Female
Fetal Monitoring - methods
Fetal Monitoring - statistics & numerical data
Heart Rate, Fetal - physiology
Humans
Maternal-Fetal Relations - physiology
Pregnancy
Signal Processing, Computer-Assisted
maternal ECG
independent component analysis
Multivariate empirical mode decomposition
fetal ECG
signal separation
fetal heart rate
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Abstract BACKGROUND: The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate(FHR) is commonly used for diagnosing certain abnormalities in the formation of the heart. Usually, non-invasive abdominal electrocardiogram (AbECG) signals are obtained by placing surface electrodes in the abdomen region of the pregnant woman. AbECG signals are often not suitable for the direct analysis of fetal heart activity. Moreover, the strength and magnitude of the FECG signals are low compared to the maternal electrocardiogram (MECG) signals. The MECG signals are often superimposed with the FECG signals that make the monitoring of FECG signals a difficult task. OBJECTIVE: Primary goal of the paper is to separate the fetal electrocardiogram (FECG) signals from the unwanted maternal electrocardiogram (MECG) signals. METHOD: A multivariate signal processing procedure is proposed here that combines the Multivariate Empirical Mode Decomposition (MEMD) and Independent Component Analysis (ICA). RESULTS: The proposed method is evaluated with clinical abdominal signals taken from three pregnant women (N= 3) recorded during the 38-41 weeks of the gestation period. The number of fetal R-wave detected (N EFQRS ), the number of unwanted maternal peaks (N MQRS ), the number of undetected fetal R-wave (N UFQRS ) and the FHR detection accuracy quantifies the performance of our method. Clinical investigation with three test subjects shows an overall detection accuracy of 92.8%. CONCLUSION: Comparative analysis with benchmark signal processing method such as ICA suggests the noteworthy performance of our method.
AbstractList BACKGROUND: The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate(FHR) is commonly used for diagnosing certain abnormalities in the formation of the heart. Usually, non-invasive abdominal electrocardiogram (AbECG) signals are obtained by placing surface electrodes in the abdomen region of the pregnant woman. AbECG signals are often not suitable for the direct analysis of fetal heart activity. Moreover, the strength and magnitude of the FECG signals are low compared to the maternal electrocardiogram (MECG) signals. The MECG signals are often superimposed with the FECG signals that make the monitoring of FECG signals a difficult task. OBJECTIVE: Primary goal of the paper is to separate the fetal electrocardiogram (FECG) signals from the unwanted maternal electrocardiogram (MECG) signals. METHOD: A multivariate signal processing procedure is proposed here that combines the Multivariate Empirical Mode Decomposition (MEMD) and Independent Component Analysis (ICA). RESULTS: The proposed method is evaluated with clinical abdominal signals taken from three pregnant women (N= 3) recorded during the 38-41 weeks of the gestation period. The number of fetal R-wave detected (N EFQRS ), the number of unwanted maternal peaks (N MQRS ), the number of undetected fetal R-wave (N UFQRS ) and the FHR detection accuracy quantifies the performance of our method. Clinical investigation with three test subjects shows an overall detection accuracy of 92.8%. CONCLUSION: Comparative analysis with benchmark signal processing method such as ICA suggests the noteworthy performance of our method.
The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate (FHR) is commonly used for diagnosing certain abnormalities in the formation of the heart. Usually, non-invasive abdominal electrocardiogram (AbECG) signals are obtained by placing surface electrodes in the abdomen region of the pregnant woman. AbECG signals are often not suitable for the direct analysis of fetal heart activity. Moreover, the strength and magnitude of the FECG signals are low compared to the maternal electrocardiogram (MECG) signals. The MECG signals are often superimposed with the FECG signals that make the monitoring of FECG signals a difficult task.BACKGROUNDThe fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate (FHR) is commonly used for diagnosing certain abnormalities in the formation of the heart. Usually, non-invasive abdominal electrocardiogram (AbECG) signals are obtained by placing surface electrodes in the abdomen region of the pregnant woman. AbECG signals are often not suitable for the direct analysis of fetal heart activity. Moreover, the strength and magnitude of the FECG signals are low compared to the maternal electrocardiogram (MECG) signals. The MECG signals are often superimposed with the FECG signals that make the monitoring of FECG signals a difficult task.Primary goal of the paper is to separate the fetal electrocardiogram (FECG) signals from the unwanted maternal electrocardiogram (MECG) signals.OBJECTIVEPrimary goal of the paper is to separate the fetal electrocardiogram (FECG) signals from the unwanted maternal electrocardiogram (MECG) signals.A multivariate signal processing procedure is proposed here that combines the Multivariate Empirical Mode Decomposition (MEMD) and Independent Component Analysis (ICA).METHODA multivariate signal processing procedure is proposed here that combines the Multivariate Empirical Mode Decomposition (MEMD) and Independent Component Analysis (ICA).The proposed method is evaluated with clinical abdominal signals taken from three pregnant women (N= 3) recorded during the 38-41 weeks of the gestation period. The number of fetal R-wave detected (NEFQRS), the number of unwanted maternal peaks (NMQRS), the number of undetected fetal R-wave (NUFQRS) and the FHR detection accuracy quantifies the performance of our method. Clinical investigation with three test subjects shows an overall detection accuracy of 92.8%.RESULTSThe proposed method is evaluated with clinical abdominal signals taken from three pregnant women (N= 3) recorded during the 38-41 weeks of the gestation period. The number of fetal R-wave detected (NEFQRS), the number of unwanted maternal peaks (NMQRS), the number of undetected fetal R-wave (NUFQRS) and the FHR detection accuracy quantifies the performance of our method. Clinical investigation with three test subjects shows an overall detection accuracy of 92.8%.Comparative analysis with benchmark signal processing method such as ICA suggests the noteworthy performance of our method.CONCLUSIONComparative analysis with benchmark signal processing method such as ICA suggests the noteworthy performance of our method.
The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate (FHR) is commonly used for diagnosing certain abnormalities in the formation of the heart. Usually, non-invasive abdominal electrocardiogram (AbECG) signals are obtained by placing surface electrodes in the abdomen region of the pregnant woman. AbECG signals are often not suitable for the direct analysis of fetal heart activity. Moreover, the strength and magnitude of the FECG signals are low compared to the maternal electrocardiogram (MECG) signals. The MECG signals are often superimposed with the FECG signals that make the monitoring of FECG signals a difficult task. Primary goal of the paper is to separate the fetal electrocardiogram (FECG) signals from the unwanted maternal electrocardiogram (MECG) signals. A multivariate signal processing procedure is proposed here that combines the Multivariate Empirical Mode Decomposition (MEMD) and Independent Component Analysis (ICA). The proposed method is evaluated with clinical abdominal signals taken from three pregnant women (N= 3) recorded during the 38-41 weeks of the gestation period. The number of fetal R-wave detected (NEFQRS), the number of unwanted maternal peaks (NMQRS), the number of undetected fetal R-wave (NUFQRS) and the FHR detection accuracy quantifies the performance of our method. Clinical investigation with three test subjects shows an overall detection accuracy of 92.8%. Comparative analysis with benchmark signal processing method such as ICA suggests the noteworthy performance of our method.
Author Balasubramanian, Parvathavarthini
Roshini, Mable
Thanaraj, Palani
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Keywords maternal ECG
independent component analysis
Multivariate empirical mode decomposition
fetal ECG
signal separation
fetal heart rate
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Snippet BACKGROUND: The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate(FHR) is commonly used for...
The fetal electrocardiogram (FECG) signals are essential to monitor the health condition of the baby. Fetal heart rate (FHR) is commonly used for diagnosing...
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SubjectTerms Adult
Algorithms
Electrocardiography - methods
Electrocardiography - statistics & numerical data
Female
Fetal Monitoring - methods
Fetal Monitoring - statistics & numerical data
Heart Rate, Fetal - physiology
Humans
Maternal-Fetal Relations - physiology
Pregnancy
Signal Processing, Computer-Assisted
Title Integration of multivariate empirical mode decomposition and independent component analysis for fetal ECG separation from abdominal signals
URI https://journals.sagepub.com/doi/full/10.3233/THC-161224
https://www.ncbi.nlm.nih.gov/pubmed/27315149
https://www.proquest.com/docview/1826697846
Volume 24
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