University of Illinois Chicago
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Environmental deformations dynamically shift the grid cell spatial metric

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journal contribution
posted on 2023-04-20, 19:38 authored by Alexandra T Keinath, Russell A Epstein, Vijay Balasubramanian
In familiar environments, the firing fields of entorhinal grid cells form regular triangular lattices. However, when the geometric shape of the environment is deformed, these time-averaged grid patterns are distorted in a grid scale-dependent and local manner. We hypothesized that this distortion in part reflects dynamic anchoring of the grid code to displaced boundaries, possibly through border cell-grid cell interactions. To test this hypothesis, we first reanalyzed two existing rodent grid rescaling datasets to identify previously unrecognized boundary-tethered shifts in grid phase that contribute to the appearance of rescaling. We then demonstrated in a computational model that boundary-tethered phase shifts, as well as scale-dependent and local distortions of the time-averaged grid pattern, could emerge from border-grid interactions without altering inherent grid scale. Together, these results demonstrate that environmental deformations induce history-dependent shifts in grid phase, and implicate border-grid interactions as a potential mechanism underlying these dynamics.

History

Citation

Keinath, A. T., Epstein, R. A.Balasubramanian, V. (2018). Environmental deformations dynamically shift the grid cell spatial metric. eLife, 7, e38169-. https://doi.org/10.7554/elife.38169

Publisher

eLife Sciences Publications

Language

  • en

issn

2050-084X