Abstract
PurposeThe human neuro-motor system can select different intermuscular coordination patterns to complete any given task, such as pedalling a bicycle. This study assessed whether intermuscular coordination patterns are used consistently across visit days and cadence conditions in recreationally active individuals.MethodsSeven participants completed a cycling exercise protocol across 2 days, consisting of pedalling at 150 Watts at cadences of 60, 80 and 100 rpm. Whilst cycling, surface electromyography was continuously recorded from ten leg muscles. For each participant, muscle coordination patterns were established using principal component (PC) analysis and the amount that each pattern was used was quantified by the PC loading scores. A sample entropy derived measure of the persistence of the loading scores across consecutive pedal cycles, entropic half-life (EnHL), was calculated. The median loading scores and EnHLs of the first three PCs were then compared across cadence conditions and visit days.ResultsNo significant differences were found in the median loading scores across cadence conditions or visits, nor were there any significant differences in the EnHLs across visits. However, the EnHLs were significantly longer when participants were cycling at 60 rpm compared to 100 rpm.ConclusionThese findings are based on a small sample size, but do suggest that, within individual participants, a consistent neuromuscular control strategy is used during cycling on different days. However, the underlying structure of muscle coordination is more persistent when pedalling at slower cadences with large differences between individuals.
Highlights
When humans pedal a bicycle, coordination of multiple lower limb muscles must occur to generate and apply the required reaction forces to the pedal
The rANOVA was used to compare the entropic half-life (EnHL) across principal component (PC) vectors to identify whether they needed to be considered independently
PC loading scores and EnHLs were considered dependent variables and cadence, visit day and participant were defined as independent variables
Summary
When humans pedal a bicycle, coordination of multiple lower limb muscles must occur to generate and apply the required reaction forces to the pedal. The amount that each muscle is recruited can vary across consecutive pedal cycles. This may reflect motor redundancy, the suggestion that the body accommodates more muscles than mechanical degrees. There are a number of solutions available to the nervous system to solve a given motor task (Muller and Sternad 2009), providing humans with the adaptability to meet task-specific requirements and optimise performance. Through analysing the peaks of sEMG waveforms, the contribution of individual muscles to the pedal cycle has been characterised (Houtz and Fischer 1959)
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