Articular Cartilage and Meniscus Reveal Higher Friction in Swing Phase Than in Stance Phase Under Dynamic Gait Conditions

Overview

Journal Sci Rep

Specialty Science

Date 2019 Apr 10

PMID 30962482

Citations 10

Authors

Daniela Warnecke

Maxi Messemer

Luisa de Roy

Svenja Stein

Cristina Gentilini

Robert Walker

Nick Skaer

Anita Ignatius

Lutz Durselen

Affiliations

Soon will be listed here.

Abstract

Most previous studies investigated the remarkably low and complex friction properties of meniscus and cartilage under constant loading and motion conditions. However, both load and relative velocity within the knee joint vary considerably during physiological activities. Hence, the question arises how friction of both tissues is affected by physiological testing conditions occurring during gait. As friction properties are of major importance for meniscal replacement devices, the influence of these simulated physiological testing conditions was additionally tested for a potential meniscal implant biomaterial. Using a dynamic friction testing device, three different friction tests were conducted to investigate the influence of either just varying the motion conditions or the normal load and also to replicate the physiological gait conditions. It could be shown for the first time that the friction coefficient during swing phase was statistically higher than during stance phase when varying both loading and motion conditions according to the physiological gait pattern. Further, the friction properties of the exemplary biomaterial were also higher, when tested under dynamic gait parameters compared to static conditions, which may suggest that static conditions can underestimate the friction coefficient rather than reflecting the in vivo performance.

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