S.G. Oei scite author profile

Abstract-Electrophysiological monitoring of the fetal-heart and the uterine-muscle activity, referred to as an electrohysterogram, is essential to permit timely treatment during pregnancy. While remarkable progress is reported for fetal-cardiac-activity monitoring, the electrohysterographic (EHG) measurement and interpretation remain challenging. In particular, little attention has been paid to the analysis of the EHG propagation, whose characteristics might be predictive of the preterm delivery. Therefore, this paper focuses, for the first time, on the noninvasive estimation of the conduction velocity of the EHG-action potentials. To this end, multichannel EHG recording and surface high-density electrodes are used. A maximum-likelihood method is employed for analyzing the EHG-action-potential propagation in two dimensions. The use of different weighting strategies of the derived cost function is introduced to deal with the poor signal similarity between different channels. The presented methods were evaluated by specific simulations proving the best weighting strategy to lead to an accuracy improvement of 56.7%. EHG measurements on ten women with uterine contractions confirmed the feasibility of the method by leading to conduction velocity values within the expected physiological range.

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Estimation of internal uterine pressure by joint amplitude and frequency analysis of electrohysterographic signals

Rabotti

Mischi

Laar

et al. 2008

Physiol. Meas.

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Monitoring the uterine contraction provides important prognostic information during pregnancy and parturition. The existing methods employed in clinical practice impose a compromise between reliability and invasiveness. A promising technique for uterine contraction monitoring is electrohysterography (EHG). The EHG signal measures the electrical activity which triggers the contraction of the uterine muscle. In this paper, a non-invasive method for intrauterine pressure (IUP) estimation by EHG signal analysis is proposed. The EHG signal is regarded as a non-stationary signal whose frequency and amplitude characteristics are related to the IUP. After acquisition in a multi-channel configuration, the EHG signal is therefore analyzed in the time-frequency domain. A first estimation of the IUP is then derived by calculation of the unnormalized first statistical moment of the frequency spectrum. The estimation accuracy is finally increased by identification of a second-order polynomial model. The proposed method is compared to root mean squared analysis and optimal linear filtering and validated by simultaneous measurement of the IUP on nine women during labor. The results suggest that the proposed EHG signal analysis provides an accurate estimate of the IUP.

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Simulation‐based team training for multi‐professional obstetric care teams to improve patient outcome: a multicentre, cluster randomised controlled trial

Fransen

Ven

Schuit

et al. 2016

BJOG

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Multidisciplinary Team Training in a Simulation Setting for Acute Obstetric Emergencies

Merién

Ven

Mol

et al. 2011

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Dynamic segmentation and linear prediction for maternal ECG removal in antenatal abdominal recordings

et al. 2009

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Monitoring the fetal heart rate (fHR) and fetal electrocardiogram (fECG) during pregnancy is important to support medical decision making. Before labor, the fHR is usually monitored using Doppler ultrasound. This method is inaccurate and therefore of limited clinical value. During labor, the fHR can be monitored more accurately using an invasive electrode; this method also enables monitoring of the fECG. Antenatally, the fECG and fHR can also be monitored using electrodes on the maternal abdomen. The signal-to-noise ratio of these recordings is, however, low, the maternal electrocardiogram (mECG) being the main interference. Existing techniques to remove the mECG from these non-invasive recordings are insufficiently accurate or do not provide all spatial information of the fECG. In this paper a new technique for mECG removal in antenatal abdominal recordings is presented. This technique operates by the linear prediction of each separate wave in the mECG. Its performance in mECG removal and fHR detection is evaluated by comparison with spatial filtering, adaptive filtering, template subtraction and independent component analysis techniques. The new technique outperforms the other techniques in both mECG removal and fHR detection (by more than 3%).

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Spectral analysis of fetal heart rate variability for fetal surveillance: review of the literature

Laar

Porath

Peters

et al. 2008

Acta Obstet Gynecol Scand

103

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An Improved Adaptive Power Line Interference Canceller for Electrocardiography

Martens

Mischi

Oei

et al. 2006

IEEE Trans. Biomed. Eng.

123

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Power line interference may severely corrupt a biomedical recording. Notch filters and adaptive cancellers have been suggested to suppress this interference. We propose an improved adaptive canceller for the reduction of the fundamental power line interference component and harmonics in electrocardiogram (ECG) recordings. The method tracks. the amplitude, phase, and frequency of all the interference components for power line frequency deviations up to about 4 Hz. A comparison is made between the performance of our method, former adaptive cancellers, and a narrow and a wide notch filter in suppressing the fundamental power line interference component. For this purpose a real ECG signal is corrupted by an artificial power line interference signal. The cleaned signal after applying all methods is compared with the original ECG signal. Our improved adaptive canceller shows a signal-to-power-line-interference ratio for the fundamental component up to 30 dB higher than that produced by the other methods. Moreover, our method is also effective for the suppression of the harmonics of the power line interference.

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S.G. Oei

Multidisciplinary Team Training in a Simulation Setting for Acute Obstetric Emergencies

Noninvasive Estimation of the Electrohysterographic Action-Potential Conduction Velocity

Estimation of internal uterine pressure by joint amplitude and frequency analysis of electrohysterographic signals

Simulation‐based team training for multi‐professional obstetric care teams to improve patient outcome: a multicentre, cluster randomised controlled trial

Multidisciplinary Team Training in a Simulation Setting for Acute Obstetric Emergencies

Dynamic segmentation and linear prediction for maternal ECG removal in antenatal abdominal recordings

Spectral analysis of fetal heart rate variability for fetal surveillance: review of the literature

An Improved Adaptive Power Line Interference Canceller for Electrocardiography

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