A network of topographic numerosity maps in human association cortex

Sensory and motor cortices each contain multiple topographic maps with the structure of sensory organs (such as the retina or cochlea) mapped onto the cortical surface. These sensory maps are hierarchically organized. For example, visual field maps contain neurons that represent increasingly large p...

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Bibliographic Details
Published in:Nature human behaviour 2017-01, Vol.1 (2), p.0036, Article 0036
Main Authors: Harvey, Ben M., Dumoulin, Serge O.
Format: Article
Language:English
Subjects:
631/378/2649/1723
631/477/2811
Behavioral Sciences
Biological organs
Biomedical and Life Sciences
Cognitive functioning
Cognitive systems
Cortex
Decision making
Experimental Psychology
Functional magnetic resonance imaging
letter
Life Sciences
Magnetic resonance imaging
Mathematics
Microeconomics
Neurons
Neurosciences
Personality and Social Psychology
Topography
Visual space
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Summary:Sensory and motor cortices each contain multiple topographic maps with the structure of sensory organs (such as the retina or cochlea) mapped onto the cortical surface. These sensory maps are hierarchically organized. For example, visual field maps contain neurons that represent increasingly large parts of visual space with increasingly complex responses 1 . Some visual neurons respond to stimuli with a particular numerosity — the number of objects in a set. We recently discovered a parietal topographic numerosity map in which neural numerosity preferences progress gradually across the cortical surface 2 , analogous to sensory maps. Following this analogy, we hypothesized that there may be multiple numerosity maps. Numerosity perception is implicated in many cognitive functions, including foraging 3 , multiple object tracking 4 , dividing attention 5 , decision-making 6 and mathematics 7 – 9 . Here we use ultra-high-field (7 Tesla, 7T) functional magnetic resonance imaging (fMRI) and neural-model-based analyses to reveal numerosity-selective neural populations organized into six widely separated topographic maps in each hemisphere. Although we describe subtle differences between these maps, their properties are very similar, unlike in sensory map hierarchies. These maps are found in areas implicated in object recognition, motion perception, attention control, decision-making and mathematics. Multiple numerosity maps may allow interactions with these cognitive systems, suggesting a broad role for quantity processing in supporting many perceptual and cognitive functions. Using ultra-high-field functional magnetic resonance imaging, the authors identify six widely separated maps in the human cortex that code for numerosity (the number of objects in a set).
ISSN:2397-3374
2397-3374
DOI:10.1038/s41562-016-0036