Multiple timescales of sensory-evidence accumulation across the dorsal cortex

• Published in: eLife Vol. 11
• Main Authors: Pinto, Lucas, Tank, David W, Brody, Carlos D
• Format: Journal Article
• Language: English
• Published: England eLife Science Publications, Ltd 16.06.2022; eLife Sciences Publications Ltd; eLife Sciences Publications, Ltd
• Subjects: Cognition & reasoning; Cognitive ability; Computer applications; Confidence intervals; cortex; Decision making; evidence accumulation; Integration; intrinsic timescales; Lasers; Neuroscience; optogenetics; Quantitative psychology; Somatosensory cortex; Temporal cortex; Virtual reality; cortex; mouse; virtual reality; evidence accumulation; decision-making; neuroscience; intrinsic timescales; optogenetics
• ISSN: 2050-084X; 2050-084X
• DOI: 10.7554/eLife.70263

Cortical areas seem to form a hierarchy of intrinsic timescales, but the relevance of this organization for cognitive behavior remains unknown. In particular, decisions requiring the gradual accrual of sensory evidence over time recruit widespread areas across this hierarchy. Here, we tested the hypothesis that this recruitment is related to the intrinsic integration timescales of these widespread areas. We trained mice to accumulate evidence over seconds while navigating in virtual reality and optogenetically silenced the activity of many cortical areas during different brief trial epochs. We found that the inactivation of all tested areas affected the evidence-accumulation computation. Specifically, we observed distinct changes in the weighting of sensory evidence occurring during and before silencing, such that frontal inactivations led to stronger deficits on long timescales than posterior cortical ones. Inactivation of a subset of frontal areas also led to moderate effects on behavioral processes beyond evidence accumulation. Moreover, large-scale cortical Ca activity during task performance displayed different temporal integration windows. Our findings suggest that the intrinsic timescale hierarchy of distributed cortical areas is an important component of evidence-accumulation mechanisms.