Abstract
Introduction
Patellofemoral (PF) complications are among the most frequently observed adverse events after total knee arthroplasty (TKA). It has been reported that PF complications after TKA include decreasing knee range of motion, anterior knee pain, quadriceps and patellar-tendon rupture, patellar subluxation, and partial abrasion and loosening of the patellar component. Although recent improvements in surgical technique and prosthetic design have decreased these complications, the percentage of patients who have a revision TKA for PF complications still ranged up to 6.6% to 12%. For the present study, we hypothesized that the alignment of the femoral component is correlated with PF contact stress. The purpose of this study was to investigate the relationship between femoral component alignment and PF contact stress in vivo, using a pressure sensor in patients who had favorable extension-flexion gap balance during TKA.
Methods
Thirty knees with medial compartment osteoarthritis that underwent posterior stabilized mobile-bearing TKA using identical prostheses (PFC Sigma RPF; Depuy, Warsaw, IN, USA) by a single surgeon (TM) with modified gap technique under a computed tomography (CT)-based navigation system (Vector Vision 1.61; Brain Lab, Heimstetten, Germany) were evaluated. PF contact stress was measured intraoperatively and compared with the alignment of the femoral component including intraoperative navigation data concerning medial shift of the patella and lateral tilt of the patella, postoperative coronal femoral component angle (alpha angle), postoperative sagittal femoral component angle (gamma angle), postoperative condylar twist angle (CTA), postoperative lateral condylar lift-off angle, and postoperative mechanical femoral component angle (mFCA). In addition, postoperative Insall-Salvati ratio (I-S ratio) was measured by dividing the length of patellar tendon by the greatest diagonal length of the patella.
Results
Maximum PF stress was 2.4 ± 1.9 MPa, medial shift of the patella was 2.6 ± 1.5 mm, and lateral tilt of the patella was 8.5 ± 4.2 degrees. The PF contact stress was not correlated sagittal and coronal alignment of the femoral component and patella tracking, whereas rotational alignment of the femoral component was negatively correlated with the PF contact stress (r = −0.718, p < 0.01).
Discussion and conclusion
Multiple regression analysis shows that PF contact stress correlates with CTA, I-S ratio positively correlates with PF contact stress in Spearman correlation analysis. The results of the present study showed a negative correlation between maximum stress in the PF joint and CTA.
It has been reported that excessive external rotation increases the medial flexion gap, leading to symptomatic flexion instability of the femoral component. In addition, external rotation of the femoral component can cause relative medialization of the trochlear groove during flexion, resulting in anterior knee pain. Therefore, we should carefully decide the proper rotational alignment of the femoral component.
It has been reported that PF contact stress in a normal knee was from 2.1 to 2.9 MPa in a cadaveric study. In the present study, patients with rotational alignment of the femoral component after TKA between 1.2° and 2.2° internally rotated from CEA had PF contact stress in this normal range.