Mechanical and Computational Fluid Dynamic Models for Magnesium-Based Implants-Reference-Cited by-同舟云学术

Mechanical and Computational Fluid Dynamic Models for Magnesium-Based Implants

Published:2024-02-08 Issue:4 Volume:17 Page:830
ISSN:1996-1944
Container-title:Materials
language:en
Short-container-title:Materials

Author:

Manescu (Paltanea) Veronica¹²^ORCID,Paltanea Gheorghe²^ORCID,Antoniac Aurora¹,Gruionu Lucian Gheorghe³^ORCID,Robu Alina¹,Vasilescu Marius¹,Laptoiu Stefan Alexandru¹,Bita Ana Iulia¹^ORCID,Popa Georgiana Maria⁴,Cocosila Andreea Liliana⁴,Silviu Vlad⁴,Porumb Anca⁵

Affiliation:

1. Faculty of Material Science and Engineering, National University of Science and Technology Politehnica Bucharest, 313 Splaiul Independentei, District 6, RO-060042 Bucharest, Romania

2. Faculty of Electrical Engineering, National University of Science and Technology Politehnica Bucharest, 313 Splaiul Independentei, District 6, RO-060042 Bucharest, Romania

3. Faculty of Mechanics, University of Craiova, 13 Alexandru Ioan Cuza, RO-200585 Craiova, Romania

4. Department of Surgical Disciplines, Faculty of Medicine and Pharmacy, University of Oradea, 10 P-ta 1 December Street, RO-410073 Oradea, Romania

5. Department of Dental Medicine, Faculty of Medicine and Pharmacy, University of Oradea, 10 P-ta 1 December Street, RO-410073 Oradea, Romania

Abstract

Today, mechanical properties and fluid flow dynamic analysis are considered to be two of the most important steps in implant design for bone tissue engineering. The mechanical behavior is characterized by Young’s modulus, which must have a value close to that of the human bone, while from the fluid dynamics point of view, the implant permeability and wall shear stress are two parameters directly linked to cell growth, adhesion, and proliferation. In this study, we proposed two simple geometries with a three-dimensional pore network dedicated to a manufacturing route based on a titanium wire waving procedure used as an intermediary step for Mg-based implant fabrication. Implant deformation under different static loads, von Mises stresses, and safety factors were investigated using finite element analysis. The implant permeability was computed based on Darcy’s law following computational fluid dynamic simulations and, based on the pressure drop, was numerically estimated. It was concluded that both models exhibited a permeability close to the human trabecular bone and reduced wall shear stresses within the biological range. As a general finding, the proposed geometries could be useful in orthopedics for bone defect treatment based on numerical analyses because they mimic the trabecular bone properties.

Publisher

MDPI AG

Link

https://www.mdpi.com/1996-1944/17/4/830/pdf

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