Facing Successfully High Mental Workload and Stressors: An FMRI Study

Overview

Journal Hum Brain Mapp

Publisher Wiley

Specialty Neurology

Date 2021 Nov 5

PMID 34738280

Citations 8

Authors

Mickael Causse

Evelyne Lepron

Kevin Mandrick

Vsevolod Peysakhovich

Isabelle Berry

Daniel Callan

Florence Remy

Affiliations

Soon will be listed here.

Abstract

The present fMRI study aimed at highlighting patterns of brain activations and autonomic activity when confronted with high mental workload and the threat of auditory stressors. Twenty participants performed a complex cognitive task in either safe or aversive conditions. Our results showed that increased mental workload induced recruitment of the lateral frontoparietal executive control network (ECN), along with disengagement of medial prefrontal and posterior cingulate regions of the default mode network (DMN). Mental workload also elicited an increase in heart rate and pupil diameter. Task performance did not decrease under the threat of stressors, most likely due to efficient inhibition of auditory regions, as reflected by a large decrement of activity in the superior temporal gyri. The threat of stressors was also accompanied with deactivations of limbic regions of the salience network (SN), possibly reflecting emotional regulation mechanisms through control from dorsal medial prefrontal and parietal regions, as indicated by functional connectivity analyses. Meanwhile, the threat of stressors induced enhanced ECN activity, likely for improved attentional and cognitive processes toward the task, as suggested by increased lateral prefrontal and parietal activations. These fMRI results suggest that measuring the balance between ECN, SN, and DMN recruitment could be used for objective mental state assessment. In this sense, an extra recruitment of task-related regions and a high ratio of lateral versus medial prefrontal activity may represent a relevant marker of increased but efficient mental effort, while the opposite may indicate a disengagement from the task due to mental overload and/or stressors.

Citing Articles

Short-term microgravity effects simulation does not affect fNIRS measures of cerebral oxygenation changes induced by cognitive load.

Peysakhovich V, Kiehl T, Martinez L, Boyer L, Causse M, Paillet A Front Physiol. 2025; 16:1425302.

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Effects of startle on cognitive performance and physiological activity revealed by fNIRS and thermal imaging.

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Heart rate dynamics for cognitive load estimation in a driving simulation task.

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Attenuated processing of task-irrelevant speech and other auditory stimuli: fMRI evidence from arithmetic tasks.

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