Top-down Attention and Alzheimer's Pathology Impact Cortical Selectivity During Learning, Influencing Episodic Memory in Older Adults

Overview

Journal bioRxiv

Date 2024 Dec 23

PMID 39713293

Authors

Jintao Sheng

Alexandra N Trelle

America Romero

Jennifer Park

Tammy T Tran

Sharon J Sha

Katrin I Andreasson

Edward N Wilson

Elizabeth C Mormino

Anthony D Wagner

Affiliations

Soon will be listed here.

Abstract

Human aging affects the ability to remember new experiences, in part, because of altered neural function during memory formation. One potential contributor to age-related memory decline is diminished neural selectivity -- i.e., a decline in the differential response of cortical regions to preferred vs. non-preferred stimuli during event perception -- yet the factors driving variability in neural selectivity with age remain unclear. We examined the impact of top-down attention and preclinical Alzheimer's disease (AD) pathology on neural selectivity during memory encoding in 156 cognitively unimpaired older participants who underwent fMRI while performing a word-face and word-scene associative memory task. Neural selectivity in face- and place-selective cortical regions was greater during events that were later remembered compared to forgotten. Critically, neural selectivity during learning positively scaled with memory-related variability in top-down attention, whereas selectivity negatively related to early AD pathology, evidenced by elevated plasma pTau. Path analysis revealed that neural selectivity at encoding mediated the effects of age, top-down attention, and pTau on associative memory. Collectively, these data reveal multiple pathways that contribute to memory differences among older adults -- AD-independent reductions in top-down attention and AD-related pathology alter the precision of cortical representations of events during experience, with consequences for remembering.

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