Abstract
Fetal echocardiography is an operator-dependent examination technique requiring a high level of expertise. Pulsed-wave Doppler (PWD) is often used as a reference for the mechanical activity of the heart, from which several quantitative parameters can be extracted. These aspects suggest the development of software tools that can reliably identify complete and clinically meaningful fetal cardiac cycles that can enable their automatic measurement. Several scientific works have addressed the tracing of the PWD velocity envelope. In this work, we assess the different steps involved in the signal processing chains that enable PWD envelope tracing. We apply a supervised classifier trained on envelopes traced by different signal processing chains for distinguishing complete and measurable PWD heartbeats from incomplete or malformed ones, which makes it possible to determine the impact of each of the different processing steps on the detection accuracy. In this study, we collected 43 images and labeled 174,319 PWD segments from 25 pregnant women volunteers. By considering seven envelope tracing techniques and the 23 different processing steps involved in their implementation, the results of our study reveal that, compared to the steps investigated in most other works, those that achieve binarisation and envelope extraction are significantly more important (p < 0.05). The best approaches among those studied enabled greater than 98% accuracy on our large manually annotated dataset.
Highlights
Ultrasonography is the leading technology for the diagnosis and monitoring of fetal heart pathologies [1]
To enable evaluation of the role played by the processing steps of each option described above with respect to pulsed-wave Doppler (PWD) envelope tracing, we identified a prototypical processing chain, which we labeled the main work chain (MC)
The results of the pairwise Wilcoxon tests, which was applied to each processing step on the MC and other processing chains that differed only in the use of another option in that step, reveal significant differences for all combinations in the phases mentioned above and between chains 2, 15, and 16 and the MC
Summary
Ultrasonography is the leading technology for the diagnosis and monitoring of fetal heart pathologies [1]. Fetal echocardiography typically takes advantage of pulsed-wave Doppler (PWD) for the assessment of the cardiac rhythm [2, 3], which enables objective analysis of the blood flow through the heart. In routine Doppler examinations, the apical view is considered to be the best for fetal heart inspection in cases of suspected valvular heart disease [4]. Using the apical five-chamber view, the four cardiac chambers and the first part of the aorta (assumed to be a fifth chamber) can be investigated.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
