| Literature DB >> 27882612 |
Josh C Carter1, Daniel R Sturnick2, Pamela M Vacek3, Michael J DeSarno3, Erin C Argentieri1, James R Slauterbeck1, Robert J Johnson1, Bruce D Beynnon1.
Abstract
The complex inter-segmental forces that are developed across an extended knee by body weight and contraction of the quadriceps muscle group transmits an anteriorly directed force on the tibia that strain the anterior cruciate ligament (ACL). We hypothesized that a relationship exists between geometry of the knees extensor mechanism and the risk of sustaining a non-contact ACL injury. Geometry of the extensor mechanism was characterized using MRI scans of the knees of 88 subjects that suffered their first non-contact ACL injury and 88 matched control subjects with normal knees that were on the same team. The orientation of the patellar tendon axis was measured relative to the femoral flexion-extension axis to determine the extensor moment arm (EMA), and relative to tibial long axis to measure coronal patellar tendon angle (CPTA) and sagittal patellar tendon angle (SPTA). Associations between these parameters and ACL injury risk were tested with and without adjustment for flexion and internal rotation position of the tibia relative to the femur during MRI data acquisition. After adjustment for internal rotation position of the tibia relative to the femur there were no associations between EMA, CPTA, and SPTA and risk of suffering an ACL injury. However, increased internal rotation position of the tibia relative to the femur was significantly associated with increased risk of ACL injury in female athletes both in univariate analysis (Odds Ratio = 1.16 per degree of internal rotation of the tibia, p = 0.002), as well as after adjustment for EMA, CPTA, and SPTA.:Entities:
Keywords: anterior cruciate ligament injury risk factor; extensor moment arm; femur; morphometrics; patellar tendon
Mesh:
Year: 2016 PMID: 27882612 DOI: 10.1002/jor.23366
Source DB: PubMed Journal: J Orthop Res ISSN: 0736-0266 Impact factor: 3.494