Quadriceps force during knee extension in different replacement scenarios with a modular partial prosthesis

Abstract

BackgroundPrevious biomechanical studies have shown that bi-cruciate retaining knee replacement does not significantly alter normal knee kinematics, however, there are no data on the influence of a combined medial and patellofemoral bi-compartimental arthroplasty. The purpose of this in vitro study was to evaluate the effect of different replacement scenarios with a modular partial knee replacement system on the amount of quadriceps force required to extend the knee during an isokinetic extension cycle. MethodsTen human knee specimens were tested in a kinematic knee simulator under (1) physiologic condition and after subsequent implantation of (2) a medial unicondylar and (3) a trochlear replacement. An isokinetic extension cycle of the knee with a constant extension moment of 31Nm was simulated. The resulting quadriceps extension force was measured from 120° to full knee extension. FindingsThe quadriceps force curve described a typically sinusoidal characteristic before and after each replacement scenario. The isolated medial replacement resulted in a slightly, but significantly higher maximum quadriceps force (1510N vs. 1585N, P=0.006) as well as the subsequent trochlear replacement showed an additional increase (1801N, P=0.008). However, for both replacements no significant difference to the untreated condition could be detected in mid-flexion (10–50°). InterpretationWhen considering a bi-compartimental replacement an increase of required maximum quadriceps force needed to extend the knee has to keep in mind. However, the close to physiological movement in mid-flexion suggests that patients with a bi-crutiate retaining arthroplasty might have an advantage in knee stability compared to total knee arthroplasty.