Different strategies to compensate for the effects of fatigue revealed by neuromuscular adaptation processes in humans
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Cited by (105)
Inter-joint coordination variability during a sit-to-stand fatiguing protocol
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2018, Journal of Electromyography and KinesiologyTowards a Grand Unified Theory of sports performance
2017, Human Movement ScienceCitation Excerpt :Most empirical investigations examining the effects of fatigue on sports performance have typically reported that it leads to decreases in the magnitude, and increases in the variability, of various indices of control (e.g., force, amplitude, velocity, acceleration, power, range of motion, etc.), which, in turn, lead to reductions in the speed, accuracy, and consistency of performance outcomes (e.g., Apriantono, Nunome, Ikegami, & Sano, 2006; Davey, Thorpe, & Williams, 2002; Higham, Pyne, Anson, & Eddy, 2012; Kellis, Katis, & Vrabas, 2006; Murray, Cook, Werner, Schlegel, & Hawkins, 2001; Rampinini, Impellizzeri, Castagna, Coutts, & Wisløff, 2009; Rota, Morel, Saboul, Rogowski, & Hautier, 2014; Russell, Benton, & Kingsley, 2011). Fewer studies have considered how fatigue affects the organisation and interaction (i.e., the coordination) of DOF underlying movement control (e.g., Aune, Ingvaldsen, & Ettema, 2008; Bonnard et al., 1994; Dorel, Drouet, Couturier, Champoux, & Hug, 2009; Forestier & Nougier, 1998; Rodacki, Fowler, & Bennett, 2001; Trezise, Bartlett, & Bussey, 2011) and the vast majority of extant investigations have only considered changes in coordination at the intra-individual level of analysis. A common finding of many of these studies, however, is that, during prolonged sub-maximal physical activity, DOF at various levels of analysis are able to adjust their contribution to minimise the global impact of fatigue, thereby allowing the same level of intensity to be maintained for longer (see also Patla, 1987).
Lower limb mechanical asymmetry during repeated treadmill sprints
2017, Human Movement ScienceCitation Excerpt :Because vertical stiffness represents a composite and macroscopic measure of lower limb joint stiffness (i.e., joint stiffness of the hip, knee, and ankle; Butler, Crowell, & Davis, 2003), it cannot be ruled out that inter-joint coordinative changes may have differed between legs. With previous research observing inter-individual coordinative changes accompanying fatiguing exercise (Bonnard, Sirin, Oddsson, & Thorstensson, 1994), it is possible that this additional variability obscured mean changes across repetitions. This adaptability may minimize any fatigue-induced contralateral differences possibly due to changes in the level of muscle activation (Arampatzis, Schade, Walsh, & Brüggemann, 2001) and/or to adjustments in the geometry of the lower limbs (Farley, Houdijk, Van Strien, & Louie, 1998).