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Characterizing patellar tendon loading during the landing phases of a stop-jump task

Authors


Corresponding author: Professor Julie R. Steele, Biomechanics Research Laboratory, University of Wollongong, Northfields Ave, Wollongong, New South Wales 2522, Australia. Tel: +61 2 4221 4161, Fax: +61 2 4221 4096, E-mail: julie_steele@uow.edu.au

Abstract

Excessive extensor mechanism loading from repeated landing has been associated with overuse knee injuries, especially patellar tendinopathy. In order to reduce these loads, it is important to establish which landing task places the highest load on the patellar tendon. It was hypothesized that the horizontal landing would create higher patellar tendon force (FPT) compared with the vertical landing. Sixteen male athletes with healthy patellar tendons performed five successful trials of a stop-jump task, which involved a symmetrical two-foot landing after a horizontal approach (horizontal landing) followed by another symmetrical two-foot landing after a vertical jump (vertical landing). For both lower limbs during each trial, the participants' ground reaction forces were recorded, three-dimensional kinematics measured and FPT calculated by dividing the net knee joint moment by the patellar tendon moment arm. Compared with the vertical landing, significantly higher FPT, posterior ground reaction forces and FPT loading rates were generated during the horizontal landing, despite lower vertical ground reaction forces (FV), highlighting the notion that FV should not be used to reflect FPT. Understanding that a horizontal landing task places the highest load on the patellar tendon, provides an appropriate framework for future research to investigate lower limb landing strategies in athletes with patellar tendinopathy.

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