Time of day is associated with paradoxical reductions in global signal fluctuation and functional connectivity.

Csaba Orban,Jingwei Li,Michael W L Chee,B T Thomas Yeo,Ru Kong,Ben Seymour

doi:10.1371/journal.pbio.3000602

Csaba Orban, Jingwei Li + Show 4 more

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https://doi.org/10.1371/journal.pbio.3000602

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Abstract

The brain exhibits substantial diurnal variation in physiology and function, but neuroscience studies rarely report or consider the effects of time of day. Here, we examined variation in resting-state functional MRI (fMRI) in around 900 individuals scanned between 8 AM and 10 PM on two different days. Multiple studies across animals and humans have demonstrated that the brain's global signal (GS) amplitude (henceforth referred to as "fluctuation") increases with decreased arousal. Thus, in accord with known circadian variation in arousal, we hypothesised that GS fluctuation would be lowest in the morning, increase in the midafternoon, and dip in the early evening. Instead, we observed a cumulative decrease in GS fluctuation as the day progressed. Although respiratory variation also decreased with time of day, control analyses suggested that this did not account for the reduction in GS fluctuation. Finally, time of day was associated with marked decreases in resting-state functional connectivity across the whole brain. The magnitude of decrease was significantly stronger than associations between functional connectivity and behaviour (e.g., fluid intelligence). These findings reveal time of day effects on global brain activity that are not easily explained by expected arousal state or physiological artefacts. We conclude by discussing potential mechanisms for the observed diurnal variation in resting brain activity and the importance of accounting for time of day in future studies.

Highlights

Circadian rhythms govern diverse aspects of physiology, including sleep/wake cycles [1], cognition [2], gene expression [3], temperature regulation [4], and endocrine signalling [5]
Since we identified a robust association between time of day and global signal (GS) fluctuation, we hypothesised that GS regression (GSR) might diminish time of day effects on regional blood oxygen level–dependent (BOLD) signal fluctuation and resting-state functional connectivity (RSFC)
We examined the impact of time of day on various measures of resting-state brain activity in over 900 participants from the Human Connectome Project (HCP) dataset, scanned between 8 AM and 10 PM on two sessions

Summary

Introduction

Circadian rhythms govern diverse aspects of physiology, including sleep/wake cycles [1], cognition [2], gene expression [3], temperature regulation [4], and endocrine signalling [5]. Studies of brain function in both humans and animals have documented time of day–. Time of day is associated with paradoxical reduction in global signal fluctuation. The list of participants who passed our visual quality screening of their pulse and respiratory data can be found at the GitHub repository maintained by the Computational Brain Imaging Group at https://github.com/ThomasYeoLab/CBIG/tree/ master/stable_projects/preprocessing/Orban2020_ tod

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