Use this URL to cite or link to this record in EThOS: https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.786949
Title: Design of customised total knee implants with musculoskeletal dynamic simulations
Author: Wang, Linjie
Awarding Body: University of Sussex
Current Institution: University of Sussex
Date of Award: 2019
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Abstract:
Effects of a customised total knee implant (CTKI) on the contact forces and relative motions of the tibiofemoral and patellofemoral joints have been investigated with computer simulations by applying the patient-specific muscle forces on the lower limb and the joint reaction forces at the ankle and hip joints. Firstly, a method was proposed and realized to create a CTKI based on the geometry of a patient's knee joint using ANSYS Mechanical APDL. Secondly, a patient-specific musculoskeletal model was built to calculate the muscle forces and joint reaction forces during a squat motion. Finally, a dynamic finite element (FE) model was created in ANSYS incorporating the aforementioned forces and the CTKI to calculate the contact forces and relative motions of the tibiofemoral and patellofemoral joints. In addition, an off-the-shelf symmetric total knee implant (STKI) with cruciate ligaments (CLs) retained was simulated for comparison analysis. Knee joint collateral ligaments with nonlinear properties and pretensions were created in the dynamic FE model. A series of dynamic simulations of a squat motion with different initial laxities of the collateral ligaments were performed on the CTKI model under three treatment scenarios of CLs: both CLs retained, anterior cruciate ligament (ACL) removed and both CLs removed. Results showed that only the CTKI model with both CLs retained resulted in similar femoral external rotation and posterior translation with those of the healthy knees. There were not big differences in the tibiofemoral compressive forces among the three scenarios. All the three tibiofemoral compressive forces showed good agreement with other research results from either in-vivo measurements or simulations. The CTKI has better mobility than the traditional STKI designs. The curvatures of the tibial bearing surfaces have been varied in the transverse and longitudinal directions. Compared with the STKI, the CTKIs could restore patient's knee function to normal, though the tibiofemoral compressive force observed in CTKIs was larger than that of the STKI in the late 25° of simulated knee flexion angles, which was caused by the large passive knee ligament forces and the larger knee motion ranges. The patella has also been studied and compared between the unresurfaced and resurfaced patellar components. The laxity of patellofemoral ligament was firstly tested on the unresurfaced patellar component. Then, the same dynamic boundary conditions were applied on three different patellar button components. Differences were found in the patellar internal rotation and medial tilt motions between the unresurfaced and resurfaced patellar components. The original patellar button component showed contact between the patellar bone and the femoral component apart from contact between the patellar component and the femoral component. The scaled-up button was able to avoid the contact between the patellar component and the femoral component and reduce the patellar medial translation. However, it resulted in larger patellofemoral force than that of the original and flat patellar components. The patellofemoral forces on the scaled-up patellar component were more fluctuating due to less conformity of the contact surfaces. The scaled-up patellar components were found to have two contact areas on the patellofemoral joint, while the original one had only one contact area.
Supervisor: Not available Sponsor: Not available
Qualification Name: Thesis (Ph.D.) Qualification Level: Doctoral
EThOS ID: uk.bl.ethos.786949  DOI: Not available
Keywords: RD0756 Artificial limbs
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