EEG resting state alpha dynamics predict an individual's vulnerability to auditory hallucinations

H. Honcamp; S. X. Duggirala; J. R. Climent; A. Astudillo; N. J. Trujillo-Barreto; M. Schwartze; D. E. J. Linden; T. A. M. J. van Amelsvoort; W. El-Deredy; S. A. Kotz

doi:10.1007/s11571-024-10093-1

EEG resting state alpha dynamics predict an individual's vulnerability to auditory hallucinations

H. Honcamp, S. X. Duggirala, J. R. Climent, A. Astudillo, N. J. Trujillo-Barreto, M. Schwartze, D. E. J. Linden, T. A. M. J. van Amelsvoort, W. El-Deredy, S. A. Kotz

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Abstract

Task-free brain activity exhibits spontaneous fluctuations between functional states, characterized by synchronized activation patterns in distributed resting-state (RS) brain networks. The temporal dynamics of the networks’ electrophysiological signatures reflect individual variations in brain activity and connectivity linked to mental states and cognitive functions and can predict or monitor vulnerability to develop psychiatric or neurological disorders. In particular, RS alpha fluctuations modulate perceptual sensitivity, attentional shifts, and cognitive control, and could therefore reflect a neural correlate of increased vulnerability to sensory distortions, including the proneness to hallucinatory experiences. We recorded 5 min of RS EEG from 33 non-clinical individuals varying in hallucination proneness (HP) to investigate links between task-free alpha dynamics and vulnerability to hallucinations. To this end, we used a dynamic brain state allocation method to identify five recurrent alpha states together with their spatiotemporal dynamics and most active brain areas through source reconstruction. The dynamical features of a state marked by activation in somatosensory, auditory, and posterior default-mode network areas predicted auditory and auditory-verbal HP, but not general HP, such that individuals with higher vulnerability to auditory hallucinations spent more time in this state. The temporal dynamics of spontaneous alpha activity might reflect individual differences in attention to internally generated sensory events and altered auditory perceptual sensitivity. Altered RS alpha dynamics could therefore instantiate a neural marker of increased vulnerability to auditory hallucinations.

Original language	English
Pages (from-to)	2405-2417
Number of pages	13
Journal	Cognitive Neurodynamics
Volume	18
Issue number	5
DOIs	https://doi.org/10.1007/s11571-024-10093-1
Publication status	Published - Oct 2024

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Keywords

Temporal dynamics
Risk assessment
Alpha
Hidden semi-Markov modeling
EEG resting state
Hallucination proneness

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10.1007/s11571-024-10093-1

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Honcamp, H., Duggirala, S. X., Climent, J. R., Astudillo, A., Trujillo-Barreto, N. J., Schwartze, M., Linden, D. E. J., van Amelsvoort, T. A. M. J., El-Deredy, W., & Kotz, S. A. (2024). EEG resting state alpha dynamics predict an individual's vulnerability to auditory hallucinations. Cognitive Neurodynamics, 18(5), 2405-2417. https://doi.org/10.1007/s11571-024-10093-1

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abstract = "Task-free brain activity exhibits spontaneous fluctuations between functional states, characterized by synchronized activation patterns in distributed resting-state (RS) brain networks. The temporal dynamics of the networks{\textquoteright} electrophysiological signatures reflect individual variations in brain activity and connectivity linked to mental states and cognitive functions and can predict or monitor vulnerability to develop psychiatric or neurological disorders. In particular, RS alpha fluctuations modulate perceptual sensitivity, attentional shifts, and cognitive control, and could therefore reflect a neural correlate of increased vulnerability to sensory distortions, including the proneness to hallucinatory experiences. We recorded 5 min of RS EEG from 33 non-clinical individuals varying in hallucination proneness (HP) to investigate links between task-free alpha dynamics and vulnerability to hallucinations. To this end, we used a dynamic brain state allocation method to identify five recurrent alpha states together with their spatiotemporal dynamics and most active brain areas through source reconstruction. The dynamical features of a state marked by activation in somatosensory, auditory, and posterior default-mode network areas predicted auditory and auditory-verbal HP, but not general HP, such that individuals with higher vulnerability to auditory hallucinations spent more time in this state. The temporal dynamics of spontaneous alpha activity might reflect individual differences in attention to internally generated sensory events and altered auditory perceptual sensitivity. Altered RS alpha dynamics could therefore instantiate a neural marker of increased vulnerability to auditory hallucinations.",

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AU - Honcamp, H.

AU - Duggirala, S. X.

AU - Climent, J. R.

AU - Astudillo, A.

AU - Trujillo-Barreto, N. J.

AU - Schwartze, M.

AU - Linden, D. E. J.

AU - van Amelsvoort, T. A. M. J.

AU - El-Deredy, W.

AU - Kotz, S. A.

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/10

Y1 - 2024/10

N2 - Task-free brain activity exhibits spontaneous fluctuations between functional states, characterized by synchronized activation patterns in distributed resting-state (RS) brain networks. The temporal dynamics of the networks’ electrophysiological signatures reflect individual variations in brain activity and connectivity linked to mental states and cognitive functions and can predict or monitor vulnerability to develop psychiatric or neurological disorders. In particular, RS alpha fluctuations modulate perceptual sensitivity, attentional shifts, and cognitive control, and could therefore reflect a neural correlate of increased vulnerability to sensory distortions, including the proneness to hallucinatory experiences. We recorded 5 min of RS EEG from 33 non-clinical individuals varying in hallucination proneness (HP) to investigate links between task-free alpha dynamics and vulnerability to hallucinations. To this end, we used a dynamic brain state allocation method to identify five recurrent alpha states together with their spatiotemporal dynamics and most active brain areas through source reconstruction. The dynamical features of a state marked by activation in somatosensory, auditory, and posterior default-mode network areas predicted auditory and auditory-verbal HP, but not general HP, such that individuals with higher vulnerability to auditory hallucinations spent more time in this state. The temporal dynamics of spontaneous alpha activity might reflect individual differences in attention to internally generated sensory events and altered auditory perceptual sensitivity. Altered RS alpha dynamics could therefore instantiate a neural marker of increased vulnerability to auditory hallucinations.

AB - Task-free brain activity exhibits spontaneous fluctuations between functional states, characterized by synchronized activation patterns in distributed resting-state (RS) brain networks. The temporal dynamics of the networks’ electrophysiological signatures reflect individual variations in brain activity and connectivity linked to mental states and cognitive functions and can predict or monitor vulnerability to develop psychiatric or neurological disorders. In particular, RS alpha fluctuations modulate perceptual sensitivity, attentional shifts, and cognitive control, and could therefore reflect a neural correlate of increased vulnerability to sensory distortions, including the proneness to hallucinatory experiences. We recorded 5 min of RS EEG from 33 non-clinical individuals varying in hallucination proneness (HP) to investigate links between task-free alpha dynamics and vulnerability to hallucinations. To this end, we used a dynamic brain state allocation method to identify five recurrent alpha states together with their spatiotemporal dynamics and most active brain areas through source reconstruction. The dynamical features of a state marked by activation in somatosensory, auditory, and posterior default-mode network areas predicted auditory and auditory-verbal HP, but not general HP, such that individuals with higher vulnerability to auditory hallucinations spent more time in this state. The temporal dynamics of spontaneous alpha activity might reflect individual differences in attention to internally generated sensory events and altered auditory perceptual sensitivity. Altered RS alpha dynamics could therefore instantiate a neural marker of increased vulnerability to auditory hallucinations.

KW - Temporal dynamics

KW - Risk assessment

KW - Alpha

KW - Hidden semi-Markov modeling

KW - EEG resting state

KW - Hallucination proneness

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SN - 1871-4080

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JO - Cognitive Neurodynamics

JF - Cognitive Neurodynamics

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ER -

EEG resting state alpha dynamics predict an individual's vulnerability to auditory hallucinations

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Keywords

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