Investigating brain cortical activity in patients with post-COVID-19 brain fog

Grzegorz M Wojcik; Oren Shriki; Lukasz Kwasniewicz; Andrzej Kawiak; Yarden Ben-Horin; Sagi Furman; Krzysztof Wróbel; Bernadetta Bartosik; Ewelina Panas

doi:10.3389/fnins.2023.1019778

Investigating brain cortical activity in patients with post-COVID-19 brain fog

Front Neurosci. 2023 Feb 9:17:1019778. doi: 10.3389/fnins.2023.1019778. eCollection 2023.

Authors

Grzegorz M Wojcik¹, Oren Shriki^{2

3}, Lukasz Kwasniewicz¹, Andrzej Kawiak¹, Yarden Ben-Horin², Sagi Furman², Krzysztof Wróbel¹, Bernadetta Bartosik¹, Ewelina Panas⁴

Affiliations

¹ Department of Neuroinformatics and Biomedical Engineering, Institute of Computer Science, Maria Curie-Sklodowska University in Lublin, Lublin, Poland.
² Department of Cognitive and Brain Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel.
³ Department of Computer Science, Ben-Gurion University of the Negev, Beer-Sheva, Israel.
⁴ Department of International Relations, Faculty of Political Science and Journalism, Maria Curie-Sklodowska University in Lublin, Lublin, Poland.

Abstract

Brain fog is a kind of mental problem, similar to chronic fatigue syndrome, and appears about 3 months after the infection with COVID-19 and lasts up to 9 months. The maximum magnitude of the third wave of COVID-19 in Poland was in April 2021. The research referred here aimed at carrying out the investigation comprising the electrophysiological analysis of the patients who suffered from COVID-19 and had symptoms of brain fog (sub-cohort A), suffered from COVID-19 and did not have symptoms of brain fog (sub-cohort B), and the control group that had no COVID-19 and no symptoms (sub-cohort C). The aim of this article was to examine whether there are differences in the brain cortical activity of these three sub-cohorts and, if possible differentiate and classify them using the machine-learning tools. he dense array electroencephalographic amplifier with 256 electrodes was used for recordings. The event-related potentials were chosen as we expected to find the differences in the patients' responses to three different mental tasks arranged in the experiments commonly known in experimental psychology: face recognition, digit span, and task switching. These potentials were plotted for all three patients' sub-cohorts and all three experiments. The cross-correlation method was used to find differences, and, in fact, such differences manifested themselves in the shape of event-related potentials on the cognitive electrodes. The discussion of such differences will be presented; however, an explanation of such differences would require the recruitment of a much larger cohort. In the classification problem, the avalanche analysis for feature extractions from the resting state signal and linear discriminant analysis for classification were used. The differences between sub-cohorts in such signals were expected to be found. Machine-learning tools were used, as finding the differences with eyes seemed impossible. Indeed, the A&B vs. C, B&C vs. A, A vs. B, A vs. C, and B vs. C classification tasks were performed, and the efficiency of around 60-70% was achieved. In future, probably there will be pandemics again due to the imbalance in the natural environment, resulting in the decreasing number of species, temperature increase, and climate change-generated migrations. The research can help to predict brain fog after the COVID-19 recovery and prepare the patients for better convalescence. Shortening the time of brain fog recovery will be beneficial not only for the patients but also for social conditions.

Keywords: COVID-19; EEG; ERP; LDA; brain fog; cortical activity.

Grants and funding

This study was financed by the Polish National Agency for Academic Exchange under the NAWA Urgency Grants program within the framework of the project titled Understanding the Brain Fog-Research on COVID-19 Post-Infectious Chronic Fatigue Syndrome (contract no. BPN/GIN/2021/1/00019/U/00001).