The aim of this study was to investigate the biomechanical effect of the anterolateral ligament (ALL), anterior cruciate ligament (ACL), or both ALL and ACL on kinematics under dynamic loading conditions using dynamic simulation subject-specific knee models. Five subject-specific musculoskeletal models were validated with computationally predicted muscle activation, electromyography data, and previous experimental data to analyze effects of the ALL and ACL on knee kinematics under gait and squat loading conditions.Objectives
Methods
Unicompartmental knee arthroplasty (UKA) is one surgical option for treating symptomatic medial osteoarthritis. Clinical studies have shown the functional benefits of UKA; however, the optimal alignment of the tibial component is still debated. The purpose of this study was to evaluate the effects of tibial coronal and sagittal plane alignment in UKA on knee kinematics and cruciate ligament tension, using a musculoskeletal computer simulation. The tibial component was first aligned perpendicular to the mechanical axis of the tibia, with a 7° posterior slope (basic model). Subsequently, coronal and sagittal plane alignments were changed in a simulation programme. Kinematics and cruciate ligament tensions were simulated during weight-bearing deep knee bend and gait motions. Translation was defined as the distance between the most medial and the most lateral femoral positions throughout the cycle.Objectives
Methods
Malalignment of the tibial component could influence the long-term survival of a total knee arthroplasty (TKA). The object of this study was to investigate the biomechanical effect of varus and valgus malalignment on the tibial component under stance-phase gait cycle loading conditions. Validated finite element models for varus and valgus malalignment by 3° and 5° were developed to evaluate the effect of malalignment on the tibial component in TKA. Maximum contact stress and contact area on a polyethylene insert, maximum contact stress on patellar button and the collateral ligament force were investigated.Objectives
Methods
The aim of the current study was to analyse the effects of posterior cruciate ligament (PCL) deficiency on forces of the posterolateral corner structure and on tibiofemoral (TF) and patellofemoral (PF) contact force under dynamic-loading conditions. A subject-specific knee model was validated using a passive flexion experiment, electromyography data, muscle activation, and previous experimental studies. The simulation was performed on the musculoskeletal models with and without PCL deficiency using a novel force-dependent kinematics method under gait- and squat-loading conditions, followed by probabilistic analysis for material uncertain to be considered.Objectives
Methods
Malrotation of the femoral component can result in post-operative complications in total knee arthroplasty (TKA), including patellar maltracking. Therefore, we used computational simulation to investigate the influence of femoral malrotation on contact stresses on the polyethylene (PE) insert and on the patellar button as well as on the forces on the collateral ligaments. Validated finite element (FE) models, for internal and external malrotations from 0° to 10° with regard to the neutral position, were developed to evaluate the effect of malrotation on the femoral component in TKA. Femoral malrotation in TKA on the knee joint was simulated in walking stance-phase gait and squat loading conditions.Objectives
Materials and Methods
The clinical diagnosis of a partial tear of the
anterior cruciate ligament (ACL) is still subject to debate. Little
is known about the contribution of each ACL bundle during the Lachman
test. We investigated this using six fresh-frozen cadaveric lower
limbs. Screws were placed in the femora and tibiae as fixed landmarks
for digitisation of the bone positions. The femur was secured horizontally
in a clamp. A metal hook was screwed to the tibial tubercle and
used to apply a load of 150 N directed anteroposteriorly to the
tibia to simulate the Lachman test. The knees then received constant
axial compression and 3D knee kinematic data were collected by digitising
the screw head positions in 30° flexion under each test condition.
Measurements of tibial translation and rotation were made, first with
the ACL intact, then after sequential cutting of the ACL bundles,
and finally after complete division of the ACL. Two-way analysis
of variance analysis was performed. During the Lachman test, in all knees and in all test conditions,
lateral tibial translation exceeded that on the medial side. With
an intact ACL, both anterior and lateral tibial landmarks translated
significantly more than those on the medial side (p <
0.001).
With sequential division of the ACL bundles, selective cutting of
the posterolateral bundle (PLB) did not increase translation of
any landmark compared with when the ACL remained intact. Cutting the
anteromedial bundle (AMB) resulted in an increased anterior translation
of all landmarks. Compared to the intact ACL, when the ACL was fully
transected a significant increase in anterior translation of all
landmarks occurred (p <
0.001). However, anterior tibial translation
was almost identical after AMB or complete ACL division. We found that the AMB confers its most significant contribution
to tibial translation during the Lachman test, whereas the PLB has
a negligible effect on anterior translation. Section of the PLB
had a greater effect on increasing the internal rotation of the
tibia than the AMB. However, its contribution of a mean of 2.8°
amplitude remains low. The clinical relevance of our investigation
suggests that, based on anterior tibial translation only, one cannot distinguish
between a full ACL and an isolated AMB tear. Isolated PLB tears
cannot be detected solely by the Lachman test, as this bundle probably
contributes more resistance to the pivot shift.
