Predictive Representations in Hippocampal and Prefrontal Hierarchies.
Iva K BrunecIda MomennejadPublished in: The Journal of neuroscience : the official journal of the Society for Neuroscience (2021)
As we navigate the world, we use learned representations of relational structures to explore and to reach goals. Studies of how relational knowledge enables inference and planning are typically conducted in controlled small-scale settings. It remains unclear, however, how people use stored knowledge in continuously unfolding navigation, e.g., walking long distances in a city. We hypothesized that multiscale predictive representations guide naturalistic navigation in humans, and these scales are organized along posterior-anterior prefrontal and hippocampal hierarchies. We conducted model-based representational similarity analyses of neuroimaging data collected while male and female participants navigated realistically long paths in virtual reality. We tested the pattern similarity of each point-along each path-to a weighted sum of its successor points within predictive horizons of different scales. We found that anterior PFC showed the largest predictive horizons, posterior hippocampus the smallest, with the anterior hippocampus and orbitofrontal regions in between. Our findings offer novel insights into how cognitive maps support hierarchical planning at multiple scales.Significance StatementWhenever we navigate the world, we represent our journey at multiple horizons: from our immediate surroundings to our distal goal. How are such cognitive maps at different horizons simultaneously represented in the brain? Here, we applied a reinforcement learning-based analysis to neuroimaging data acquired while participants virtually navigated their hometown. We investigated neural patterns in the hippocampus and prefrontal cortex (PFC), key cognitive map regions. We uncovered predictive representations with multi-scale horizons in prefrontal and hippocampal gradients, with the longest predictive horizons in anterior PFC, and the shortest in posterior hippocampus. These findings provide empirical support for the computational hypothesis that multiscale neural representations guide goal-directed navigation. This advances our understanding of hierarchical planning in everyday navigation of realistic distances.
Keyphrases
- working memory
- prefrontal cortex
- cerebral ischemia
- healthcare
- functional connectivity
- virtual reality
- cognitive impairment
- subarachnoid hemorrhage
- electronic health record
- resting state
- transcranial magnetic stimulation
- magnetic resonance imaging
- minimally invasive
- single cell
- mass spectrometry
- computed tomography
- room temperature
- white matter
- machine learning
- contrast enhanced
- artificial intelligence
- atomic force microscopy