Force-velocity relationship and stretch-shortening cycle function in sprint and endurance athletes

Andrew J. Harrison, Sean P. Keane, John Coglan

Research output: Contribution to journalArticlepeer-review

Abstract

This study examined the torque-velocity and power-velocity relationships of quadriceps muscle function, stretch shortening cycle function, and leg-spring stiffness in sprint and endurance athletes. Isokinetic maximal knee extension torque was obtained from 7 sprinters and 7 endurance athletes using a Con-trex isokinetic dynamometer. Torque and power measures were corrected for lean-thigh cross-sectional area and lean-thigh volume, respectively. Stretch-shortening cycle function and muscle stiffness measurements were obtained while subjects performed single-legged squat, countermovement, and drop-rebound jumps on an inclined sledge and force-plate apparatus. The results indicated that sprinters generated, on average, 0.15 ± 0.05 N·m·cm-2 more torque across all velocities compared with endurance athletes. Significant differences were also found in the power-velocity relationships between the 2 groups. The sprinters performed significantly better than the endurance athletes on all jumps, but there were no differences in prestretch augmentation between the groups. The average vertical leg stiffness during drop jumps was significantly higher for sprinters (5.86 N·m-1) compared with endurance runners (3.38 N·m-1). The findings reinforce the need for power training to be carried out at fast contraction speeds but also show that SSC function remains important in endurance running.

Original languageEnglish
Pages (from-to)473-479
Number of pages7
JournalJournal of Strength and Conditioning Research
Volume18
Issue number3
DOIs
Publication statusPublished - Aug 2004

Keywords

  • Biomechanics
  • Hill equation
  • Isokinetics
  • Jumping
  • Leg stiffness
  • Running

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