TY - JOUR
T1 - The modular organization of human anatomical brain networks
T2 - Accounting for the cost of wiring
AU - Betzel, Richard F.
AU - Medaglia, John D.
AU - Papadopoulos, Lia
AU - Baum, Graham L.
AU - Gur, Ruben
AU - Gur, Raquel
AU - Roalf, David
AU - Satterthwaite, Theodore D.
AU - Bassett, Danielle S.
N1 - Publisher Copyright:
© 2017 Massachusetts Institute of Technology Published under a Creative Commons Attribution 4.0 International (CC BY 4.0) license.
PY - 2017
Y1 - 2017
N2 - Brain networks are expected to be modular. However, existing techniques for estimating a network’s modules make it difficult to assess the influence of organizational principles such as wiring cost reduction on the detected modules. Here we present a modification of an existing module detection algorithm that allowed us to focus on connections that are unexpected under a cost-reduction wiring rule and to identify modules from among these connections. We applied this technique to anatomical brain networks and showed that the modules we detected differ from those detected using the standard technique. We demonstrated that these novel modules are spatially distributed, exhibit unique functional fingerprints, and overlap considerably with rich clubs, giving rise to an alternative and complementary interpretation of the functional roles of specific brain regions. Finally, we demonstrated that, using the modified module detection approach, we can detect modules in a developmental dataset that track normative patterns of maturation. Collectively, these findings support the hypothesis that brain networks are composed of modules and provide additional insight into the function of those modules.
AB - Brain networks are expected to be modular. However, existing techniques for estimating a network’s modules make it difficult to assess the influence of organizational principles such as wiring cost reduction on the detected modules. Here we present a modification of an existing module detection algorithm that allowed us to focus on connections that are unexpected under a cost-reduction wiring rule and to identify modules from among these connections. We applied this technique to anatomical brain networks and showed that the modules we detected differ from those detected using the standard technique. We demonstrated that these novel modules are spatially distributed, exhibit unique functional fingerprints, and overlap considerably with rich clubs, giving rise to an alternative and complementary interpretation of the functional roles of specific brain regions. Finally, we demonstrated that, using the modified module detection approach, we can detect modules in a developmental dataset that track normative patterns of maturation. Collectively, these findings support the hypothesis that brain networks are composed of modules and provide additional insight into the function of those modules.
KW - Community structure
KW - Complex networks
KW - Geometry
KW - Modularity
KW - Wiring cost
UR - https://www.scopus.com/pages/publications/85016718348
UR - https://www.scopus.com/pages/publications/85016718348#tab=citedBy
U2 - 10.1162/NETN_a_00002
DO - 10.1162/NETN_a_00002
M3 - Article
AN - SCOPUS:85016718348
SN - 2472-1751
VL - 1
SP - 42
EP - 68
JO - Network Neuroscience
JF - Network Neuroscience
IS - 1
ER -