Functional gradients, in which response properties change gradually across the cortical surface, have been proposed as a key organising principle of the brain. However, the presence of these gradients remains undetermined in many brain regions. Resting-state neuroimaging studies have suggested these gradients can be reconstructed from patterns of functional connectivity. Here we investigate the accuracy of these reconstructions and establish whether it is connectivity or the functional properties within a region that determine these "connectopic maps". Different manifold learning techniques were used to recover visual field maps while participants were at rest or engaged in natural viewing. We benchmarked these reconstructions against maps ...
AbstractA quarter-century ago visual neuroscientists had little information about the number and org...
Much of the visual cortex is organized into visual field maps: nearby neurons have receptive fields ...
The functional organization of the brain can be represented as a low-dimensional space that reflects...
Functional gradients, in which response properties change gradually across a brain region, have been...
Human visual cortex contains topographic visual field maps whose organization can be revealed with r...
Brain regions are often topographically connected: nearby locations within one brain area connect wi...
One way to study connectivity in visual cortical areas is by examining spontaneous neural activity. ...
The cortical visual system is composed of many areas serving various visual functions. In non-human ...
SummaryMuch of the visual cortex is organized into visual field maps: nearby neurons have receptive ...
AbstractHuman visual cortical fields (VCFs) vary in size and anatomical location across individual s...
Neural activity in mammalian brains exhibits large spontaneous fluctuations whose structure reveals ...
Classical models of brain organization have often considered the brain to be made up of a mosaic of ...
International audienceGradients capture some of the variance of the resting-state functional magneti...
Human behavior and cognition are largely supported by the cerebral cortex, a structure organized at ...
International audienceFunctional neuroimaging provides the unique opportunity to characterize brain ...
AbstractA quarter-century ago visual neuroscientists had little information about the number and org...
Much of the visual cortex is organized into visual field maps: nearby neurons have receptive fields ...
The functional organization of the brain can be represented as a low-dimensional space that reflects...
Functional gradients, in which response properties change gradually across a brain region, have been...
Human visual cortex contains topographic visual field maps whose organization can be revealed with r...
Brain regions are often topographically connected: nearby locations within one brain area connect wi...
One way to study connectivity in visual cortical areas is by examining spontaneous neural activity. ...
The cortical visual system is composed of many areas serving various visual functions. In non-human ...
SummaryMuch of the visual cortex is organized into visual field maps: nearby neurons have receptive ...
AbstractHuman visual cortical fields (VCFs) vary in size and anatomical location across individual s...
Neural activity in mammalian brains exhibits large spontaneous fluctuations whose structure reveals ...
Classical models of brain organization have often considered the brain to be made up of a mosaic of ...
International audienceGradients capture some of the variance of the resting-state functional magneti...
Human behavior and cognition are largely supported by the cerebral cortex, a structure organized at ...
International audienceFunctional neuroimaging provides the unique opportunity to characterize brain ...
AbstractA quarter-century ago visual neuroscientists had little information about the number and org...
Much of the visual cortex is organized into visual field maps: nearby neurons have receptive fields ...
The functional organization of the brain can be represented as a low-dimensional space that reflects...