Finite element analysis of malposition in bi-unicompartmental knee arthroplasty

Armillotta, Nicola; Bori, Edoardo; Innocenti, Bernardo

doi:10.1007/s00402-022-04656-2

Arch Orthop Trauma Surg

2022

DOI: 10.1007/s00402-022-04656-2

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Finite element analysis of malposition in bi-unicompartmental knee arthroplasty

Nicola Armillotta

Edoardo Bori²,

Bernardo Innocenti³

Abstract: Purpose Bi-unicompartmental knee arthroplasty is a less invasive treatment than a total one, great advantage for the patient but more difficult for the surgeon because of the lower visibility during surgery; this can therefore lead to eventual small errors in cutting angles during the procedure. The aim of this study is to investigate the effects of these slight angle variations in terms of anterior-posterior slope for the lateral tibial tray. Methods The geometries of the bones were acquired and uncemented fi… Show more

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2024

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Cited by 2 publications

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Effect of design and surgical parameters variations in mobile‐bearing versus fixed‐bearing unicompartmental knee arthroplasty: A finite element analysis

Luyckx,

Bori,

Saldari

et al. 2024

J. exp. orthop.

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PurposeUnicompartmental knee arthroplasty (UKAs) are available in the market as fixed‐ and mobile‐bearing (FB and MB) and can be characterised by a different set of design parameters in terms of geometries, materials and surgical approaches, with overall good clinical outcomes. However, clear biomechanical evidence concerning the consequences of variations of these features on knee biomechanics is still lacking; therefore, the present study aims to perform a sensitivity analysis to see which outcomes are affected by these variations.MethodsFor both MB‐UKA and FB‐UKA, five design and surgical parameters were defined (bearing insert thickness, tibial component material, implant components friction coefficient, antero‐posterior slope angle and level of tibial bone resection). Two control models were defined based on standard configurations for both implants. Finite element analysis was chosen to perform this study, and different parameter combinations (216 models in total) were implemented and tested at both 0° and 90° of flexion, using a previously validated finite element knee model. The results were then evaluated in terms of bone and polyethylene Von Mises stress and tibio‐femoral contact area.ResultsBearing thickness, tibial bone cut and slope angle were found to be the most sensitive parameters for both types of UKAs. Specifically, changes in these parameters in the FB‐UKA appeared to induce more significant variations in the polyethylene insert (both in terms of polyethylene stress and contact area), while in the MB‐UKA, these changes influenced bone stress distribution more.ConclusionsSurgical parameters returned to have a more significant influence than material and friction variations; furthermore, the outcomes most affected by parameter variations were the insert‐related ones for FB‐UKA while for the MB‐UKA were the ones regarding tibial bone stresses.Level of EvidenceNot Applicable.

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Effect of design and surgical parameters variations in mobile‐bearing versus fixed‐bearing unicompartmental knee arthroplasty: A finite element analysis

Luyckx,

Bori,

Saldari

et al. 2024

J. exp. orthop.

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Effect of different constraining boundary conditions on simulated femoral stresses and strains during gait

Bavil,

Eghan-Acquah,

Diamond

et al. 2024

Sci Rep

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Finite element analysis (FEA) is commonly used in orthopaedic research to estimate localised tissue stresses and strains. A variety of boundary conditions have been proposed for isolated femur analysis, but it remains unclear how these assumed constraints influence FEA predictions of bone biomechanics. This study compared the femoral head deflection (FHD), stresses, and strains elicited under four commonly used boundary conditions (fixed knee, mid-shaft constraint, springs, and isostatic methods) and benchmarked these mechanics against the gold standard inertia relief method for normal and pathological femurs (extreme anteversion and retroversion, coxa vara, and coxa valga). Simulations were performed for the stance phase of walking with the applied femoral loading determined from patient-specific neuromusculoskeletal models. Due to unrealistic biomechanics observed for the commonly used boundary conditions, we propose a novel biomechanical constraint method to generate physiological femur biomechanics. The biomechanical method yielded FHD (< 1 mm), strains (approaching 1000 µε), and stresses (< 60 MPa), which were consistent with physiological observations and similar to predictions from the inertia relief method (average coefficient of determination = 0.97, average normalized root mean square error = 0.17). Our results highlight the superior performance of the biomechanical method compared to current methods of constraint for both healthy and pathological femurs.

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Finite element analysis of malposition in bi-unicompartmental knee arthroplasty

Cited by 2 publications

References 36 publications

Effect of design and surgical parameters variations in mobile‐bearing versus fixed‐bearing unicompartmental knee arthroplasty: A finite element analysis

Effect of design and surgical parameters variations in mobile‐bearing versus fixed‐bearing unicompartmental knee arthroplasty: A finite element analysis

Effect of different constraining boundary conditions on simulated femoral stresses and strains during gait

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