E. Fotiadou scite author profile

Extraction of a clean fetal electrocardiogram (ECG) from non-invasive abdominal recordings is one of the biggest challenges in fetal monitoring. An ECG allows for the interpretation of the electrical heart activity beyond the heart rate and heart rate variability. However, the low signal quality of the fetal ECG hinders the morphological analysis of its waveform in clinical practice. The time-sequenced adaptive filter has been proposed for performing optimal time-varying filtering of non-stationary signals having a recurring statistical character. In our study, the time-sequenced adaptive filter is applied to enhance the quality of multichannel fetal ECG after the maternal ECG is removed. To improve the performance of the filter in cases of low signal-to-noise ratio (SNR), we enhance the ECG reference signals by averaging consecutive ECG complexes. The performance of the proposed augmented time-sequenced adaptive filter is evaluated in both synthetic and real data from PhysioNet. This evaluation shows that the suggested algorithm clearly outperforms other ECG enhancement methods, in terms of uncovering the ECG waveform, even in cases with very low SNR. With the presented method, quality of the fetal ECG morphology can be enhanced to the extent that the ECG might be fit for use in clinical diagnostics. Graphical abstractThe extracted fetal ECG signals from non-invasive abdominal recordings still contain a substantial amount of noise. The time-sequenced adaptive filter provides a relatively accurate estimate of the underlying fetal ECG signal when the quality of the reference channels is enhanced prior to filtering.

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End-to-end trained encoder–decoder convolutional neural network for fetal electrocardiogram signal denoising

Fotiadou

Konopczyński

Hesser

et al. 2020

Physiol. Meas.

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Multi-Channel Fetal ECG Denoising With Deep Convolutional Neural Networks

Fotiadou

Vullings

2020

Front. Pediatr.

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Non-invasive fetal electrocardiography represents a valuable alternative continuous fetal monitoring method that has recently received considerable attention in assessing fetal health. However, the non-invasive fetal electrocardiogram (ECG) is typically severely contaminated by a considerable amount of various noise sources, rendering fetal ECG denoising a very challenging task. This work employs a deep learning approach for removing the residual noise from multi-channel fetal ECG after the maternal ECG has been suppressed. We propose a deep convolutional encoder-decoder network with symmetric skip-layer connections, learning end-to-end mappings from noise-corrupted fetal ECG signals to clean ones. Experiments on simulated data show an average signal-to-noise ratio (SNR) improvement of 9.5 dB for fetal ECG signals with input SNR ranging between −20 and 20 dB. The method is additionally evaluated on a large set of real signals, demonstrating that it can provide significant quality improvement of the noisy fetal ECG signals. We further show that employment of multi-channel signal information by the network provides superior and more reliable performance as opposed to its single-channel network counterpart. The presented method is able to preserve beat-to-beat morphological variations and does not require any prior information on the power spectra of the noise or the pulse location.

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Anchoring Graph Cuts Towards Accurate Depth Estimation in Integral Images

Zarpalas

Fotiadou

Biperis

et al. 2012

J. Display Technol.

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Video-based facial discomfort analysis for infants

Fotiadou

Zinger

Ten

et al. 2014

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E. Fotiadou

Enhancement of low-quality fetal electrocardiogram based on time-sequenced adaptive filtering

End-to-end trained encoder–decoder convolutional neural network for fetal electrocardiogram signal denoising

Multi-Channel Fetal ECG Denoising With Deep Convolutional Neural Networks

Anchoring Graph Cuts Towards Accurate Depth Estimation in Integral Images

Video-based facial discomfort analysis for infants

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