The functional consequences of cortical circuit abnormalities on gamma oscillations in schizophrenia: insights from computational modeling

The functional consequences of cortical circuit abnormalities on gamma oscillations in schizophrenia: insights from computational modeling

Schizophrenia is characterized by cortical circuit abnormalities, which might be reflected in gamma-frequency (30-100 Hz) oscillations in the electroencephalogram. Here we used a computational model of cortical circuitry to examine the effects that neural circuit abnormalities might have on gamma ge...

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Bibliographic Details
Published in:Frontiers in human neuroscience Vol. 3; p. 33
Main Author: Spencer, Kevin M
Format: Journal Article
Language:English
Published: Switzerland Frontiers Research Foundation 20-10-2009
Frontiers Media S.A
Subjects:
Animal models
computational model
Computational neuroscience
Cortex
cortical excitability
EEG
Electroencephalography
Excitability
gamma oscillation
Hallucinations
Interneurons
Mental disorders
N-Methyl-D-aspartic acid
Neural networks
Neurons
Neuroscience
NMR
Nuclear magnetic resonance
Oscillations
Pyramidal cells
Schizophrenia
United States > US
computational model
schizophrenia
gamma oscillation
cortical excitability
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Summary:Schizophrenia is characterized by cortical circuit abnormalities, which might be reflected in gamma-frequency (30-100 Hz) oscillations in the electroencephalogram. Here we used a computational model of cortical circuitry to examine the effects that neural circuit abnormalities might have on gamma generation and network excitability. The model network consisted of 1000 leaky integrate-and-fire neurons with realistic connectivity patterns and proportions of neuron types [pyramidal cells (PCs), regular-spiking inhibitory interneurons, and fast-spiking interneurons (FSIs)]. The network produced a gamma oscillation when driven by noise input. We simulated reductions in: (1) recurrent excitatory inputs to PCs; (2) both excitatory and inhibitory inputs to PCs; (3) all possible connections between cells; (4) reduced inhibitory output from FSIs; and (5) reduced NMDA input to FSIs. Reducing all types of synaptic connectivity sharply reduced gamma power and phase synchrony. Network excitability was reduced when recurrent excitatory connections were deleted, but the network showed disinhibition effects when inhibitory connections were deleted. Reducing FSI output impaired gamma generation to a lesser degree than reducing synaptic connectivity, and increased network excitability. Reducing FSI NMDA input also increased network excitability, but increased gamma power. The results of this study suggest that a multimodal approach, combining non-invasive neurophysiological and structural measures, might be able to distinguish between different neural circuit abnormalities in schizophrenia patients. Computational modeling may help to bridge the gaps between post-mortem studies, animal models, and experimental data in humans, and facilitate the development of new therapies for schizophrenia and neuropsychiatric disorders in general.
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Reviewed by: Tom Eichele, University of Bergen, Norway; Kenneth Hugdahl, University of Bergen, Norway
Edited by: Kenneth Hugdahl, University of Bergen, Norway
ISSN:1662-5161
1662-5161
DOI:10.3389/neuro.09.033.2009