A novel rat spatial transitive inference paradigm for investigating memory schema and deliberation

Inferential reasoning is a vital cognitive ability that enables animals to navigate novel situations by leveraging existing relational knowledge of memory schema. Transitive inference (TI), a classic paradigm for studying this process, tests the ability of subjects to infer relationships within a value hierarchy (e.g., A > B > C > D > E) after being trained only on adjacent pairs (e.g., A-B, B-C). While the ability to perform transitive inference is well-conserved across species, the neural mechanisms supporting it, particularly the role of the hippocampal-prefrontal circuit, remain underexplored due to limitations in existing rodent TI paradigms. These paradigms often rely on manual trial setups with pot-digging choice behavior using odors that makes it difficult to pinpoint the moment of inferential deliberation. To address these challenges, we developed a novel automated spatial TI task for rats using a radial maze, which leverages their natural foraging behaviors and includes a dedicated deliberation zone. We found that most rats successfully learned the premise pairs and successfully inferred, with performance comparable to studies using traditional odor-based tasks. We also investigated vicarious trial and error (VTE), a behavioral correlate of deliberation during choice trajectories. We found that VTE behavior was elevated during the initial stages of learning with access to new maze arms, when the first novel premise pair was introduced, and for incorrect trials, corresponding to hypothesized association of VTE events with uncertainty. Further, rats also had elevated VTE behavior on inference testing day for the inference test pair (B-D) compared to the other inner premise pairs (B-C & C-D) on their first testing day, suggesting the need to deliberate during inferential reasoning. Thus, VTEs may reflect deliberation in addition to uncertainty. Our findings demonstrate the feasibility of a spatial TI task that is well-suited for neurophysiological investigation and provides new insights into the behavioral correlates of inferential reasoning and deliberation.