Performance and perceived fatigability across the intensity spectrum: role of muscle mass during cycling.

The role of muscle mass in modulating performance and perceived fatigability across the entire intensity spectrum during cycling remains unexplored. We hypothesized that at task failure (T), muscle contractile function would decline more following single- (SL) versus double-leg (DL) cycling within severe and extreme intensities, but not moderate and heavy intensities. After DL and SL ramp-incremental tests, on separate days, 11 recreationally active males (V̇o: 49.5 ± 7.7 mL·kg·min) completed SL and DL cycling until T within each intensity domain. Power output for SL trials was set at 60% of the corresponding DL trial. Before and immediately after T, participants performed an isometric maximal voluntary contraction (MVC) coupled with one superimposed and three resting femoral nerve stimulations [100 Hz; 10 Hz; single twitch ()] to measure performance fatigability. Perceived fatigue, leg pain, dyspnea, and effort were collected during trials. T within each intensity domain was not different between SL and DL (all > 0.05). MVC declined more for SL versus DL following heavy- (-42 ± 16% vs. -30 ± 18%; = 0.011) and severe-intensity cycling (-41 ± 12% vs. -31 ± 15%; = 0.036). Similarly, peak force declined more for SL following heavy- (-31 ± 12% vs. -22 ± 10%; = 0.007) and severe-intensity cycling (-49 ± 13% vs. -40 ± 7%; = 0.048). Except for heavy intensity, voluntary activation reductions were similar between modes. Similarly, except for dyspnea, which was lower for SL versus DL across all domains, ratings of fatigue, pain, and effort were similar at T between exercise modes. Thus, the amount of muscle mass modulates the extent of contractile function impairment in an intensity-dependent manner. We investigated the modulatory role of muscle mass on performance and perceived fatigability across the entire intensity spectrum. Despite similar time-to-task failure, single-leg cycling resulted in greater impairments in muscle contractile function within the heavy- and severe-intensity domains, but not the moderate- and extreme-intensity domains. Perceived fatigue, pain, and effort were similar between cycling modes. This indicates that the modulatory role of muscle mass on the extent of performance fatigability is intensity domain-dependent.