Sensorimotor Network Segregation Declines with Age and is Linked to GABA and to Sensorimotor Performance

Overview

Journal Neuroimage

Specialty Radiology

Date 2018 Nov 12

PMID 30414983

Citations 71

Authors

Kaitlin Cassady

Holly Gagnon

Poortata Lalwani

Molly Simmonite

Bradley Foerster

Denise Park

Scott J Peltier

Myria Petrou

Stephan F Taylor

Daniel H Weissman

Rachael D Seidler

Thad A Polk

Affiliations

Soon will be listed here.

Abstract

Aging is typically associated with declines in sensorimotor performance. Previous studies have linked some age-related behavioral declines to reductions in network segregation. For example, compared to young adults, older adults typically exhibit weaker functional connectivity within the same functional network but stronger functional connectivity between different networks. Based on previous animal studies, we hypothesized that such reductions of network segregation are linked to age-related reductions in the brain's major inhibitory transmitter, gamma aminobutyric acid (GABA). To investigate this hypothesis, we conducted graph theoretical analyses of resting state functional MRI data to measure sensorimotor network segregation in both young and old adults. We also used magnetic resonance spectroscopy to measure GABA levels in the sensorimotor cortex and collected a battery of sensorimotor behavioral measures. We report four main findings. First, relative to young adults, old adults exhibit both less segregated sensorimotor brain networks and reduced sensorimotor GABA levels. Second, less segregated networks are associated with lower GABA levels. Third, less segregated networks and lower GABA levels are associated with worse sensorimotor performance. Fourth, network segregation mediates the relationship between GABA and performance. These findings link age-related differences in network segregation to age-related differences in GABA levels and sensorimotor performance. More broadly, they suggest a neurochemical substrate of age-related dedifferentiation at the level of large-scale brain networks.

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