Possible Neuropathological Mechanisms Underlying the Increased Complexity of Brain Electrical Activity in Schizophrenia: A Computational Study

Objective: Schizophrenia is a complex neurodevelopmental illness that is associated with different deficits in the cerebral cortex and neural networks, resulting in irregularity of brain waves. Various neuropathological hypotheses have been proposed for this irregularity that we intend to examine in...

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Published in:Iranian journal of psychiatry Vol. 18; no. 2; pp. 127 - 133
Main Authors: Khaleghi, Ali, Mohammadi, Mohammad Reza, Shahi, Kian, Nasrabadi, Ali Motie
Format: Journal Article
Language:English
Published: Iran Tehran University of Medical Sciences, Psychiatry and Psychology Research Center 01.04.2023
Psychiatry & Psychology Research Center, Tehran University of Medical Sciences
Tehran University of Medical Sciences
Subjects:
Computational Modelling
Hypotheses
Neural networks
Neuropathology
Neurophysiology
Original
Schizophrenia
Schizophrenia
Computational Modelling
Neuropathology
Neurophysiology
ISSN:2008-2215, 1735-4587, 1735-4587, 2008-2215
Online Access:Get full text
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Summary:Objective: Schizophrenia is a complex neurodevelopmental illness that is associated with different deficits in the cerebral cortex and neural networks, resulting in irregularity of brain waves. Various neuropathological hypotheses have been proposed for this irregularity that we intend to examine in this computational study. Method: We used a mathematical model of a neuronal population based on cellular automata to examine two hypotheses about the neuropathology of schizophrenia: first, reducing neuronal stimulation thresholds to increase neuronal excitability; and second, increasing the percentage of excitatory neurons and decreasing the percentage of inhibitory neurons to increase the excitation to inhibition ratio in the neuronal population. Then, we compare the complexity of the output signals produced by the model in both cases with real healthy resting-state electroencephalogram (EEG) signals using the Lempel-Ziv complexity measure and see if these changes alter (increase or decrease) the complexity of the neuronal population dynamics. Results: By lowering the neuronal stimulation threshold (i.e., the first hypothesis), no significant change in the pattern and amplitude of the network complexity was observed, and the model complexity was very similar to the complexity of real EEG signals (P > 0.05). However, increasing the excitation to inhibition ratio (i.e., the second hypothesis) led to significant changes in the complexity pattern of the designed network (P < 0.05). More interestingly, in this case, the complexity of the output signals of the model increased significantly compared to real healthy EEGs (P = 0.002) and the model output of the unchanged condition (P = 0.028) and the first hypothesis (P = 0.001). Conclusion: Our computational model suggests that imbalances in the excitation to inhibition ratio in the neural network are probably the source of abnormal neuronal firing patterns and thus the cause of increased complexity of brain electrical activity in schizophrenia.
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ISSN:2008-2215
1735-4587
1735-4587
2008-2215
DOI:10.18502/ijps.v18i2.12363