A systematic review of automated pre-processing, feature extraction and classification of cardiotocography

Context The interpretations of cardiotocography (CTG) tracings are indeed vital to monitor fetal well-being both during pregnancy and childbirth. Currently, many studies are focusing on feature extraction and CTG classification using computer vision approach in determining the most accurate diagnosis as well as monitoring the fetal well-being during pregnancy. Additionally, a fetal monitoring system would be able to perform detection and precise quantification of fetal heart rate patterns. Objective This study aimed to perform a systematic review to describe the achievements made by the researchers, summarizing findings that have been found by previous researchers in feature extraction and CTG classification, to determine criteria and evaluation methods to the taxonomies of the proposed literature in the CTG field and to distinguish aspects from relevant research in the field of CTG. Methods Article search was done systematically using three databases: IEEE Xplore digital library, Science Direct, and Web of Science over a period of 5 years. The literature in the medical sciences and engineering was included in the search selection to provide a broader understanding for researchers. Results After screening 372 articles, and based on our protocol of exclusion and inclusion criteria, for the final set of articles, 50 articles were obtained. The research literature taxonomy was divided into four stages. The first stage discussed the proposed method which presented steps and algorithms in the pre-processing stage, feature extraction and classification as well as their use in CTG (20/50 papers). The second stage included the development of a system specifically on automatic feature extraction and CTG classification (7/50 papers). The third stage consisted of reviews and survey articles on automatic feature extraction and CTG classification (3/50 papers). The last stage discussed evaluation and comparative studies to determine the best method for extracting and classifying features with comparisons based on a set of criteria (20/50 articles). Discussion This study focused more on literature compared to techniques or methods. Also, this study conducts research and identification of various types of datasets used in surveys from publicly available, private, and commercial datasets. To analyze the results, researchers evaluated independent datasets using different techniques. Conclusions This systematic review contributes to understand and have insight into the relevant research in the field of CTG by surveying and classifying pertinent research efforts. This review will help to address the current research opportunities, problems and challenges, motivations, recommendations related to feature extraction and CTG classification, as well as the measurement of various performance and various data sets used by other researchers.

[1]  D. Nunan,et al.  A cross‐sectional comparison of three guidelines for intrapartum cardiotocography , 2017, International journal of gynaecology and obstetrics: the official organ of the International Federation of Gynaecology and Obstetrics.

[2]  AN OUTLIER BASED BI-LEVEL NEURAL NETWORK CLASSIFICATION SYSTEM FOR IMPROVED CLASSIFICATION OF CARDIOTOCOGRAM DATA , 2014 .

[3]  Ahmad Taher Azar,et al.  Feature selection using swarm-based relative reduct technique for fetal heart rate , 2014, Neural Computing and Applications.

[4]  Hasan Ocak,et al.  A Medical Decision Support System Based on Support Vector Machines and the Genetic Algorithm for the Evaluation of Fetal Well-Being , 2013, Journal of Medical Systems.

[5]  Suzanna Long,et al.  Evaluation of support vector machines and random forest classifiers in a real-time fetal monitoring system based on cardiotocography data , 2017, 2017 IEEE Conference on Computational Intelligence in Bioinformatics and Computational Biology (CIBCB).

[7]  Yang Zhang,et al.  Fetal state assessment based on cardiotocography parameters using PCA and AdaBoost , 2017, 2017 10th International Congress on Image and Signal Processing, BioMedical Engineering and Informatics (CISP-BMEI).

[8]  J. Jezewski,et al.  Fetal state assessment using fuzzy analysis of fetal heart rate signals—Agreement with the neonatal outcome , 2013 .

[9]  Rik Vullings,et al.  Selective heart rate variability analysis to account for uterine activity during labor and improve classification of fetal distress , 2016, 2016 38th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[10]  E. Chandraharan,et al.  Continuous cardiotocography during labour: Analysis, classification and management. , 2016, Best practice & research. Clinical obstetrics & gynaecology.

[11]  Adhistya Erna Permanasari,et al.  Decision tree to analyze the cardiotocogram data for fetal distress determination , 2017, 2017 International Conference on Sustainable Information Engineering and Technology (SIET).

[12]  João Bernardes,et al.  Interobserver agreement in CTG interpretation using the 2015 FIGO guidelines for intrapartum fetal monitoring. , 2016, European journal of obstetrics, gynecology, and reproductive biology.

[13]  J. De Jonckheere,et al.  Inter-observer reliability of 4 fetal heart rate classifications. , 2017, Journal of gynecology obstetrics and human reproduction.

[14]  R. Jyothi,et al.  Classification of labour contractions using KNN classifier , 2016, 2016 International Conference on Systems in Medicine and Biology (ICSMB).

[15]  Ersen Yilmaz,et al.  Fetal State Assessment from Cardiotocogram Data Using Artificial Neural Networks , 2016 .

[16]  Lenka Lhotská,et al.  A three class treatment of the FHR classification problem using latent class analysis labeling , 2014, 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[17]  Zafer Cömert,et al.  A novel software for comprehensive analysis of cardiotocography signals “CTG-OAS” , 2017, 2017 International Artificial Intelligence and Data Processing Symposium (IDAP).

[18]  Guglielmo Frigo,et al.  Comparative evaluation of on-line missing data regression techniques in intrapartum FHR measurements , 2017, 2017 IEEE International Instrumentation and Measurement Technology Conference (I2MTC).

[19]  Chii-Wann Lin,et al.  Comparison of a Novel Computerized Analysis Program and Visual Interpretation of Cardiotocography , 2014, PloS one.

[20]  C. Sundar,et al.  Incapable of identifying suspicious records in CTG data using ANN based machine learning techniques , 2014 .

[21]  Hasan Ocak,et al.  Prediction of fetal state from the cardiotocogram recordings using adaptive neuro-fuzzy inference systems , 2012, Neural Computing and Applications.

[22]  Antoniya Georgieva,et al.  Artificial neural networks applied to fetal monitoring in labour , 2011, Neural Computing and Applications.

[23]  Joakim Andén,et al.  Scattering Transform for Intrapartum Fetal Heart Rate Variability Fractal Analysis: A Case-Control Study , 2014, IEEE Transactions on Biomedical Engineering.

[24]  F. Mecacci,et al.  Comparison of five classification systems for interpreting electronic fetal monitoring in predicting neonatal status at birth , 2013, The journal of maternal-fetal & neonatal medicine : the official journal of the European Association of Perinatal Medicine, the Federation of Asia and Oceania Perinatal Societies, the International Society of Perinatal Obstetricians.

[25]  Riccardo Bellazzi,et al.  Comparison of data mining techniques applied to fetal heart rate parameters for the early identification of IUGR fetuses , 2016, 2016 38th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[26]  P. Rucci,et al.  Cardiotocographic findings in the second stage of labor among fetuses delivered with acidemia: a comparison of two classification systems. , 2016, European journal of obstetrics, gynecology, and reproductive biology.

[27]  Maria Romano,et al.  Software for computerised analysis of cardiotocographic traces , 2016, Comput. Methods Programs Biomed..

[28]  Muhammad Arif,et al.  Decision Trees Based Classification of Cardiotocograms Using Bagging Approach , 2015, 2015 13th International Conference on Frontiers of Information Technology (FIT).

[29]  Chrysostomos D. Stylios,et al.  An ordinal classification approach for CTG categorization , 2017, 2017 39th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[30]  R. Vullings,et al.  Detection rate of fetal distress using contraction-dependent fetal heart rate variability analysis , 2018, Physiological measurement.

[31]  Patrice Abry,et al.  Sparse Support Vector Machine for Intrapartum Fetal Heart Rate Classification , 2017, IEEE Journal of Biomedical and Health Informatics.

[32]  Hyung-Jeong Yang,et al.  FitMine: automatic mining for time-evolving signals of cardiotocography monitoring , 2017, Data Mining and Knowledge Discovery.

[33]  Diogo Ayres-de-Campos,et al.  Computer analysis of foetal monitoring signals. , 2016, Best practice & research. Clinical obstetrics & gynaecology.

[34]  Zafer Cömert,et al.  Comparison of Machine Learning Techniques for Fetal Heart Rate Classification , 2017 .

[35]  Francesco Amato,et al.  Evaluation of floatingline and foetal heart rate variability , 2018, Biomed. Signal Process. Control..

[36]  Stephen J Payne,et al.  Feature selection using genetic algorithms for fetal heart rate analysis , 2014, Physiological measurement.

[37]  Abdulhamit Subasi,et al.  Classification of the cardiotocogram data for anticipation of fetal risks using machine learning techniques , 2015, Appl. Soft Comput..

[38]  T. I. Haweel,et al.  Volterra neural analysis of fetal cardiotocographic signals , 2013, 2013 1st International Conference on Communications, Signal Processing, and their Applications (ICCSPA).

[39]  Petr Gajdos,et al.  Classification of cardiotocography records by random forest , 2013, 2013 36th International Conference on Telecommunications and Signal Processing (TSP).

[40]  Cristian Rotariu,et al.  Automatic analysis of the fetal heart rate variability and uterine contractions , 2014, 2014 International Conference and Exposition on Electrical and Power Engineering (EPE).

[41]  Paul Fergus,et al.  Machine learning ensemble modelling to classify caesarean section and vaginal delivery types using Cardiotocography traces , 2018, Comput. Biol. Medicine.

[42]  Zafer Cömert,et al.  Cardiotocography signals with artificial neural network and extreme learning machine , 2016, 2016 24th Signal Processing and Communication Application Conference (SIU).

[43]  Muhammad Arif,et al.  Classification of cardiotocograms using random forest classifier and selection of important features from cardiotocogram signal , 2015 .

[44]  Sabina Martí Gamboa,et al.  Diagnostic Accuracy of the FIGO and the 5-Tier Fetal Heart Rate Classification Systems in the Detection of Neonatal Acidemia , 2016, American Journal of Perinatology.

[45]  Ito Wasito,et al.  Fetal state classification from cardiotocography based on feature extraction using hybrid K-Means and support vector machine , 2015, 2015 International Conference on Advanced Computer Science and Information Systems (ICACSIS).

[46]  S. Das,et al.  Determination of window size for baseline estimation of fetal heart rate using CTG , 2015, Proceedings of the 2015 Third International Conference on Computer, Communication, Control and Information Technology (C3IT).

[47]  Janusz Jezewski,et al.  Improving fetal heart rate signal interpretation by application of myriad filtering , 2013 .

[48]  George Nikolakopoulos,et al.  A one-class approach to cardiotocogram assessment , 2015, 2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).