Reliability of Change-of-Direction Economy in Soccer Players

in International Journal of Sports Physiology and Performance

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Filippo Dolci
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Andrew E. Kilding
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Tania Spiteri
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Paola Chivers
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Ben Piggott
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Andrew Maiorana
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Nicolas H. Hart
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DOI:
https://doi.org/10.1123/ijspp.2019-0877
Keywords:
shuttle runs; football; movement efficiency; energetic cost; aerobic cost
First Published Online:
28 Oct 2020
In Print:
Volume 16: Issue 2
Page Range:
280–286
Restricted access

Purpose: To evaluate the reliability of new change-of-direction-economy tests (assessing energetic efficiency when performing continuous shuttle runs) compared with common running-economy tests in soccer players Methods: Sixteen subelite, male soccer players were recruited to perform a testing battery involving running economy (RE), 10-m shuttle-running economy (SRE10), and 20-m shuttle-running economy (SRE20) at 8.4 km·h−1 mean speed on 2 different days within 48 hours. SRE10 and SRE20 consisted of continuous shuttle runs interspersed with 180° directional changes. During the RE, SRE20, and SRE10 tests, respiratory exchange ratio and oxygen uptake were collected and used to calculate the movement-economy values over any running condition as oxygen cost and energetic cost. The secondary variables (carbon dioxide production, heart rate, minute ventilation, and blood lactate) were also monitored during all tests. Results: Depending on expression (oxygen cost or energetic cost), reliability was established for RE (CV: 5.5%–5.8%; ICC = .77–.88), SRE10 (CV: 3.5%–3.8%; ICC = .78–.96), and SRE20 (CV: 3.5%–3.8%; ICC = .66–.94). All secondary physiological variables reported good reliability (CV < 10%), except for blood lactate (CV < 35.8). The RE, SRE10, and SRE20 tests show good reliability in soccer players, whereas blood lactate has the highest variability among physiological variables during the economy tests. Conclusion: The assessment of change-of-direction economy through performing 20- and 10-m shuttle runs is reliable and can be applied to evaluate soccer players’ energetic movement efficiency under more soccer-specific running conditions.

Dolci and Piggott are with the School of Health Science, and Chivers and Hart, the Inst for Health Research, University of Notre Dame, Fremantle, WA, Australia. Kilding is with the Sports Performance Research Inst New Zealand, Auckland University of Technology, Auckland, New Zealand. Spiteri, Chivers, and Hart are with the School of Medical and Health Sciences, and Chivers and Hart also the Exercise Medicine Research Inst, Edith Cowan University, Perth, WA, Australia. Maiorana is with the School of Physiotherapy and Exercise Science, Curtin University, Perth, WA, Australia, and the Allied Health Dept, Fiona Stanley Hospital, Perth, WA, Australia.

Dolci (Filippo.dolci1@my.nd.edu.au) is corresponding author.
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