Abstract
This study explored the impact of two differing warm-up protocols (involving either resistance exercises or plyometric exercises) on running economy (RE) in healthy recreationally active participants. Twelve healthy university students [three males, nine females, age 20 ± 2 years, maximal oxygen uptake (38.4 ± 6.4 ml min–1 kg–1)] who performed less than 5 h per week of endurance exercise volunteered to participant in this study. All participants completed three different warm-up protocols (control, plyometric, and resistance warm-up) in a counterbalanced crossover design with trials separated by 48 h, using a Latin-square arrangement. Dependent variables measured in this study were RE at four running velocities (7, 8, 9, and 10 km h–1), maximal oxygen uptake; heart rate; respiratory exchange rate; expired ventilation; perceived race readiness; rating of perceived exertion, time to exhaustion and leg stiffness. The primary finding of this study was that the plyometric warm-up improved RE compared to the control warm-up (6.2% at 7 km h–1, ES = 0.355, 9.1% at 8 km h–1, ES = 0.513, 4.5% at 9 km h–1, ES = 0.346, and 4.4% at 10 km h–1, ES = 0.463). There was no statistically significant difference in VO2 between control and resistance warm-up conditions at any velocity. There were also no statistically significant differences between conditions in other metabolic and pulmonary gas exchange variables; time to exhaustion; perceived race readiness and maximal oxygen uptake. However, leg stiffness increased by 20% (P = 0.039, ES = 0.90) following the plyometric warm-up and was correlated with the improved RE at a velocity of 8 km h–1 (r = 0.475, P = 0.041). No significant differences in RE were found between the control and resistance warm-up protocols. In comparison with the control warm-up protocol, an acute plyometric warm-up protocol can improve RE in healthy adults.
Highlights
Distance running performance is determined by three major physiological variables; maximal oxygen uptake (VO2max); lactate threshold (LT) and running economy (RE) (Coyle, 1995)
At all velocities, VO2 was significantly lower following the plyometric warm-up protocol compared to the control condition: 30.08 ± 3.42 ml min−1 kg−1 to 27.33 ± 4.30 ml min−1 kg−1, [F(2,22) = 8.781, P = 0.006, ES = 0.513] (8 km h−1), 33.58 ± 3.61 ml min−1 kg−1 to 32.08 ± 2.61 ml min−1 kg−1, [F(2,22) = 4.287, P = 0.034, TABLE 2 | The effects of four running velocities on VO2 following the control, plyometric, and resistance warm-up protocols
This study investigated the influences of plyometric and resistance warm-up protocols on RE in healthy adults
Summary
Distance running performance is determined by three major physiological variables; VO2max; lactate threshold (LT) and running economy (RE) (Coyle, 1995). VO2max refers to the maximal volume of oxygen that the individual can uptake and utilize per minute, and is one of the key determinants of superior endurance running performance (Bassett and Howley, 2000). Despite having similar endurance performance abilities, runners may display wide variation in VO2max values, indicating that other factors play a major role in determining exercise performance. Previous research (Daniels and Daniels, 1992) indicated that improvements in RE may result in superior running performance due to a reduced energetic cost at submaximal intensities, even amongst athletes with similar VO2max values, suggesting that to some extent it may be possible to compensate for limitations in VO2max with superior RE capabilities
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