Abstract
We propose objective and robust measures for the purpose of classification of “vaginal vs. cesarean section” delivery by investigating temporal dynamics and complex interactions between fetal heart rate (FHR) and maternal uterine contraction (UC) recordings from cardiotocographic (CTG) traces. Multivariate extension of empirical mode decomposition (EMD) yields intrinsic scales embedded in UC-FHR recordings while also retaining inter-channel (UC-FHR) coupling at multiple scales. The mode alignment property of EMD results in the matched signal decomposition, in terms of frequency content, which paves the way for the selection of robust and objective time-frequency features for the problem at hand. Specifically, instantaneous amplitude and instantaneous frequency of multivariate intrinsic mode functions are utilized to construct a class of features which capture nonlinear and nonstationary interactions from UC-FHR recordings. The proposed features are fed to a variety of modern machine learning classifiers (decision tree, support vector machine, AdaBoost) to delineate vaginal and cesarean dynamics. We evaluate the performance of different classifiers on a real world dataset by investigating the following classifying measures: sensitivity, specificity, area under the ROC curve (AUC) and mean squared error (MSE). It is observed that under the application of all proposed 40 features AdaBoost classifier provides the best accuracy of 91.8% sensitivity, 95.5% specificity, 98% AUC, and 5% MSE. To conclude, the utilization of all proposed time-frequency features as input to machine learning classifiers can benefit clinical obstetric practitioners through a robust and automatic approach for the classification of fetus dynamics.
Highlights
According to the World Health Organization (WHO) (World Health Organization et al, 2015), the high global pregnancyrelated mortality ratio of 216 per 100,000 live births is caused by the postpartum hemorrhage, infections and pre-eclampsia (World Health Organization, 2015; Withers et al, 2018)
An ultrasound transducer attached to the abdominal wall was used to record Fetal heart rate (FHR), while a pressure transducer connected to the maternal abdomen was used to record uterine contraction (UC); both sampled at 4 Hz
Keeping the objective of the present study, we focused on a wide range of frequency (0.004–0.5 Hz) to investigate all possible physiological mechanisms which might be of interest
Summary
According to the World Health Organization (WHO) (World Health Organization et al, 2015), the high global pregnancyrelated mortality ratio of 216 per 100,000 live births is caused by the postpartum hemorrhage, infections and pre-eclampsia (World Health Organization, 2015; Withers et al, 2018). The substandard care, in terms of imprecise blood loss estimate and delayed involvement of trained obstetricians, is key to maternal mortality and morbidity (Crowhurst and Plaat, 1999; Rizvi et al, 2004) This underpins a computerized risk score system using continuous monitoring of the fetus for early identification of associated risks during antepartum and intrapartum periods. Various techniques are in practice including fetal stethoscope, intermittent auscultation (Doppler ultrasound) and electronic fetal monitoring (EFM) (Freeman et al, 2012) These techniques have the potential to determine intrauterine hypoxia (Alfirevic et al, 2017), and make additional assessments leading to the identification of normal and abnormal births (Alfirevic et al, 2017). The EFM, named cardiotocography (CTG), provides the precise monitoring and recording of FHR and captures maternal uterine contractions (UCs), making CTG a more attractive technique in obstetrics (Warrick et al, 2009)
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