Affiliations: [a] Electronics and Communications Engineering Department, Arab Academy for Science and Technology, Cairo, Egypt | [b] School of Electrical Engineering, Universiti Teknologi Malaysia, Johor, Malaysia | [c] School of Biomedical Engineering and Health Sciences, Universiti Teknologi Malaysia, Johor, Malaysia
Correspondence:
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Corresponding author: Ismail M. El-Badawy, Electronics and Communications Engineering Department, Arab Academy for Science and Technology, Cairo, Egypt. E-mail: ismailelbadawy@aast.edu.
Abstract: BACKGROUND: The quantitative features of a capnogram signal are important clinical metrics in assessing pulmonary function. However, these features should be quantified from the regular (artefact-free) segments of the capnogram waveform. OBJECTIVE: This paper presents a machine learning-based approach for the automatic classification of regular and irregular capnogram segments. METHODS: Herein, we proposed four time- and two frequency-domain features experimented with the support vector machine classifier through ten-fold cross-validation. MATLAB simulation was conducted on 100 regular and 100 irregular 15 s capnogram segments. Analysis of variance was performed to investigate the significance of the proposed features. Pearson’s correlation was utilized to select the relatively most substantial ones, namely variance and the area under normalized magnitude spectrum. Classification performance, using these features, was evaluated against two feature sets in which either time- or frequency-domain features only were employed. RESULTS: Results showed a classification accuracy of 86.5%, which outperformed the other cases by an average of 5.5%. The achieved specificity, sensitivity, and precision were 84%, 89% and 86.51%, respectively. The average execution time for feature extraction and classification per segment is only 36 ms. CONCLUSION: The proposed approach can be integrated with capnography devices for real-time capnogram-based respiratory assessment. However, further research is recommended to enhance the classification performance.
