Litcius/Paper detail

Exploring intensity-dependent modulations in EEG resting-state network efficiency induced by exercise

Daniel Büchel, Øyvind Sandbakk, Jochen Baumeister

2021European Journal of Applied Physiology23 citationsDOIOpen Access PDF

Abstract

Abstract Purpose Exhaustive cardiovascular load can affect neural processing and is associated with decreases in sensorimotor performance. The purpose of this study was to explore intensity-dependent modulations in brain network efficiency in response to treadmill running assessed from resting-state electroencephalography (EEG) measures. Methods Sixteen trained participants were tested for individual peak oxygen uptake (VO 2 peak ) and performed an incremental treadmill exercise at 50% (10 min), 70% (10 min) and 90% speed VO 2 peak (all-out) followed by cool-down running and active recovery. Before the experiment and after each stage, borg scale (BS), blood lactate concentration (B La ), resting heartrate (HR rest ) and 64-channel EEG resting state were assessed. To analyze network efficiency, graph theory was applied to derive small world index (SWI) from EEG data in theta, alpha-1 and alpha-2 frequency bands. Results Analysis of variance for repeated measures revealed significant main effects for intensity on BS, B La , HR rest and SWI. While BS, B La and HR rest indicated maxima after all-out, SWI showed a reduction in the theta network after all-out. Conclusion Our explorative approach suggests intensity-dependent modulations of resting-state brain networks, since exhaustive exercise temporarily reduces brain network efficiency. Resting-state network assessment may prospectively play a role in training monitoring by displaying the readiness and efficiency of the central nervous system in different training situations.

Topics & Concepts

Resting state fMRIElectroencephalographyTreadmillIntensity (physics)Physical medicine and rehabilitationExercise intensityBrain activity and meditationPsychologyCardiologyAudiologyPhysical therapyHeart rateNeuroscienceMedicineInternal medicinePhysicsBlood pressureQuantum mechanicsFunctional Brain Connectivity StudiesEEG and Brain-Computer InterfacesNeural dynamics and brain function