Integrating Random Memory Patterns and Spatial Maps in Food-Caching Birds

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• Speaker to be confirmed
• Tuesday 11 March 2025, 15:00-16:30
• CBL Seminar Room, Engineering Department, 4th floor Baker building.

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A major challenge in neuroscience is understanding how the hippocampus encodes numerous episodic memories without interference while maintaining spatial representations. While theoretical considerations favour random, uncorrelated patterns for episodic memory storage, most experimental studies focus on spatial memory that is highly structured. In this journal club, we will explore recent work in chickadees, a species that relies on precise memory for food caching, to investigate how hippocampal circuits integrate random patterns with structured spatial codes. The first study [1] demonstrates that place cells not only encode an animal’s location but also respond when the bird gazes at distant locations, suggesting a unified hippocampal representation of attended space. The second study [2] identifies sparse, high-dimensional ‘barcode’ patterns that uniquely label individual caching events, coexisting with conventional place cell activity but remaining mostly uncorrelated to spatial proximity. The third study [3] presents a computational model in which chaotic recurrent network dynamics generate barcodes that serve as memory indices while maintaining a structured code for spatial memory. Together, these findings bridge theoretical ideas of hippocampal indexing with empirical data, offering a new perspective on how the brain simultaneously supports spatial navigation and episodic memory storage. [1] Payne, H. L., & Aronov, D. (2024). Remote activation of place codes by gaze in a highly visual animal. bioRxiv, 2024-09. [2] Chettih, S. N., Mackevicius, E. L., Hale, S., & Aronov, D. (2024). Barcoding of episodic memories in the hippocampus of a food-caching bird. Cell, 187(8), 1922-1935. [3] Fang, C., Lindsey, J., Abbott, L. F., Aronov, D., & Chettih, S. (2024). Barcode activity in a recurrent network model of the hippocampus enables efficient memory binding. bioRxiv.

This talk is part of the Computational Neuroscience series.

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