Functional Graph Alterations in Schizophrenia: a Result from a Global Anatomic Decoupling?

Overview

Journal Pharmacopsychiatry

Specialties Pharmacology
Psychiatry

Date 2012 May 9

PMID 22565236

Citations 22

Authors

J Cabral

M L Kringelbach

G Deco

Affiliations

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Abstract

During rest, the brain exhibits slow hemodynamic fluctuations (<0.1 Hz) that are correlated across spatially segregated brain regions, defining functional networks. Resting-state functional networks of people with schizophrenia were found to have graph properties that differ from those of control subjects. Namely, functional graphs from patients exhibit reduced small-worldness, increased hierarchy, lower clustering, improved efficiency and greater robustness. Notably, most of these parameters correlate with patients' cognitive performance.To test if a brain-wide coupling deficit could be at the origin of such network reorganization, we use a model of resting-state activity where the coupling strength can be manipulated. For a range of coupling values, the simulated functional graphs obtained were characterized using graph theory.For a coupling range, simulated graphs shared properties of healthy resting-state functional graphs. On decreasing the coupling strength, the resultant functional graphs exhibited a topological reorganization, in the same way as described in schizophrenia.This work shows how complex functional graph alterations reported in schizophrenia can be accounted for by a decrease in the structural coupling strength. These results are corroborated by reports of lower white matter density in schizophrenia.

Citing Articles

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Exploring global and local processes underlying alterations in resting-state functional connectivity and dynamics in schizophrenia.

Metzner C, Dimulescu C, Kamp F, Fromm S, Uhlhaas P, Obermayer K Front Psychiatry. 2024; 15:1352641.

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Metastable oscillatory modes emerge from synchronization in the brain spacetime connectome.

Cabral J, Castaldo F, Vohryzek J, Litvak V, Bick C, Lambiotte R Commun Phys. 2024; 5:184.

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Functional Connectivity Alterations of Within and Between Networks in Schizophrenia: A Retrospective Study.

Keyvanfard F, Schmid A, Nasiraei-Moghaddam A Basic Clin Neurosci. 2023; 14(3):397-409.

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Lawn T, Howard M, Turkheimer F, Misic B, Deco G, Martins D Neurosci Biobehav Rev. 2023; 150:105193.

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