Vigilance State Classification of Comatose Patients Based on Multifractal Analysis of EEG Signals
Various information can be inferred from electrical signals generated by the brain using the electroencephalogram (EEG). This information can be used for the detection or classification of several diseases using many signal processing methods. Multifractal analysis has been widely used in the last t...
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| Main Authors: | , , , |
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| Format: | Article |
| Language: | English |
| Published: |
IEEE
2025-01-01
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| Series: | IEEE Access |
| Subjects: | |
| Online Access: | https://ieeexplore.ieee.org/document/11095672/ |
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| Summary: | Various information can be inferred from electrical signals generated by the brain using the electroencephalogram (EEG). This information can be used for the detection or classification of several diseases using many signal processing methods. Multifractal analysis has been widely used in the last two decades to examine various electrical signals generated by the human body. In this study, we analyze the multifractal characteristics of a data set comprising 27 EEG signals where the objective is to demonstrate the efficacy of this method in differentiating the states of vigilance in patients. These signals are obtained from comatose patients in the intensive care unit of the National Institute of Neurology of Tunis, each of whom had a documented Glasgow coma scale score. The purpose of analyzing these data is to identify the connection between the coma scales and the signals generated by some regions of the cerebral cortex in the brain and how this could lead to determining the state of the coma of these patients based on their electrical brain activities, especially due to the number of limitations of the behavioral and physiological coma scales currently used. Because EEG signals are multifractal, we applied the wavelet leader method to extract features from the singularity spectra of the recorded signals with a known Glasgow coma scale and classify them. We found that the singularity spectrum curves of patients in deep, mild, and light coma are distant from each other. Furthermore, we found that the spectra of patients in a light coma are shifted to the right compared to those of patients in a deep coma. On the other hand, curves calculated from the sedated patients are on the left of the curves of those in deep coma and are shrinking in shape compared to non-sedated patients. The lighter the coma, the more distinct the curves, especially the frontal channel curves. We also calculated the h values at the peak of the singularity spectrum curves of three different channels from the three other areas of the brain for the three groups. We found that the results from the back areas of the brain are aligned with those from the frontal lobe area. The h value averages of sedated patients, deep coma patients, and light coma patients are 0.116, 0.196, and 0.317, respectively. These results provided strong evidence that the multifractal analysis of EEG signals can be utilized to classify the vigilance states of comatose patients. However, although this analysis overcomes the limited physiological scales currently used, it still needs more investigation with a large sample of comatose patients. |
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| ISSN: | 2169-3536 |