The human brain connectome weighted by the myelin content and total intra-axonal cross-sectional area of white matter tracts.
Mark C NelsonJessica RoyerWen Da LuIlana R LeppertJennifer S W CampbellSimona SchiaviHyerang JinShahin TavakolReinder Vos de WaelRaul Rodriguez-CrucesGilbert Bruce PikeBoris C BernhardtAlessandro DaducciBratislav MišićChristine Lucas TardifPublished in: Network neuroscience (Cambridge, Mass.) (2023)
A central goal in neuroscience is the development of a comprehensive mapping between structural and functional brain features, which facilitates mechanistic interpretation of brain function. However, the interpretability of structure-function brain models remains limited by a lack of biological detail. Here, we characterize human structural brain networks weighted by multiple white matter microstructural features including total intra-axonal cross-sectional area and myelin content. We report edge-weight-dependent spatial distributions, variance, small-worldness, rich club, hubs, as well as relationships with function, edge length, and myelin. Contrasting networks weighted by the total intra-axonal cross-sectional area and myelin content of white matter tracts, we find opposite relationships with functional connectivity, an edge-length-independent inverse relationship with each other, and the lack of a canonical rich club in myelin-weighted networks. When controlling for edge length, networks weighted by either fractional anisotropy, radial diffusivity, or neurite density show no relationship with whole-brain functional connectivity. We conclude that the co-utilization of structural networks weighted by total intra-axonal cross-sectional area and myelin content could improve our understanding of the mechanisms mediating the structure-function brain relationship.