Cooper Test Provides Better Half-Marathon Performance Prediction in Recreational Runners Than Laboratory Tests

José Ramón Alvero-Cruz; Elvis A Carnero; Manuel Avelino Giráldez García; Fernando Alacid; Thomas Rosemann; Pantelis T Nikolaidis; Beat Knechtle

doi:10.3389/fphys.2019.01349

Cooper Test Provides Better Half-Marathon Performance Prediction in Recreational Runners Than Laboratory Tests

Front Physiol. 2019 Nov 5:10:1349. doi: 10.3389/fphys.2019.01349. eCollection 2019.

Authors

José Ramón Alvero-Cruz¹, Elvis A Carnero², Manuel Avelino Giráldez García³, Fernando Alacid⁴, Thomas Rosemann⁵, Pantelis T Nikolaidis⁶, Beat Knechtle^{5

7}

Affiliations

¹ Faculty of Medicine, Andalucía TECH, University of Málaga, Málaga, Spain.
² Florida Hospital Sanford, Translational Research Institute for Diabetes and Metabolism, Burnham Prebys Medical Discovery Institute, Orlando, FL, United States.
³ Faculty of Sports Science and Physical Education, University of A Coruña, A Coruña, Spain.
⁴ Department of Education, Health Research Centre, University of Almería, Almería, Spain.
⁵ Institute of Primary Care, University of Zurich, Zurich, Switzerland.
⁶ Exercise Physiology Laboratory, Nikaia, Greece.
⁷ Medbase St. Gallen am Vadianplatz, St. Gallen, Switzerland.

Abstract

This study compared the ability to predict performance in half-marathon races through physiological variables obtained in a laboratory test and performance variables obtained in the Cooper field test. Twenty-three participants (age: 41.6 ± 7.6 years, weight: 70.4 ± 8.1 kg, and height: 172.5 ± 6.3 cm) underwent body composition assessment and performed a maximum incremental graded exercise laboratory test to evaluate maximum aerobic power and associated cardiorespiratory and metabolic variables. Cooper's original protocol was performed on an athletic track and the variables recorded were covered distance, rating of perceived exertion, and maximum heart rate. The week following the Cooper test, all participants completed a half-marathon race at the maximum possible speed. The associations between the laboratory and field tests and the final time of the test were used to select the predictive variables included in a stepwise multiple regression analysis, which used the race time in the half marathon as the dependent variable and the laboratory variables or field tests as independent variables. Subsequently, a concordance analysis was carried out between the estimated and actual times through the Bland-Altman procedure. Significant correlations were found between the time in the half marathon and the distance in the Cooper test (r = -0.93; p < 0.001), body weight (r = 0.40; p < 0.04), velocity at ventilatory threshold 1, (r = -0.72; p < 0.0001), speed reached at maximum oxygen consumption (vVO₂max), (r = -0.84; p < 0.0001), oxygen consumption at ventilatory threshold 2 (VO₂VT2) (r = -0.79; p < 0.0001), and VO₂max (r = -0.64; p < 0.05). The distance covered in the Cooper test was the best predictor of time in the half-marathon, and might predicted by the equation: Race time (min) = 201.26 - 0.03433 (Cooper test in m) (R ² = 0.873, SEE: 3.78 min). In the laboratory model, vVO2max, and body weight presented an R ² = 0.77, SEE 5.28 min. predicted by equation: Race time (min) = 156.7177 - 4.7194 (vVO₂max) - 0.3435 (Weight). Concordance analysis showed no differences between the times predicted in the models the and actual times. The data indicated a high predictive power of half marathon race time both from the distance in the Cooper test and vVO2max in the laboratory. However, the variable associated with the Cooper test had better predictive ability than the treadmill test variables. Finally, it is important to note that these data may only be extrapolated to recreational male runners.

Keywords: comparison performance methods; field test; laboratory test; long-distance runners; prediction equations.