RETRACTED ARTICLE: Effect of sagittal femoral component alignment on biomechanics after mobile-bearing total knee arthroplasty

In this study, we used the previously developed and validated finite element (FE) model [19‐22]. A three-dimensional (3D) non-linear FE model for normal knee joint was developed using medical imaging data. The subject’s medical history showed no musculoskeletal disorders or related diseases arising from a malalignment in the lower extremity, which indicated a healthy knee joint. The model includes bony structures of the knee joint with soft tissues in the patellofemoral and tibiofemoral joint. The model was developed using computed tomography (CT) and magnetic resonance imaging (MRI) (Fig. 1). CT image was performed with 0.1 mm slice thickness using a 64-channel CT scanner (Somatom Sensation 64, Siemens Healthcare, Erlangen, Germany). MRI image was performed on a 3-T MR system (Discovery MR750w®, GE healthcare, Milwaukee, WI, USA) with GEM Flex-Medium coil. MRI scans were obtained with 0.4 mm slice thickness in the sagittal plane. The reconstructed CT and MRI models were combined in an appropriate alignment using a commercial software (Rapidform version 2006; 3D Systems Korea Inc., Seoul, South Korea). Bones were assumed to be rigid because bone stiffness is much higher than that of the relevant soft tissues, and its influence in this study was negligible [23]. The major ligaments were modeled with nonlinear and tension-only spring elements [24, 25]. The ligament insertion points were determined with respect to the anatomy seen in the magnetic resonance imaging of the subject and descriptions based on previous studies (Fig. 1) [26‐28].

To develop models for the changes in femoral sagittal alignment, two experienced surgeons (the second and sixth authors) performed a surgical simulation of a TKA. The simulation was conducted using Unigraphics NX (Version 7.0, Siemens PLM Software, Torrance, CA, USA). Computer-assisted design models of a mobile-bearing TKA from LCS (Johnson & Johnson—DePuy Orthopaedics, Inc., Warsaw, IN, USA) were virtually implanted into the bone geometry. A large-sized femoral component and size 4 tibial baseplate for mobile-bearing TKA were selected based on the dimensions of the femur and tibia, respectively. In the neutral position, in aligning the components in the coronal plane, the femoral component was set perpendicular to the mechanical axis connecting the center of the knee and the center of the femoral head. The tibial component was set perpendicular to the mechanical axis connecting the center of the knee and the center of the ankle joint. The rotational alignments of the femoral and tibial components were positioned in line with the femoral epicondylar and tibial anteroposterior axes, respectively. To develop the femoral component sagittal alignment models, the femoral component was positioned at − 3°, 0°, 3°, 5°, and 7° flexion in the plane parallel to the anterior cortex of the distal femur in the different simulated implantations (Fig. 2). The thickness of the distal bone cut was equal to the thickness of femoral component’s distal condyle.

In the TKA, contact conditions were applied between the femoral component and the PE insert, between the femoral component and the patellar button, and between the tibial component and the PE insert. The coefficient of friction between the PE material and the metal was selected as 0.04 for maintaining consistency with the explicit FE models proposed in previous studies [29]. The femoral component, PE insert, tibial component, and bone cement were composed of a cobalt chromium alloy (CoCr), ultra-high-molecular-weight polyethylene (UHMWPE), titanium alloy (Ti6Al4V), and poly (methyl methacrylate) (PMMA), respectively [29‐31]. The material properties for each TKA component are listed in Table 1. A cement layer with a constant penetration depth of 3 mm into the bone was considered. It was based on a test of different cementing techniques at the femoral and tibial resection surfaces that were in contact with the femoral and tibial components, respectively [32]. The interfaces between the prosthesis and the bone were rigidly fixed by the cement used in this study [31]. Convergence was defined to be a relative change of more than 5% between two adjacent meshes with a mean edge length of 1.2 mm [33]. The 15,302 elements were used to construct TKA model.

The changes in the femoral sagittal alignment model topologies provided six degrees of freedom to the TF and PF joints. The FE investigation included two types of loading conditions that corresponded with the loads used in the experiments that studied the TKA model validation and model predictions under deep-knee-bend loading conditions. The intact model was validated in a previous study [19‐22], and the TKA model was validated through a comparison with the models used in a previous study [34]. An anterior force of 133 N and posterior force of 89 N were applied to 30° and 75° flexions followed by a measurement of the total anterior-posterior (AP) displacement to validate the mobile-bearing TKA model under the first loading conditions [34]. The second loading conditions corresponded to a deep-knee-bend loading that was applied to evaluate the effects of the changes in femoral sagittal alignment. Computational analysis was performed with anterior-posterior force applied to the femur with respect to the compressive load applied to the hip with femoral internal-external rotation constrained, medial-lateral translation free, and flexion determined by a combination of vertical hip and quadriceps load, leading to a six degrees of freedom TF joint [35, 36]. A proportional integral-derivative controller was incorporated into the computational model to control the quadriceps in a manner similar to that in a previous experiment [37]. A control system was used to calculate the instantaneous quadriceps displacement that was required to match the target flexion profile and was the same as that used in the experiment. Internal-external and varus-valgus torques were applied to the tibia, with the rest of tibial degree of freedoms constrained [35, 36].

The FE model was analyzed using Abaqus FEA (formerly ABAQUS) software, Version 6.11 (Dassault Systèmes Simulia Corp., Johnston, RI, USA). The kinematics of the TF joint, PF contact stress, force in the collateral ligaments, and quadriceps muscle forces were calculated throughout the deep-knee-bend loading conditions. The AP TF joint translation was calculated based on Grood and Suntay’s definition of the joint coordinate system [38].

In the FE model used for the TKA, the AP translations in the TF joint were 8.7 and 7.3 mm at 30° and 75° flexions, respectively (Fig. 3), which was in agreement with a previous study that used experiments within one standard deviation under identical loading conditions applied to the prosthesis [34].

Figure 4 shows that kinematics of the TF joint changed as the femoral component flexed under deep-knee-bend activity. Posterior translation on the TF joint also increased with the increase in femoral component flexion (Fig. 4). FE models for mobile-bearing TKA showed posterior femoral rollback of their lateral condyle, while the medial condyle remained in a similar contact position during a deep-knee-bend condition (Fig. 5). However, the posterior position of the contact point was observed when the femoral component sagittal flexion increased in any angle of flexion during deep-knee-bend activity (Fig. 5). Contact stress on the PF joint decreased as the femoral component flexed during deep-knee-bend activity (Fig. 6). The 7° flexion model showed that contact stress on the PF joint decreased by 9.4% as compared to the − 3° model (Fig. 6).

Figure 7 shows collateral ligament force change as the femoral component flexed during deep-knee-bend activity. Both medial and lateral collateral ligaments’ forces decreased as the femoral component flexed. A similar trend was found in the quadriceps force (Fig. 8). It required the largest lumped quadriceps forces during deep flexion as the femoral component flexed. The flexion 7° model showed that the quadriceps force decreased by 10.4% compared to the − 3° model.