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The magnitude of neuromuscular fatigue is not intensity dependent when cycling above critical power but relates to aerobic and anaerobic capacities
Author(s) -
Schäfer Lisa U.,
Hayes Mark,
Dekerle Jeanne
Publication year - 2018
Publication title -
experimental physiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.925
H-Index - 101
eISSN - 1469-445X
pISSN - 0958-0670
DOI - 10.1113/ep087273
Subject(s) - anaerobic exercise , cycling , muscle fatigue , intensity (physics) , physical medicine and rehabilitation , cardiology , medicine , exercise physiology , exercise intensity , zoology , physical therapy , electromyography , physics , biology , heart rate , archaeology , quantum mechanics , blood pressure , history
New FindingsWhat is the central question of this study? Is the magnitude of neuromuscular fatigue dependent upon exercise intensity above critical power (CP) when W ′ (the curvature constant of the power–duration relationship) is depleted?What is the main finding and its importance? The magnitude of neuromuscular fatigue is the same after two bouts of supra‐CP cycling (3 versus 12 min) when controlling for W ′ depletion but is larger for individuals of greater anaerobic capacity after the shorter bout and smaller for individuals of greater aerobic capacity after the longer exercise bout. These findings provide new insight into the mechanisms underpinning exercise above CP.Abstract The aim of the present study was to test whether the development of neuromuscular fatigue within the severe‐intensity domain could be linked to the depletion of the curvature constant ( W ′) of the power–duration relationship. Twelve recreationally active men completed tests to determine peak oxygen consumption, critical power (CP) and W ′, followed by two randomly assigned constant‐load supra‐CP trials set to deplete W ′ fully in 3 (P‐3) and 12 min (P‐12). Pre‐ to postexercise changes in maximal voluntary contraction, potentiated quadriceps twitch force evoked by single ( Q pot ) and paired high‐ (PS100) and low‐frequency (PS10) stimulations and voluntary activation were determined. Cycling above CP reduced maximal voluntary contraction (P‐3, −20 ± 10% versus P‐12, −15 ± 7%), measures associated with peripheral fatigue ( Q pot , −35 ± 13 versus −31 ± 14%; PS10, −38 ± 13 versus −37 ± 17%; PS100, −18 ± 9 versus −13 ± 8% for P‐3 and P‐12, respectively) and voluntary activation (P‐3, −12 ± 3% versus P‐12, −13 ± 3%; P < 0.05), with no significant difference between trials ( P > 0.05). Changes in maximal voluntary contraction and evoked twitch forces were inversely correlated with CP and peak oxygen consumption after P‐12, whereas W ′ was significantly correlated with changes in Q pot and PS10 after P‐3 ( P < 0.05). Therefore, the magnitude of neuromuscular fatigue does not depend on exercise intensity when W ′ is fully exhausted during severe‐intensity exercise; nonetheless, exploration of inter‐individual variations suggests that mechanisms underpinning exercise tolerance within this domain differ between short‐ and long‐duration exercise.