UBC‐Nepal expedition: acclimatization to high‐altitude increases spinal motoneurone excitability during fatigue in humans

Abstract: The fatigue-induced failure of the motor cortex to drive muscles maximally increases in acute hypoxia (AH) compared to normoxia (N) but improves with acclimatization (chronic hypoxia; CH). Despite their importance to muscle output, it is unknown how locomotor motoneurones in humans are affected by hypoxia and acclimatization. Eleven participants performed 16 min of submaximal [25% maximal torque (maximal voluntary contraction, MVC)] intermittent isometric elbow flexions in N, AH (environmental chamber) and CH … Show more

“…Consistent with greater peripheral fatigue, the rise in EMG over the 16 min fatigue protocol was greatest in acute hypoxia (+58%), compared to normoxia (+22%) and chronic hypoxia (+11%) (see Table 2 of Ruggiero et al . ). The recruitment of more motor units (or increased firing rates) during the fatiguing contractions in acute hypoxia than in chronic hypoxia means that motoneurone activity was not well matched between conditions.…”

“…() compared the fatigue‐related declines in CMEPs of two sizes (15% and 50% of maximal M‐wave; elicited during a TMS‐induced silent period as in Ruggiero et al . ()) during a sustained submaximal contraction of 20% maximal EMG. The smaller CMEP declined more than the larger.…”

“…However, we urge caution with regard to the interpretation by Ruggiero et al . () given the differences in fatigue and associated differences in motoneurone activity across the experimental conditions. An experimental approach that would reduce the differences in motoneurone activity between conditions would be to perform contractions to only an EMG target instead of a force target.…”

Differences in muscle performance during fatigue may explain the differences in motoneurone excitability between acute and chronic hypoxia

“…Consistent with greater peripheral fatigue, the rise in EMG over the 16 min fatigue protocol was greatest in acute hypoxia (+58%), compared to normoxia (+22%) and chronic hypoxia (+11%) (see Table 2 of Ruggiero et al . ). The recruitment of more motor units (or increased firing rates) during the fatiguing contractions in acute hypoxia than in chronic hypoxia means that motoneurone activity was not well matched between conditions.…”

“…() compared the fatigue‐related declines in CMEPs of two sizes (15% and 50% of maximal M‐wave; elicited during a TMS‐induced silent period as in Ruggiero et al . ()) during a sustained submaximal contraction of 20% maximal EMG. The smaller CMEP declined more than the larger.…”

“…However, we urge caution with regard to the interpretation by Ruggiero et al . () given the differences in fatigue and associated differences in motoneurone activity across the experimental conditions. An experimental approach that would reduce the differences in motoneurone activity between conditions would be to perform contractions to only an EMG target instead of a force target.…”

Differences in muscle performance during fatigue may explain the differences in motoneurone excitability between acute and chronic hypoxia

“…5 A of Ruggiero et al . ), M max size increases with fatigue in N and AH but decreases in CH. To compensate for this reduction in peripheral excitability, greater descending drive would be required in CH compared to N and AH to achieve a targeted level of iEMG.…”

“…5 B of Ruggiero et al . ). Just prior to this time point, the absolute increase in integrated EMG (iEMG) during a matched torque contraction is 13% for AH, 5% for N, and 4% for CH.…”

Reply from Luca Ruggiero, Alexandra F. Yacyshyn, Jane Nettleton and Chris J. McNeil

Altitude-induced effects on neuromuscular, metabolic and perceptual responses before, during and after a high-intensity resistance training session