HIP MOMENT INCREASES WHILE KNEE AND ANKLE MOMENTS REMAIN CONSTANT DURING SQUATS WITH INCREASING LOADS IN ELITE POWERLIFTERS

Authors

Alexander Pürzel, Centre for Sport Science and University Sports, University of Vienna, Vienna, AustriaFollow
Paul Kaufmann, Centre for Sport Science and University Sports, University of Vienna, Vienna, AustriaFollow
Willi Koller, Centre for Sport Science and University Sports, University of Vienna, Vienna, AustriaFollow
David Deimel, Centre for Sport Science and University Sports, University of Vienna, Vienna, AustriaFollow
Arnold Baca, Centre for Sport Science and University Sports, University of Vienna, Vienna, AustriaFollow
Hans Kainz, Centre for Sport Science and University Sports, University of Vienna, Vienna, AustriaFollow

Category

Athletics

Document Type

Paper

Abstract

This study aimed to investigate compensation strategies among elite powerlifters under high-load conditions. 31 top-ranked powerlifters from the Austrian team executed competition-style squats at 70%, 75%, 80%, 85%, and 90% of their estimated 1-repetition-maximum (F_max). Employing musculoskeletal modelling, we conducted a biomechanical analysis (i.e. joints moments calculated via inverse dynamics) to understand the alterations in squatting mechanics across various loads. Our findings revealed a consistent relative load shift from the knee to the hip joint with increasing intensity. The knee and ankle joint moments remained constant from 70% to 90% F_max, underscoring the dominant role of the hip joint in high-load squatting, which indicates that an increasing external load imposes varying relative loads on the hip, knee, and ankle joints during squats.

Recommended Citation

Pürzel, Alexander; Kaufmann, Paul; Koller, Willi; Deimel, David; Baca, Arnold; and Kainz, Hans (2024) "HIP MOMENT INCREASES WHILE KNEE AND ANKLE MOMENTS REMAIN CONSTANT DURING SQUATS WITH INCREASING LOADS IN ELITE POWERLIFTERS," ISBS Proceedings Archive: Vol. 42: Iss. 1, Article 17.
Available at: https://commons.nmu.edu/isbs/vol42/iss1/17