Network Neuroscience (Jan 2023)

The topology, stability, and instability of learning-induced brain network repertoires in schizophrenia

  • Emmanuel D. Meram,
  • Shahira Baajour,
  • Asadur Chowdury,
  • John Kopchick,
  • Patricia Thomas,
  • Usha Rajan,
  • Dalal Khatib,
  • Caroline Zajac-Benitez,
  • Luay Haddad,
  • Alireza Amirsadri,
  • Jeffrey A. Stanley,
  • Vaibhav A. Diwadkar

DOI
https://doi.org/10.1162/netn_a_00278
Journal volume & issue
Vol. 7, no. 1
pp. 184 – 212

Abstract

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AbstractThere is a paucity of graph theoretic methods applied to task-based data in schizophrenia (SCZ). Tasks are useful for modulating brain network dynamics, and topology. Understanding how changes in task conditions impact inter-group differences in topology can elucidate unstable network characteristics in SCZ. Here, in a group of patients and healthy controls (n = 59 total, 32 SCZ), we used an associative learning task with four distinct conditions (Memory Formation, Post-Encoding Consolidation, Memory Retrieval, and Post-Retrieval Consolidation) to induce network dynamics. From the acquired fMRI time series data, betweenness centrality (BC), a metric of a node’s integrative value was used to summarize network topology in each condition. Patients showed (a) differences in BC across multiple nodes and conditions; (b) decreased BC in more integrative nodes, but increased BC in less integrative nodes; (c) discordant node ranks in each of the conditions; and (d) complex patterns of stability and instability of node ranks across conditions. These analyses reveal that task conditions induce highly variegated patterns of network dys-organization in SCZ. We suggest that the dys-connection syndrome that is schizophrenia, is a contextually evoked process, and that the tools of network neuroscience should be oriented toward elucidating the limits of this dys-connection.