BACKGROUND: many patellofemoral complications such as anterior knee pain, subluxation, fracture, wear, and aseptic loosening after total knee arthroplasty are attributed to malrotation of the femoral component. Rotating-platform mobile bearings can reduce malrotation between the tibial and femoral components and may also improve patellofemoral maltracking. METHODS: a computer model (LifeMOD/KneeSIM) of a weight-bearing deep knee bend was validated using cadaver knees tested in an Oxford-type knee rig. Changes in knee kinematics and patellofemoral forces were measured after femoral component malrotation of ± 3°. The effect of a rotating-bearing on these kinematics and forces was determined. FINDINGS: in a fixed-bearing arthroplasty femoral component internal malrotation increased tibiofemoral internal rotation by 3.4°, and external malrotation increased tibiofemoral external rotation by 4°. Femoral component malrotation affected patellofemoral lateral shift by up to 2.5mm, and patellofemoral lateral shear by up to 19N. When the malrotated femoral component was tested against a rotating-bearing the change in tibiofemoral rotation and patellofemoral lateral shift was less than 1° and 1mm respectively. The rotating-bearing reduced peak lateral shear by 7N and peak medial shear by 17N. Increasing the conformity of the rotating-bearing reduced changes in tibiofemoral rotation due to femoral malrotation and increased the net rotation of the bearing (by approximately 5°) during flexion. INTERPRETATION: our results are consistent with one randomized clinical outcome study and emphasize the value of computational modeling for preclinical design evaluation. It is important to continue to improve existing methodologies for accurate femoral component alignment especially in rotation. 2010 Elsevier Ltd. All rights reserved.
BACKGROUND: many patellofemoral complications such as anterior knee pain, subluxation, fracture, wear, and aseptic loosening after total knee arthroplasty are attributed to malrotation of the femoral component. Rotating-platform mobile bearings can reduce malrotation between the tibial and femoral components and may also improve patellofemoral maltracking. METHODS: a computer model (LifeMOD/KneeSIM) of a weight-bearing deep knee bend was validated using cadaver knees tested in an Oxford-type knee rig. Changes in knee kinematics and patellofemoral forces were measured after femoral component malrotation of ± 3°. The effect of a rotating-bearing on these kinematics and forces was determined. FINDINGS: in a fixed-bearing arthroplasty femoral component internal malrotation increased tibiofemoral internal rotation by 3.4°, and external malrotation increased tibiofemoral external rotation by 4°. Femoral component malrotation affected patellofemoral lateral shift by up to 2.5mm, and patellofemoral lateral shear by up to 19N. When the malrotated femoral component was tested against a rotating-bearing the change in tibiofemoral rotation and patellofemoral lateral shift was less than 1° and 1mm respectively. The rotating-bearing reduced peak lateral shear by 7N and peak medial shear by 17N. Increasing the conformity of the rotating-bearing reduced changes in tibiofemoral rotation due to femoral malrotation and increased the net rotation of the bearing (by approximately 5°) during flexion. INTERPRETATION: our results are consistent with one randomized clinical outcome study and emphasize the value of computational modeling for preclinical design evaluation. It is important to continue to improve existing methodologies for accurate femoral component alignment especially in rotation. 2010 Elsevier Ltd. All rights reserved.
Authors: Thomas Zumbrunn; Michael P Duffy; Harry E Rubash; Henrik Malchau; Orhun K Muratoglu; Kartik Mangudi Varadarajan Journal: Knee Surg Sports Traumatol Arthrosc Date: 2016-11-11 Impact factor: 4.342
Authors: Amir Sternheim; Jasjit Lochab; Michael Drexler; Paul Kuzyk; Oleg Safir; Allan Gross; David Backstein Journal: Int Orthop Date: 2012-10-16 Impact factor: 3.075