Go to NeurIPS 2025 Conference homepageREMI: Reconstructing Episodic Memory During Internally Driven Path Planning
Keywords: grid cells; place cells; hippocampus; medial entorhinal cortex; spatial navigation and planning
TL;DR: We propose REMI, a unified, system-level theory for cue-triggered goal retrieval, path planning, and reconstruction of sensory experience along a planned route using grid cells, place cells, and sensory cells.
Abstract: Grid cells in the medial entorhinal cortex (MEC) and place cells in the hippocampus (HC) both form spatial representations. Grid cells fire in triangular grid patterns, while place cells fire at specific locations and respond to contextual cues. How do these interacting systems support not only spatial encoding but also internally driven path planning, such as navigating to locations recalled from cues? Here, we propose a system-level theory of MEC-HC wiring that explains how grid and place cell patterns could be connected to enable cue-triggered goal retrieval, path planning, and reconstruction of sensory experience along planned routes. We suggest that place cells autoassociate sensory inputs with grid cell patterns, allowing sensory cues to trigger recall of goal-location grid patterns. We show analytically that grid-based planning permits shortcuts through unvisited locations and generalizes local transitions to long-range paths. During planning, intermediate grid states trigger place cell pattern completion, reconstructing sensory experiences along the route. Using a single-layer RNN modeling the HC-MEC loop with a planning subnetwork, we demonstrate these effects in both biologically grounded navigation simulations using RatatouGym and visually realistic navigation tasks using Habitat Sim.
Primary Area: Neuroscience and cognitive science (e.g., neural coding, brain-computer interfaces)
Submission Number: 17765
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