Exploring the limits of network topology estimation using diffusion-based tractography and tracer studies in the macaque cortex

Authors

Kelly Shen, Rotman Research Institute
Alexandros Goulas, Universitätsklinikum Hamburg-Eppendorf
David S. Grayson, University of California, Davis
John Eusebio, Rotman Research Institute
Joseph S. Gati, The University of Western Ontario
Ravi S. Menon, The University of Western Ontario
Anthony R. McIntosh, Rotman Research Institute
Stefan Everling, The University of Western OntarioFollow

Document Type

Article

Publication Date

5-1-2019

Journal

NeuroImage

Volume

191

First Page

81

Last Page

92

URL with Digital Object Identifier

10.1016/j.neuroimage.2019.02.018

Abstract

© 2019 Elsevier Inc. Reconstructing the anatomical pathways of the brain to study the human connectome has become an important endeavour for understanding brain function and dynamics. Reconstruction of the cortico-cortical connectivity matrix in vivo often relies on noninvasive diffusion-weighted imaging (DWI) techniques but the extent to which they can accurately represent the topological characteristics of structural connectomes remains unknown. We addressed this question by constructing connectomes using DWI data collected from macaque monkeys in vivo and with data from published invasive tracer studies. We found the strength of fiber tracts was well estimated from DWI and topological properties like degree and modularity were captured by tractography-based connectomes. Rich-club/core-periphery type architecture could also be detected but the classification of hubs using betweenness centrality, participation coefficient and core-periphery identification techniques was inaccurate. Our findings indicate that certain aspects of cortical topology can be faithfully represented in noninvasively-obtained connectomes while other network analytic measures warrant cautionary interpretations.

Notes

A pre-print of this article is available through BioRxiv at https://doi.org/10.1101/356576