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Predicting Working Memory Capacity Based on Glutamatergic Concentration and its Modulation of Functional Connectivity
Journal article   Peer reviewed

Predicting Working Memory Capacity Based on Glutamatergic Concentration and its Modulation of Functional Connectivity

George Zacharopoulos and Roi Cohen Kadosh
Neuroscience, Vol.457, pp.12-19
01/03/2021
PMID: 33212221

Abstract

Brain Mapping Magnetic Resonance Spectroscopy Memory, Short-Term Parietal Lobe - diagnostic imaging Prefrontal Cortex Magnetic Resonance Imaging
Working memory (WM) capacity, the amount of information one can hold online in mind, has a central role in cognition. Previous electrophysiological and imaging studies revealed the pivotal role of persistent activity within parietal and frontal regions as the neural foundations underpinning WM capacity. The best candidate molecules determining persistent activity are the brain's major excitatory and inhibitory neurotransmitters, glutamate and gamma-aminobutyric acid (GABA), respectively. However, our knowledge of these neurophysiological determinants in forming WM capacity is still poor. Using magnetic resonance spectroscopy (MRS), we examined the contribution of glutamate and GABA within the left intraparietal sulcus (IPS) and the left inferior/middle frontal gyrus (FG) in tracking WM capacity. A positive association was found between glutamate within the left IPS and WM capacity. By utilising resting-state functional MRI, we identified a negative association between parieto-cingulate connectivity and WM capacity. Individual variation in parieto-cingulate connectivity was explained by glutamatergic concentration in the IPS. Moreover, we found that parieto-cingulate connectivity mediated the relationship between interparietal sulcus glutamate and WM capacity. This set of findings reveals a novel mechanistic insight by which glutamatergic concentration within the IPS shapes WM capacity via parieto-cingulate connectivity.

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