Subspace partitioning in the human prefrontal cortex resolves cognitive interference.
Jan WeberGabriela IwamaAnne-Kristin SolbakkAlejandro Omar BlenkmannPål Gunnar LarssonJugoslav IvanovicRobert T KnightTor EndestadRandolph HelfrichPublished in: Proceedings of the National Academy of Sciences of the United States of America (2023)
The human prefrontal cortex (PFC) constitutes the structural basis underlying flexible cognitive control, where mixed-selective neural populations encode multiple task features to guide subsequent behavior. The mechanisms by which the brain simultaneously encodes multiple task-relevant variables while minimizing interference from task-irrelevant features remain unknown. Leveraging intracranial recordings from the human PFC, we first demonstrate that competition between coexisting representations of past and present task variables incurs a behavioral switch cost. Our results reveal that this interference between past and present states in the PFC is resolved through coding partitioning into distinct low-dimensional neural states; thereby strongly attenuating behavioral switch costs. In sum, these findings uncover a fundamental coding mechanism that constitutes a central building block of flexible cognitive control.