Development of non-spatial grid-like neural codes tracks inference and intelligence
Summary
Piaget's theory posits that children develop structured knowledge schemas for inferring and assimilating new information, yet the underlying neural mechanisms remain unclear. In 203 participants aged 8-25 years, we investigated how maturation of a two-dimensional (2D) knowledge map underpins inferential reasoning and knowledge assimilation. Grid-cell-like codes in the entorhinal cortex (EC) strengthened with age, reflecting schema representations in non-spatial conceptual spaces, and predi
Content
# Development of non-spatial grid-like neural codes tracks inference and intelligence
*Published: 2026 May 14*
Piaget's theory posits that children develop structured knowledge schemas for
inferring and assimilating new information, yet the underlying neural mechanisms
remain unclear. In 203 participants aged 8-25 years, we investigated how
maturation of a two-dimensional (2D) knowledge map underpins inferential
reasoning and knowledge assimilation. Grid-cell-like codes in the entorhinal
cortex (EC) strengthened with age, reflecting schema representations in
non-spatial conceptual spaces, and predicted improved inferential reasoning.
These grid-like codes also supported the medial prefrontal cortex (mPFC) in
encoding distance relationships between objects on the 2D map. As participants
assimilated new information, they integrated it into existing grid patterns in
the EC. Moreover, the maturation of these neural codes tracked real-world
intelligence measures, particularly reasoning abilities. Our findings
demonstrate that the development of non-spatial grid-like neural codes offers a
mechanistic account of cognitive development, bridging psychological theory with
a fundamental cellular representation of the cognitive map.
DOI: 10.1016/j.cell.2026.02.028