Abstract
Hippocampal cognitive maps encode the relative locations of spatial cues in an environment and adapt their representation when boundaries geometrically change. Hippocampal cognitive maps can represent abstract knowledge, yet it’s unclear whether the hippocampus is sensitive to changes to the extreme coordinates, boundaries, of abstract spaces. We created a memory-guided choice task to test whether the human hippocampus and medial prefrontal cortex(mPFC) flexibly learn abstract boundary representations in distinct two-dimensional(2D) knowledge spaces. Participants built up a 2D map-like representation of abstract boundaries, where the hippocampus and mPFC represented a decision cue’s Euclidean distance to the closest boundary. Notably, mPFC distance representations selectively reflected individual performance improvements during the task. Testing for neural sensitivity to boundary-defined contextual changes, only the hippocampus flexibly represented abstract boundaries, which related to choice behavior. These findings suggest that abstract knowledge retrieval within dynamically changing contexts is facilitated by generalized mPFC and flexible hippocampal boundary representations.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
Abstract, Results, and Figure 1 updated