# Continuous Bump Attractor Networks Require Explicit Error Coding for Gain Recalibration

**Authors:** Gorkem Secer, James J. Knierim, Noah J. Cowan

PMC · DOI: 10.21203/rs.3.rs-4209280/v1 · 2024-04-15

## TL;DR

This paper shows that continuous bump attractor networks need explicit error coding to recalibrate their integration gain for accurate continuous variable representation.

## Contribution

The paper introduces a modified ring attractor model with error-rate coding and Hebbian plasticity to achieve gain recalibration in continuous bump attractor networks.

## Key findings

- Gain recalibration in CBANs requires an explicit error signal encoded via a rate code.
- Combining error-rate coding with Hebbian plasticity enables accurate integration gain recalibration.
- Existing CBAN models lack mechanisms for gain recalibration, which this study addresses.

## Abstract

Representations of continuous variables are crucial to create internal models of the external world. A prevailing model of how the brain maintains these representations is given by continuous bump attractor networks (CBANs) in a broad range of brain functions across different areas, such as spatial navigation in hippocampal/entorhinal circuits and working memory in prefrontal cortex. Through recurrent connections, a CBAN maintains a persistent activity bump, whose peak location can vary along a neural space, corresponding to different values of a continuous variable. To track the value of a continuous variable changing over time, a CBAN updates the location of its activity bump based on inputs that encode the changes in the continuous variable (e.g., movement velocity in the case of spatial navigation)—a process akin to mathematical integration. This integration process is not perfect and accumulates error over time. For error correction, CBANs can use additional inputs providing ground-truth information about the continuous variable’s correct value (e.g., visual landmarks for spatial navigation). These inputs enable the network dynamics to automatically correct any representation error. Recent experimental work on hippocampal place cells has shown that, beyond correcting errors, ground-truth inputs also fine-tune the gain of the integration process, a crucial factor that links the change in the continuous variable to the updating of the activity bump’s location. However, existing CBAN models lack this plasticity, offering no insights into the neural mechanisms and representations involved in the recalibration of the integration gain. In this paper, we explore this gap by using a ring attractor network, a specific type of CBAN, to model the experimental conditions that demonstrated gain recalibration in hippocampal place cells. Our analysis reveals the necessary conditions for neural mechanisms behind gain recalibration within a CBAN. Unlike error correction, which occurs through network dynamics based on ground-truth inputs, gain recalibration requires an additional neural signal that explicitly encodes the error in the network’s representation via a rate code. Finally, we propose a modified ring attractor network as an example CBAN model that verifies our theoretical findings. Combining an error-rate code with Hebbian synaptic plasticity, this model achieves recalibration of integration gain in a CBAN, ensuring accurate representation for continuous variables.

## Full-text entities

- **Diseases:** PI (MESH:D000081042)
- **Chemicals:** calcium (MESH:D002118), Dopamine (MESH:D004298), PI (-)
- **Species:** Drosophila melanogaster (fruit fly, species) [taxon 7227], Homo sapiens (human, species) [taxon 9606], Rattus norvegicus (brown rat, species) [taxon 10116]

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11065082/full.md

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Source: https://tomesphere.com/paper/PMC11065082