Simon Weber scite author profile

Neurons in the hippocampus and adjacent brain areas show a large diversity in their tuning to location and head direction, and the underlying circuit mechanisms are not yet resolved. In particular, it is unclear why certain cell types are selective to one spatial variable, but invariant to another. For example, place cells are typically invariant to head direction. We propose that all observed spatial tuning patterns – in both their selectivity and their invariance – arise from the same mechanism: Excitatory and inhibitory synaptic plasticity driven by the spatial tuning statistics of synaptic inputs. Using simulations and a mathematical analysis, we show that combined excitatory and inhibitory plasticity can lead to localized, grid-like or invariant activity. Combinations of different input statistics along different spatial dimensions reproduce all major spatial tuning patterns observed in rodents. Our proposed model is robust to changes in parameters, develops patterns on behavioral timescales and makes distinctive experimental predictions.

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26th Annual Computational Neuroscience Meeting (CNS*2017): Part 3

Newton¹,

Seidenstein²,

McDougal³

et al. 2017

BMC Neurosci

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Besta

Weber

Gianinazzi

et al. 2019

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An experimental study on optimum lubrication for large-scale severe plastic deformation of aluminum-based alloys

Frint

Wagner

Weber

et al. 2017

Journal of Materials Processing Technology

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A local measure of symmetry and orientation for individual spikes of grid cells

Weber

Sprekeler

2019

PLoS Comput Biol

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Grid cells have attracted broad attention because of their highly symmetric hexagonal firing patterns. Recently, research has shifted its focus from the global symmetry of grid cell activity to local distortions both in space and time, such as drifts in orientation, local defects of the hexagonal symmetry, and the decay and reappearance of grid patterns after changes in lighting condition. Here, we introduce a method that allows to visualize and quantify such local distortions, by assigning both a local grid score and a local orientation to each individual spike of a neuronal recording. The score is inspired by a standard measure from crystallography, which has been introduced to quantify local order in crystals. By averaging over spikes recorded within arbitrary regions or time periods, we can quantify local variations in symmetry and orientation of firing patterns in both space and time.

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Simon Weber

Learning place cells, grid cells and invariances with excitatory and inhibitory plasticity

26th Annual Computational Neuroscience Meeting (CNS*2017): Part 3

Slim graph

An experimental study on optimum lubrication for large-scale severe plastic deformation of aluminum-based alloys

A local measure of symmetry and orientation for individual spikes of grid cells

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