Deforming the metric of cognitive maps distorts memory

Environmental boundaries anchor cognitive maps that support memory. However, trapezoidal boundary geometry distorts the regular firing patterns of entorhinal grid cells, proposedly providing a metric for cognitive maps. Here we test the impact of trapezoidal boundary geometry on human spatial memory...

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Bibliographic Details
Published in:Nature human behaviour 2020-02, Vol.4 (2), p.177-188
Main Authors: Bellmund, Jacob L. S., de Cothi, William, Ruiter, Tom A., Nau, Matthias, Barry, Caswell, Doeller, Christian F.
Format: Article
Language:English
Subjects:
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631/477/2811
Adult
Animal memory
Behavioral Sciences
Biomedical and Life Sciences
Cognitive functioning
Cognitive mapping
Cognitive models
Cognitive-behavioral factors
Dismissal
Experimental Psychology
Female
Geometry
Grid Cells - physiology
Humans
Life Sciences
Male
Memory bias
Microeconomics
Navigation
Neurosciences
Personality and Social Psychology
Regularity
Space Perception - physiology
Spatial Behavior - physiology
Spatial memory
Spatial Memory - physiology
Virtual Reality
Young Adult
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Summary:Environmental boundaries anchor cognitive maps that support memory. However, trapezoidal boundary geometry distorts the regular firing patterns of entorhinal grid cells, proposedly providing a metric for cognitive maps. Here we test the impact of trapezoidal boundary geometry on human spatial memory using immersive virtual reality. Consistent with reduced regularity of grid patterns in rodents and a grid-cell model based on the eigenvectors of the successor representation, human positional memory was degraded in a trapezoid environment compared with a square environment—an effect that was particularly pronounced in the narrow part of the trapezoid. Congruent with changes in the spatial frequency of eigenvector grid patterns, distance estimates between remembered positions were persistently biased, revealing distorted memory maps that explained behaviour better than the objective maps. Our findings demonstrate that environmental geometry affects human spatial memory in a similar manner to rodent grid-cell activity and, therefore, strengthen the putative link between grid cells and behaviour along with their cognitive functions beyond navigation. Bellmund et al. use immersive virtual reality combined with successor representation modelling to show that environmental geometry distorts human spatial memory consistent with deformations of grid-cell firing patterns in navigating rodents.
ISSN:2397-3374
2397-3374
DOI:10.1038/s41562-019-0767-3