2020 journal article

Joint laxity varies in response to partial and complete anterior cruciate ligament injuries throughout skeletal growth

JOURNAL OF BIOMECHANICS, 101.

By: S. Cone  n, E. Lambeth n, J. Piedrahita n, J. Spang* & M. Fisher n

co-author countries: United States of America πŸ‡ΊπŸ‡Έ
author keywords: Anterior cruciate ligament; Pediatric; Injury; Joint mechanics; Animal model
MeSH headings : Animals; Anterior Cruciate Ligament Injuries / complications; Biomechanical Phenomena; Female; Joint Instability / complications; Joint Instability / physiopathology; Rotation; Stifle / growth & development; Stifle / physiopathology; Swine
Source: Web Of Science
Added: March 23, 2020

Anterior cruciate ligament (ACL) injuries are increasingly common in the skeletally immature population. As such there is a need to increase our understanding of the biomechanical function of the joint following partial and complete ACL injury during skeletal growth. In this work, we aimed to assess changes in knee kinematics and loading of the remaining soft tissues following both partial and complete ACL injury in a porcine model. To do so, we applied anterior-posterior tibial loads and varus-valgus moments to stifle joints of female pigs ranging from early juvenile to late adolescent ages and assessed both kinematics and in-situ loads carried in the bundles of the ACL and other soft tissues including the collateral ligaments and the menisci. Partial ACL injury led to increased anterior tibial translation only in late adolescence and small increases in varus-valgus rotation at all ages. Complete ACL injury led to substantial increases in translation and rotation at all ages. At all ages, the medial collateral ligament and the medial meniscus combined to resist the majority of applied anterior tibial load following complete ACL transection. Across all ages and flexion angles, the contribution of the MCL ranged from 45 to 90% of the anterior load and the contribution of the medial meniscus ranged from 14 to 35% of the anterior load. These findings add to our current understanding of age-specific functional properties of both healthy and injured knees during skeletal growth.