![]() The goal is to create a novel method for monitoring twin pregnancies, based on electrophysiology, validated against a large dataset of simulated data and a small set of real-life twin measurements. Depending on the chosen approach a combination of convolutional neural networks (CNNs) and/or feed-forward neural networks can be used with or without a combination with more conventional signal processing algorithms. ![]() The student will get familiarized with the electrophysiological data and an approach for the separation of twin signals will be chosen together with the supervision team. We furthermore have a group of experts on machine learning and pregnancy for additional supervision. Students will be supervised by a research member whose research is dedicated to biomedical signal processing and machine learning, with specialization in pregnancy as application domain. In addition, 11 real twin pregnancy recordings exist (without ground truth data) and during the project we expect to collect another 10-20 recordings from twin pregnancies with Doppler ultrasound as ground truth reference. These recordings have ground truth data obtained from the existing method for processing singleton pregnancy data. We have access to >1200 cases of simulated twin pregnancy recordings, by combining two recordings from singleton pregnancies. These methods will exploit differences in the morphology of the fetal ECG signals for both fetuses across the electrodes. Instead, we will develop advanced source separation methods such as combinations of model-driven and data-driven machine learning to separate the signals. ![]() Standard source separation methods like principal or independent component analysis are insufficient to separate the signals due the dimensionality of the recorded data, with only 4-6 channels of data. The aim is to develop machine learning methods that exploit the multi-channel aspect of the electrophysiological recordings to separate the signals from both fetal hearts in twin pregnancies and determine the individual FHR of both fetuses. For twin pregnancies, further signal processing and/or machine learning needs to be developed to separate the data from both twins and determine their individual FHRs. In this project, we build on existing technology for non-invasive, multi-channel, electrophysiological monitoring of the FHR in singleton pregnancies. In the latter case, the two FHR patterns get confused leading to complicated, if not impossible, assessment of the fetal condition and consequently potentially dangerous situations. When the mother moves, or when the fetuses move, the ultrasound beams of these transducers might no longer be directed towards the fetal hearts, leading to loss of signal or worse, mix-up of the two fetal hearts. For twin pregnancies, this means that two ultrasound transducers are required. The Doppler shift in the ultrasound that is reflected from the heart rate is subsequently used to calculate the FHR. Here, a beam of ultrasound is transmitted into the body from the maternal abdominal surface. Before and during labor, the FHR is obtained by means of Doppler ultrasound technology. Such pregnancy monitoring is typically done through the cardiotocogram (CTG), the simultaneous registration of fetal heart rate (FHR) and uterine activity. Twin pregnancies have an elevated risk of complications that require monitoring of the fetal health during pregnancy and labor. IVF) and resulting increased incidence rate of twin pregnancies. The tendency of parents in Western countries to postpone parenthood is associated with increased needs of assisted reproductive technology (e.g.
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