The effect of fatigue on first stance phase kinetics during acceleration sprint running in professional football players.

Nineteen professional football players (Age: 26±5 years; Height: 1.84±0.08 m; Mass: 83.4±8.9 kg) completed three x 30 m maximal acceleration sprints from a standing start before completing the Yo-Yo intermittent recovery test level 1. Three x 30 m maximal acceleration sprints were then repeated post-fatigue. Light gates recorded sprint times from 0-5 m, 0-10 m, 0-15 m and 0-30 m. Force platforms collected ground reaction force of the first stance phase of the sprint run. Differences between pre- and post-fatigue were observed in the sprint times over 0-15 m (P = 0.015; CI [0.007, 0.110]) and 0-30 m (P = 0.004; CI [0.056, 0.234]). Peak medial-lateral ground reaction force was lower (P = 0.045; CI [-0.146, -0.005]) post- than pre-fatigue. The ratio of force were significantly different between pre- and post-fatigue for the medial-lateral and anterior-posterior comparison (P = 0.017; CI [-0.063, -0.010]), and the medial-lateral and vertical comparison (P = 0.012; CI [-0.036, -0.007]). Football players altered their sprint mechanics to reduce medial-lateral loading and orient the force in an increased anteroposterior and vertical direction in order to maintain 0-10 m sprint performance. Practitioners should observe medial-lateral force contributions and improve sprint technical efficacy.

Acute Hormonal Response to Kettlebell Swing Exercise Differs Depending on Load, Even When Total Work Is Normalized.

ABSTRACT: Raymond, LM, Renshaw, D, and Duncan, MJ. Acute hormonal response to kettlebell swing exercise differs depending on load, even when total work is normalized. J Strength Cond Res 35(4): 997-1005, 2021-This study examined the acute hormonal response to kettlebell (KB) swing exercise using 2 loads, but when total work was equalized. Ten strength-trained males (25 ± 6 years) completed 2 KB swing trials, with an 8- and 16-kg KB, respectively, in a counterbalanced order. Each protocol lasted 12 minutes comprising 30-second KB swings followed by 30-second rest. Swing cadence was manipulated in each trial to ensure that total weight lifted was the same across conditions. Heart rate (HR) and ratings of perceived exertion (RPE), using the Borg RPE scale 6-20, were taken at the end of each 30-second exercise period. Saliva samples (min 0.5 ml) were taken 15 minutes before, immediately after, and 15 and 30 minutes after each condition from which cortisol (C) and testosterone (T) were determined. Results indicated a significant main effect for load for C (p = 0.007) and T (p = 0.05) where higher values for both C and T were evident for the 16-kg load. There was also a significant main effect for time for T (p = 0.001), where T values were all significantly higher post-exercise compared with pre-exercise. For HR, there were significant main effects for load (p = 0.004) and time (p = 0.001) with higher HR seen in 16-kg load and significant increases in HR evident with increasing repetition, irrespective of condition (all p < 0.05). Rating of perceived exertion values increased with repetition for the 8-kg and 16-kg loads, but the increase was more marked for the 16-kg load compared with the 8-kg load (p = 0.002). The present findings suggest that KB swing exercise produces an acute increase in hormones involved in muscle adaptation, but that KB load influences this response, even when total work completed is the same.