Knee kinematics with a high-flexion posterior stabilized total knee prosthesis: An in vitro robotic experimental investigation

Background: An analysis of contemporary total knee arthroplasty reveals that, on the average, patients rarely flex the knee beyond 120degrees. The biomechanical mechanisms that inhibit further flexion after total knee arthroplasty are unknown. The objective of the present study was to investigate the capability of a single design of a fixed-bearing, high-flexion posterior stabilized total knee arthroplasty system (LPS-Flex) to restore the range of flexion to that of the intact knee. Methods: Thirteen cadaveric human knees were tested, with use of a robotic testing system, before and after total knee arthroplasty with the LPS-Flex prosthesis. The passive path and the kinematics under an isolated quadriceps force of 400 N, under an isolated hamstring force of 200 N, and with these forces combined were determined. Posterior femoral translation of the lateral and medial femoral condyles and tibial rotation were recorded from 0degrees to 150degrees of flexion. Results: The medial and lateral condyles of the intact knee translated posteriorly from full extension to 1500, reaching a mean peak (and standard deviation) of 22.9 +/- 11.3 mm and 31.9 +/- 12.5 mm, respectively, under the combined muscle forces. Following total knee arthroplasty, the amount of posterior femoral translation was lower than that observed in the intact knee. At 1500, approximately 90% of the intact posterior femoral translation was recovered by the total knee replacement. Internal tibial rotation was observed for all knees throughout the range of motion. The camspine mechanism engaged at approximately 800 and disengaged at 135degrees. Despite the absence of cam-spine engagement, further posterior femoral translation occurred from 135degrees to 150degrees. Conclusions: The tibiofemoral articular geometry of the intact knee and the knee after total knee arthroplasty with use of the LPS-Flex design demonstrated similar kinematics at high flexion angles. The cam-spine mechanism enhanced posterior femoral translation only at the mid-range of flexion. The femoral component geometry of the LPS-Flex total knee prosthesis may improve posterior tibiofemoral articulation contact in high flexion angles. Clinical Relevance: Although sufficient posterior femoral translation and tibial rotation were restored following total knee arthroplasty with the LPS-Flex prosthesis, these conditions alone may not be sufficient to fully produce the amount of knee flexion that is observed in the intact knee. The clinical outcome after total knee arthroplasty may be affected by other factors, such as preoperative range of motion, flexion space balancing, posterior tibiofemoral articular contact stability, quadriceps contraction, and patient motivation.