Analyzing Competitive Demands in Mountain Running Races: A Running Power-Based Approach

  1. Rodríguez-Medina, Juan 1
  2. Carballo-Leyenda, Belén 1
  3. Gutiérrez-Arroyo, Jorge 1
  4. García-Heras, Fabio 1
  5. Rodríguez-Marroyo, Jose A. 1
  1. 1 Department of Physical Education and Sports, Institute of Biomedicine (IBIOMED), Universidad de León, León, Spain
Journal:
International Journal of Sports Physiology and Performance

ISSN: 1555-0265 1555-0273

Year of publication: 2025

Volume: 20

Issue: 2

Pages: 275-281

Type: Article

DOI: 10.1123/IJSPP.2024-0234 GOOGLE SCHOLAR lock_openOpen access editor

More publications in: International Journal of Sports Physiology and Performance

Abstract

Purpose: This study aimed to analyze the competitive demands of mountain running races of varying lengths. Methods: Sixty-six male athletes competed in Vertical race (∼3 km and ∼1000 m of total elevation change), Sky race (∼25 km and ∼3000 m of total elevation change), and SkyUltra race (∼80 km and ∼9000 m of total elevation change). Exercise intensity and competition load (TL) were assessed using running power, heart rate, and rating of perceived exertion (RPE). Results: The highest exercise intensity was observed in Vertical race (3.9 [0.4] W·kg−1, 93.6% [2.8%] HRmax, and 9.5 [0.7] RPE) compared to Sky race (3.5 [0.5] W·kg−1, 89.9% [2.4%] HRmax, and 8.5 [1.2] RPE), and SkyUltra (2.7 [0.6] W·kg−1, 73.4% [1.1%] HRmax, and 8.2 [1.1] RPE). Vertical races had the highest mean maximal power outputs for periods <10 minutes. They also had the highest proportion of time spent >5 W·kg−1 and the most time spent above the respiratory compensation threshold. The majority of time in SkyUltra was spent at low intensity. The highest TLs were observed in these races (6200.5 [708.0] kJ, 842.0 [35.7] AU for TLHR, and 4897.3 [940.7] AU for TLRPE). However, when normalized to competition time, the SkyUltra event showed the lowest values compared with the Vertical and Sky races (∼11 vs ∼14.5 kJ·min−1, ∼1.5 vs ∼2.5 AU·m−1 for TLHR). Conclusion: The results of this study expand knowledge about the effort demands of mountain races and demonstrate how these demands are affected by race duration. Additionally, the study highlights the potential use of running power for quantifying exercise in this sport.

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