Publication detail

Biomechanical analysis of all-polyethylene total knee arthroplasty on periprosthetic tibia using the finite element method

APOSTOLOPOULOS, V. TOMÁŠ, T. BOHÁČ, P. MARCIÁN, P. MAHDAL, M. VALOUŠEK, T. JANÍČEK, P. NACHTNEBL, L.

English title

Biomechanical analysis of all-polyethylene total knee arthroplasty on periprosthetic tibia using the finite element method

Type

journal article in Web of Science

Language

en

Original abstract

Background and objective: Total knee arthroplasty (TKA) with modern all-polyethylene tibial (APT) components has shown high long-term survival rates and comparable results to those with metal-backed tibial components. Nevertheless, APT components are primarily recommended for older and low-demand patients. There are no evidence-based biomechanical guidelines for orthopaedic surgeons to determine the appropriate lower age limit for implantation of APT components. A biomechanical analysis was assumed to be suitable to evaluate the clinical results in patients under 70 years. The scope of this study was to determine biomechanically the appropriate lower age limit for implantation of APT components.& nbsp;Methods: To generate data of the highest possible quality, the geometry of the computational models was created based on computed tomography (CT) images of a representative patient. The cortical bone tissue model distinguishes the change in mechanical properties described in three parts from the tibial cut. The cancellous bone material model has a heterogeneous distribution of mechanical properties. The values used to determine the material properties of the tissues were obtained from measurements of a CT dataset comprising 45 patients.& nbsp;Results: Computational modeling showed that in the majority of the periprosthetic volume, the von Mises strain equivalent ranges from 200 to 2700 its; these strain values induce bone modeling and remodeling. The highest measured deformation value was 2910 its. There was no significant difference in the induced mechanical response between bone models of the 60-year and 70-year age groups, and there was < 3% difference from the 65-year age group.& nbsp;Conclusions: Considering in silico limitations, we suggest that APT components could be conveniently used on a bone with mechanical properties of the examined age categories. Under defined loading conditions, implantation of TKA with APT components is expected to induce modeling and remodeling of the periprosthetic tibia. Following clinical validation, the results of our study could modify the indication criteria of the procedure, and lead to more frequent implantation of all-polyethylene TKA in younger patients. (c) 2022 The Authors. Published by Elsevier B.V.& nbsp;

English abstract

Background and objective: Total knee arthroplasty (TKA) with modern all-polyethylene tibial (APT) components has shown high long-term survival rates and comparable results to those with metal-backed tibial components. Nevertheless, APT components are primarily recommended for older and low-demand patients. There are no evidence-based biomechanical guidelines for orthopaedic surgeons to determine the appropriate lower age limit for implantation of APT components. A biomechanical analysis was assumed to be suitable to evaluate the clinical results in patients under 70 years. The scope of this study was to determine biomechanically the appropriate lower age limit for implantation of APT components.& nbsp;Methods: To generate data of the highest possible quality, the geometry of the computational models was created based on computed tomography (CT) images of a representative patient. The cortical bone tissue model distinguishes the change in mechanical properties described in three parts from the tibial cut. The cancellous bone material model has a heterogeneous distribution of mechanical properties. The values used to determine the material properties of the tissues were obtained from measurements of a CT dataset comprising 45 patients.& nbsp;Results: Computational modeling showed that in the majority of the periprosthetic volume, the von Mises strain equivalent ranges from 200 to 2700 its; these strain values induce bone modeling and remodeling. The highest measured deformation value was 2910 its. There was no significant difference in the induced mechanical response between bone models of the 60-year and 70-year age groups, and there was < 3% difference from the 65-year age group.& nbsp;Conclusions: Considering in silico limitations, we suggest that APT components could be conveniently used on a bone with mechanical properties of the examined age categories. Under defined loading conditions, implantation of TKA with APT components is expected to induce modeling and remodeling of the periprosthetic tibia. Following clinical validation, the results of our study could modify the indication criteria of the procedure, and lead to more frequent implantation of all-polyethylene TKA in younger patients. (c) 2022 The Authors. Published by Elsevier B.V.& nbsp;

Keywords in English

Orthopaedic biomechanics; Total knee arthroplasty; Bone mechanics; All-polyethylene tibial component; Finite element model; von Mises strain

Released

28.04.2022

Publisher

Elsevier

Location

CLARE

ISSN

0169-2607

Volume

220

Number

1

Pages from–to

1–9

Pages count

9

BIBTEX


@article{BUT178256,
  author="Vasileios {Apostolopoulos} and Tomáš {Tomáš} and Petr {Boháč} and Petr {Marcián} and Michal {Mahdal} and Tomáš {Valoušek} and Pavel {Janíček} and Luboš {Nachtnebl},
  title="Biomechanical analysis of all-polyethylene total knee arthroplasty on periprosthetic tibia using the finite element method",
  year="2022",
  volume="220",
  number="1",
  month="April",
  pages="1--9",
  publisher="Elsevier",
  address="CLARE",
  issn="0169-2607"
}