The superficial medial collateral ligament reconstruction of the knee: effect of altering graft length on knee kinematics and stability.

摘要

PURPOSE: The purpose of this study was to evaluate and compare the resulting knee kinematics and stability of an anatomic superficial MCL (sMCL) reconstruction and a non-anatomic sMCL reconstruction. METHODS: In a cadaveric model, normal knee stability and kinematics were compared with sMCL deficient knees and with two experimental sMCL reconstructions. The first reconstruction (AnatRecon) attempted to anatomically reconstruct the sMCL. The second reconstruction (ShortRecon) used a shorter graft to mimic the effect of failing to reproduce the anatomic length of the sMCL. Changes in position of the femur with respect to the tibia were measured with an electromagnetic tracking system during simulated active knee extension and during passive knee stability testing in the sMCL intact knee, the sMCL deficient knee, and the two experimental reconstructions. RESULTS: Simulated active knee extension demonstrated a significant increase in external tibial rotation of ShortRecon compared to AnatRecon between 30 degrees and 80 degrees of knee flexion (mean difference <3.0 degrees over the range of knee flexion angles; P < 0.008), and a significant increase in external tibial rotation of ShortRecon compared to the intact sMCL was found at 60 degrees and 70 degrees of knee flexion (mean difference <2.0 degrees over the range of knee flexion angles; P < 0.008). Passive joint stability testing demonstrated that division of the sMCL produced approximately 6 degrees of valgus laxity at 30 degrees of knee flexion and increased external tibial rotation of approximately 5 degrees at 30 degrees , 9 degrees at 60 degrees , and 10 degrees at 90 degrees of knee flexion, respectively. AnatRecon restored normal knee kinematics and stability. Additionally, passive stability testing demonstrated a significant increase in external tibial rotation of ShortRecon compared to AnatRecon at 60 degrees (mean difference = 3.7 degrees ; P < 0.05) and 90 degrees of knee flexion (mean difference = 4.9 degrees ; P < 0.05). CONCLUSION: Anatomic reconstruction of the sMCL effectively restored knee kinematics and stability in the sMCL deficient knee. Altering the normal ligament length resulted in measurable changes in knee kinematics and stability. This study suggests that in cases of chronic valgus knee instability, anatomic sMCL reconstruction would provide better results than non-anatomic sMCL reconstruction.