Can rodents conceive hyperbolic spaces?
Abstract
The grid cells discovered in the rodent medial entorhinal cortex have been proposed to provide a metric for Euclidean space, possibly even hardwired in the embryo. Yet one class of models describing the formation of grid unit selectivity is entirely based on developmental self-organization, and as such it predicts that the metric it expresses should reflect the environment to which the animal has adapted. We show that, according to self-organizing models, if raised in a non-Euclidean hyperbolic cage rats should be able to form hyperbolic grids. For a given range of grid spacing relative to the radius of negative curvature of the hyperbolic surface, such grids are predicted to appear as multi-peaked firing maps, in which each peak has seven neighbours instead of the Euclidean six, a prediction that can be tested in experiments. We thus demonstrate that a useful universal neuronal metric, in the sense of a multi-scale ruler and compass that remain unaltered when changing environments, can be extended to other than the standard Euclidean plane.
Keywords
Cite
@article{arxiv.1502.02435,
title = {Can rodents conceive hyperbolic spaces?},
author = {Eugenio Urdapilleta and Francesca Troiani and Federico Stella and Alessandro Treves},
journal= {arXiv preprint arXiv:1502.02435},
year = {2015}
}
Comments
Preprint accepted for publication in J. Royal Soc. Interface, with minor changes