Exercise-induced changes in high-γ cortical functional connectivity and short-interval intracortical inhibition
Matteo Conti, Federico Carparelli, Roberta Bovenzi, Valerio Ferrari, Battista Di Gioia, Nicola Biagio Mercuri, Alessandro Stefani, Maria Giuseppina Palmieri
Highlights
• Central fatigue is more challenging to study than the peripheral one, requiring more neurophysiological techniques.
• Ten healthy volunteers underwent HD-EEG and pp-TMS before and 24–72 h after a 3 km high-intensity run.
• After 24 h, a significant hyperconnectivity in the high-γ band and a consistent hyperexcitability in left M1 were observed.
Objective
To analyze exercise-induced changes in functional connectivity (FC) using high-density EEG (HD-EEG) and primary motor cortex excitability via paired-pulse TMS (pp-TMS).
Methods
Ten healthy volunteers performed a 3 km high-intensity run. Neurophysiological assessments were conducted at baseline (T0), 24 h (T1), and 72 h (T2) post-exercise. FC was measured using HD-EEG, and primary motor cortex excitability was assessed with pp-TMS to measure short-interval intracortical inhibition (SICI) and facilitation (ICF).
Results
At T1, a significant hyperconnected network in the high-γ band was observed in several brain regions, including sensorimotor, limbic, temporal, and occipital lobes, which normalized by T2. Additionally, pp-TMS revealed disinhibition (reduced SICI) in M1 at ISI 2–3 ms at T1.
Conclusions
The study highlighted specific features of exercise-induced central fatigue. Post-exercise, the primary motor cortex became hyperexcitable, possibly as a compensatory response to peripheral fatigue. A complex network of cortical areas involved in cognition and behavior was hyperactivated, likely reflecting awareness of fatigue and self-protection decision-making processes. These changes were reversible, allowing subjects to return to baseline conditions.
Significance
This research provides insight into the neurophysiological mechanisms of central fatigue, emphasizing the brain’s adaptive responses to intense physical activity and their temporal dynamics.
Link (Clinical Neurophysiology) [Paywall]
Matteo Conti, Federico Carparelli, Roberta Bovenzi, Valerio Ferrari, Battista Di Gioia, Nicola Biagio Mercuri, Alessandro Stefani, Maria Giuseppina Palmieri
Highlights
• Central fatigue is more challenging to study than the peripheral one, requiring more neurophysiological techniques.
• Ten healthy volunteers underwent HD-EEG and pp-TMS before and 24–72 h after a 3 km high-intensity run.
• After 24 h, a significant hyperconnectivity in the high-γ band and a consistent hyperexcitability in left M1 were observed.
Objective
To analyze exercise-induced changes in functional connectivity (FC) using high-density EEG (HD-EEG) and primary motor cortex excitability via paired-pulse TMS (pp-TMS).
Methods
Ten healthy volunteers performed a 3 km high-intensity run. Neurophysiological assessments were conducted at baseline (T0), 24 h (T1), and 72 h (T2) post-exercise. FC was measured using HD-EEG, and primary motor cortex excitability was assessed with pp-TMS to measure short-interval intracortical inhibition (SICI) and facilitation (ICF).
Results
At T1, a significant hyperconnected network in the high-γ band was observed in several brain regions, including sensorimotor, limbic, temporal, and occipital lobes, which normalized by T2. Additionally, pp-TMS revealed disinhibition (reduced SICI) in M1 at ISI 2–3 ms at T1.
Conclusions
The study highlighted specific features of exercise-induced central fatigue. Post-exercise, the primary motor cortex became hyperexcitable, possibly as a compensatory response to peripheral fatigue. A complex network of cortical areas involved in cognition and behavior was hyperactivated, likely reflecting awareness of fatigue and self-protection decision-making processes. These changes were reversible, allowing subjects to return to baseline conditions.
Significance
This research provides insight into the neurophysiological mechanisms of central fatigue, emphasizing the brain’s adaptive responses to intense physical activity and their temporal dynamics.
Link (Clinical Neurophysiology) [Paywall]
