Abstract
Obstructive sleep apnea (OSAS), which is one of the leading sleep disorders and can result in death if not diagnosed and treated early, is most often confused with snoring. OSAS disease, the prevalence of which varies between 0.9% and 1.9% in Turkey, is a serious health problem that occurs as a result of complete or partial obstruction of the respiratory tract during sleep, resulting in sleep disruption, poor quality sleep, paralysis and even death in sleep. Polysomnography signal recordings (PSG) obtained from sleep laboratories are used for the diagnosis of OSAS, which is related to factors such as the individual's age, gender, neck diameter, smoking-alcohol consumption, and the occurrence of other sleep disorders. Polysomnography is used in the diagnosis and treatment of sleep disorders such as snoring, sleep apnea, parasomnia (abnormal behaviors during sleep), narcolepsy (sleep attacks that develop during the day) and restless legs syndrome. It allows recording various parameters such as brain waves, eye movements, heart and chest activity measurement, respiratory activities, and the amount of oxygen in the blood with the help of electrodes placed in different parts of the patient's body during night sleep. In this article, the performance of PSG signal data for the diagnosis of sleep apnea was examined on the basis of both signal parameters and the method used. First, feature extraction was made from PSG signals, then the feature vector was classified with Artificial Neural Networks, Support Vector Machine (SVM), k-Nearest Neighbors (k-NN) and Logistic Regression (LR).
Reference25 articles.
1. Akılotu BN, Tuncer SA. OSAS Evaluation By Means Of Machine Learning And Artificial Neural Networks By Using Polisomnographic Report Data, International Conference on Engineering Technologies (ICENTE’17), 2017.
2. Demir A, et al. Türk Toraks Derneği Obstrüktif Uyku Apne Sendromu Tanı Ve Tedavi Uzlaşı Raporu”, Türk Toraks Dergisi, Cilt 13, Vol.13, 2012.
3. Xıe J, Yu W, Wan Z, Han F, Wang Q, Chen R. Correlation Analysis between Obstructive Sleep Apnea Syndrome (OSAS) and Heart Rate Variability, Iran J Public Health., 46(11), p:1502–1511, 2017.
4. Marcos C, Hornero JVR, Álvarez D, Nabney IT. Automated detection of obstructive sleep apnoea syndrome from oxygen saturation recordings using linear discriminant analysis, Med Biol Eng Comput ., 48(9):895-902, 2010.
5. Liu D, Pang Z, Lloyd SR. A neural network method for detection of obstructive sleep apnea and narcolepsy based on pupil size and EEG, IEEE Transactions on Neural Networks, 19(2), 308-318, 2008.