Situating the default-mode network along a principal gradient of macroscale cortical organization

Understanding how the structure of cognition arises from the topographical organization of the cortex is a primary goal in neuroscience. Previous work has described local functional gradients extending from perceptual and motor regions to cortical areas representing more abstract functions, but an o...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 113; no. 44; pp. 12574 - 12579
Main Authors Margulies, Daniel S., Ghosh, Satrajit S., Goulas, Alexandros, Falkiewicz, Marcel, Huntenburg, Julia M., Langs, Georg, Bezgin, Gleb, Eickhoff, Simon B., Castellanos, F. Xavier, Petrides, Michael, Jefferies, Elizabeth, Smallwood, Jonathan
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 01.11.2016
SeriesFrom the Cover
Subjects
Animals
Biological Sciences
Brain - physiology
Brain Mapping
Cognition & reasoning
Humans
Macaca
Magnetic Resonance Imaging - methods
Models, Neurological
Morphology
Motor ability
Nerve Net - physiology
Neurosciences
Sensation - physiology
Sensorimotor Cortex - physiology
Sensory perception
default-mode network
cortical organization
connectivity
gradients
topography
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Summary:Understanding how the structure of cognition arises from the topographical organization of the cortex is a primary goal in neuroscience. Previous work has described local functional gradients extending from perceptual and motor regions to cortical areas representing more abstract functions, but an overarching framework for the association between structure and function is still lacking. Here, we show that the principal gradient revealed by the decomposition of connectivity data in humans and the macaque monkey is anchored by, at one end, regions serving primary sensory/motor functions and at the other end, transmodal regions that, in humans, are known as the default-mode network (DMN). These DMN regions exhibit the greatest geodesic distance along the cortical surface—and are precisely equidistant—from primary sensory/motor morphological landmarks. The principal gradient also provides an organizing spatial framework for multiple large-scale networks and characterizes a spectrum from unimodal to heteromodal activity in a functional metaanalysis. Together, these observations provide a characterization of the topographical organization of cortex and indicate that the role of the DMN in cognition might arise from its position at one extreme of a hierarchy, allowing it to process transmodal information that is unrelated to immediate sensory input.
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Edited by Peter L. Strick, University of Pittsburgh, Pittsburgh, PA, and approved September 9, 2016 (received for review May 27, 2016)
Author contributions: D.S.M., M.P., E.J., and J.S. designed research; D.S.M. performed research; D.S.M., S.S.G., M.F., J.M.H., G.L., G.B., and S.B.E. contributed new reagents/analytic tools; D.S.M. analyzed data; and D.S.M., S.S.G., A.G., M.F., J.M.H., G.L., G.B., S.B.E., F.X.C., M.P., E.J., and J.S. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1608282113