Determining hyper-viscoelastic structural properties of UHMWPE material used in Prodisc-C prosthesis employing a finite element–optimization coupling method

Choosing an appropriate material that owns favorable mechanical properties for decreasing wear and increasing the lifespan of the prosthesis is of great importance. This study aimed to determine the Prodisc-C prosthesis structural properties using the finite element coupling method and optimization...

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Veröffentlicht in:	Journal of the Brazilian Society of Mechanical Sciences and Engineering 2023-06, Vol.45 (6), Article 320
Hauptverfasser:	Ghafarmoghadam, Sana, Seifzadeh, Alireza, Mokhtarian, Ali, Abedinzadeh, Reza
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Compressive properties Computer simulation Conformity Coupling Elastic properties Engineering Finite element method Mathematical models Mechanical Engineering Mechanical properties Optimization Optimization algorithms Prostheses Stress distribution Stress relaxation Stress relaxation tests Structural models Technical Paper Three dimensional models Two dimensional models Viscoelasticity
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creator	Ghafarmoghadam, Sana Seifzadeh, Alireza Mokhtarian, Ali Abedinzadeh, Reza
description	Choosing an appropriate material that owns favorable mechanical properties for decreasing wear and increasing the lifespan of the prosthesis is of great importance. This study aimed to determine the Prodisc-C prosthesis structural properties using the finite element coupling method and optimization algorithm. Another goal was to discuss and evaluate the von Mises stress and mechanical properties of Prodisc-C prosthesis including hyper-viscoelastic and viscoelastic properties. For this purpose, a two-dimensional model was built and further was simulated and discussed using Abaqus software. The model’s mechanical properties were obtained via an annealing optimization algorithm. The algorithm aimed to create conformity between stress relaxation diagrams achieved from each step of simulation and experimental tests. The obtained results confirmed a high similarity in terms of conformity between the optimized behaviors achieved from finite element based on the Moony–Rivlin and Neo-Hooke models and stress relaxation test results. Afterward, the acquired characteristic parameters were then employed in a three-dimensional structural model of Prodisc-C prosthesis to evaluate von Mises stress distribution under a compressive load of 73.6 N. After considering the hyper-viscoelastic properties of Moony–Rivlin for the upper part of the prosthesis, which was composed of cobalt, the maximum stress in the prosthesis was determined to be 429.7 MPa. However, for the lower part, which was composed of titanium, the stress was calculated to be 35 MPa. Moreover, the stress of the prosthesis polymeric core was evaluated to be 936 MPa, indicating an improvement in comparison to Neo-Hooke and prosthesis elastic properties.
doi_str_mv	10.1007/s40430-023-04096-y
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This study aimed to determine the Prodisc-C prosthesis structural properties using the finite element coupling method and optimization algorithm. Another goal was to discuss and evaluate the von Mises stress and mechanical properties of Prodisc-C prosthesis including hyper-viscoelastic and viscoelastic properties. For this purpose, a two-dimensional model was built and further was simulated and discussed using Abaqus software. The model’s mechanical properties were obtained via an annealing optimization algorithm. The algorithm aimed to create conformity between stress relaxation diagrams achieved from each step of simulation and experimental tests. The obtained results confirmed a high similarity in terms of conformity between the optimized behaviors achieved from finite element based on the Moony–Rivlin and Neo-Hooke models and stress relaxation test results. Afterward, the acquired characteristic parameters were then employed in a three-dimensional structural model of Prodisc-C prosthesis to evaluate von Mises stress distribution under a compressive load of 73.6 N. After considering the hyper-viscoelastic properties of Moony–Rivlin for the upper part of the prosthesis, which was composed of cobalt, the maximum stress in the prosthesis was determined to be 429.7 MPa. However, for the lower part, which was composed of titanium, the stress was calculated to be 35 MPa. 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Soc. Mech. Sci. Eng</addtitle><description>Choosing an appropriate material that owns favorable mechanical properties for decreasing wear and increasing the lifespan of the prosthesis is of great importance. This study aimed to determine the Prodisc-C prosthesis structural properties using the finite element coupling method and optimization algorithm. Another goal was to discuss and evaluate the von Mises stress and mechanical properties of Prodisc-C prosthesis including hyper-viscoelastic and viscoelastic properties. For this purpose, a two-dimensional model was built and further was simulated and discussed using Abaqus software. The model’s mechanical properties were obtained via an annealing optimization algorithm. The algorithm aimed to create conformity between stress relaxation diagrams achieved from each step of simulation and experimental tests. The obtained results confirmed a high similarity in terms of conformity between the optimized behaviors achieved from finite element based on the Moony–Rivlin and Neo-Hooke models and stress relaxation test results. Afterward, the acquired characteristic parameters were then employed in a three-dimensional structural model of Prodisc-C prosthesis to evaluate von Mises stress distribution under a compressive load of 73.6 N. After considering the hyper-viscoelastic properties of Moony–Rivlin for the upper part of the prosthesis, which was composed of cobalt, the maximum stress in the prosthesis was determined to be 429.7 MPa. However, for the lower part, which was composed of titanium, the stress was calculated to be 35 MPa. 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Soc. Mech. Sci. Eng</stitle><date>2023-06-01</date><risdate>2023</risdate><volume>45</volume><issue>6</issue><artnum>320</artnum><issn>1678-5878</issn><eissn>1806-3691</eissn><abstract>Choosing an appropriate material that owns favorable mechanical properties for decreasing wear and increasing the lifespan of the prosthesis is of great importance. This study aimed to determine the Prodisc-C prosthesis structural properties using the finite element coupling method and optimization algorithm. Another goal was to discuss and evaluate the von Mises stress and mechanical properties of Prodisc-C prosthesis including hyper-viscoelastic and viscoelastic properties. For this purpose, a two-dimensional model was built and further was simulated and discussed using Abaqus software. The model’s mechanical properties were obtained via an annealing optimization algorithm. The algorithm aimed to create conformity between stress relaxation diagrams achieved from each step of simulation and experimental tests. The obtained results confirmed a high similarity in terms of conformity between the optimized behaviors achieved from finite element based on the Moony–Rivlin and Neo-Hooke models and stress relaxation test results. Afterward, the acquired characteristic parameters were then employed in a three-dimensional structural model of Prodisc-C prosthesis to evaluate von Mises stress distribution under a compressive load of 73.6 N. After considering the hyper-viscoelastic properties of Moony–Rivlin for the upper part of the prosthesis, which was composed of cobalt, the maximum stress in the prosthesis was determined to be 429.7 MPa. However, for the lower part, which was composed of titanium, the stress was calculated to be 35 MPa. 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subjects	Algorithms Compressive properties Computer simulation Conformity Coupling Elastic properties Engineering Finite element method Mathematical models Mechanical Engineering Mechanical properties Optimization Optimization algorithms Prostheses Stress distribution Stress relaxation Stress relaxation tests Structural models Technical Paper Three dimensional models Two dimensional models Viscoelasticity
title	Determining hyper-viscoelastic structural properties of UHMWPE material used in Prodisc-C prosthesis employing a finite element–optimization coupling method
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