Brain Structural Alterations Are Distributed Following Functional, Anatomic and Genetic Connectivity

Overview

Journal Brain

Publisher Oxford University Press

Specialty Neurology

Date 2018 Oct 23

PMID 30346490

Citations 34

Authors

Franco Cauda

Andrea Nani

Jordi Manuello

Enrico Premi

Sara Palermo

Karina Tatu

Sergio Duca

Peter T Fox

Tommaso Costa

Affiliations

Soon will be listed here.

Abstract

The pathological brain is characterized by distributed morphological or structural alterations in the grey matter, which tend to follow identifiable network-like patterns. We analysed the patterns formed by these alterations (increased and decreased grey matter values detected with the voxel-based morphometry technique) conducting an extensive transdiagnostic search of voxel-based morphometry studies in a large variety of brain disorders. We devised an innovative method to construct the networks formed by the structurally co-altered brain areas, which can be considered as pathological structural co-alteration patterns, and to compare these patterns with three associated types of connectivity profiles (functional, anatomical, and genetic). Our study provides transdiagnostical evidence that structural co-alterations are influenced by connectivity constraints rather than being randomly distributed. Analyses show that although all the three types of connectivity taken together can account for and predict with good statistical accuracy, the shape and temporal development of the co-alteration patterns, functional connectivity offers the better account of the structural co-alteration, followed by anatomic and genetic connectivity. These results shed new light on the possible mechanisms at the root of neuropathological processes and open exciting prospects in the quest for a better understanding of brain disorders.

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