Hippocampal Ensembles Represent Sequential Relationships Among an Extended Sequence of Nonspatial Events

Overview

Journal Nat Commun

Specialty Biology

Date 2022 Feb 9

PMID 35136052

Authors

Babak Shahbaba

Lingge Li

Forest Agostinelli

Mansi Saraf

Keiland W Cooper

Derenik Haghverdian

Gabriel A Elias

Pierre Baldi

Norbert J Fortin

Affiliations

Soon will be listed here.

Abstract

The hippocampus is critical to the temporal organization of our experiences. Although this fundamental capacity is conserved across modalities and species, its underlying neuronal mechanisms remain unclear. Here we recorded hippocampal activity as rats remembered an extended sequence of nonspatial events unfolding over several seconds, as in daily life episodes in humans. We then developed statistical machine learning methods to analyze the ensemble activity and discovered forms of sequential organization and coding important for order memory judgments. Specifically, we found that hippocampal ensembles provide significant temporal coding throughout nonspatial event sequences, differentiate distinct types of task-critical information sequentially within events, and exhibit theta-associated reactivation of the sequential relationships among events. We also demonstrate that nonspatial event representations are sequentially organized within individual theta cycles and precess across successive cycles. These findings suggest a fundamental function of the hippocampal network is to encode, preserve, and predict the sequential order of experiences.

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