Female Athletes With Varying Levels of Vertical Stiffness Display Kinematic and Kinetic Differences During Single-Leg Hopping

in Journal of Applied Biomechanics

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Justin P. Waxman High Point University

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Kevin R. Ford High Point University

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Anh-Dung Nguyen High Point University

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Jeffrey B. Taylor High Point University

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DOI:
https://doi.org/10.1123/jab.2017-0144
Keywords:
leg spring; biomechanics; female athlete; spring-mass model
In Print:
Volume 34: Issue 1
Page Range:
65–75
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Vertical stiffness may contribute to lower-extremity injury risk; however, it is unknown whether athletes with different stiffness levels display differences in biomechanics. This study compared differences in biomechanics between female athletes (n = 99) with varying stiffness levels during a repetitive, single-leg, vertical hopping task. Vertical stiffness was calculated as the ratio of peak vertical ground-reaction force to maximum center-of-mass displacement. Tertiles were established using stiffness values, and separate 1-way ANOVAs were used to evaluate between-group differences. Stance times decreased, and flight times, ground-reaction force, and stiffness increased, from the low- to high-stiffness group (P < .050). The high-stiffness group displayed: (1) greater lateral trunk flexion (P = .009) and lesser hip adduction (P = .022) at initial ground contact compared to the low- and moderate-stiffness groups, respectively; (2) lesser peak hip adduction compared to the low-stiffness group (P = .040); (3) lesser lateral trunk-flexion (P = .046) and knee-flexion (P = .010) excursion compared to the moderate- and low-stiffness groups, respectively; and (4) greater peak hip-flexion (P = .001), ankle-dorsiflexion (P = .002), and ankle-eversion (P = .038) moments compared to the low-stiffness group. A wide range of variability in stiffness exists within a relatively homogenous population. Athletes with varying stiffness levels display biomechanical differences that may help identify the potential mechanism(s) by which stiffness contributes to injury risk.

Waxman, Ford, and Taylor are with the Department of Physical Therapy, High Point University, High Point, NC. Nguyen is with the Department of Athletic Training, High Point University, High Point, NC.

Address author correspondence to Justin P. Waxman at jwaxman@highpoint.edu.
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