학술논문
Laser-Deposited Beta Type Ti-42Nb Alloy with Anisotropic Mechanical Properties for Pioneering Biomedical Implants with a Very Low Elastic Modulus
Document Type
Academic Journal
Author
Source
Materials. October 2022, Vol. 15 Issue 20
Subject
Language
English
ISSN
1996-1944
Abstract
Author(s): Felipe Arias-González (corresponding author) [1,*]; Alejandra Rodríguez-Contreras [2,3,4]; Miquel Punset [2,3,4,5]; José María Manero [2,3,4]; Óscar Barro [1]; Mónica Fernández-Arias [1]; Fernando Lusquiños [1,6]; Javier Gil [7]; Juan Pou [...]
Present commercial titanium alloy implants have an elastic modulus higher than 100 GPa, whereas that of the cortical bone is much smaller (17–28 GPa). This elastic modulus mismatch produces a stress shielding effect and the resorption of the bone surrounding the implant. In the present work, a fiber texture is developed in β type Ti-42Nb (wt%) alloy ingots generated by laser-directed energy deposition (LDED) in order to achieve anisotropic mechanical properties. In addition, we demonstrate that laser-deposited β type Ti-42Nb alloy ingots with an intense fiber texture exhibit a very low elastic modulus in the building direction (E[sub.z] < 50 GPa) and high yield (σ[sub.0.2z] > 700 MPa) and tensile (UTS[sub.z] > 700 MPa) strengths. Laser-deposited Ti-42Nb alloy enhances the osteoinductive effect, promoting the adhesion, proliferation, and spreading of human osteoblast-like cells. Hence, we propose that laser-deposited β type Ti-42Nb alloy is a potentially promising candidate for the manufacturing of pioneering biomedical implants with a very low elastic modulus that can suppress stress shielding.
Present commercial titanium alloy implants have an elastic modulus higher than 100 GPa, whereas that of the cortical bone is much smaller (17–28 GPa). This elastic modulus mismatch produces a stress shielding effect and the resorption of the bone surrounding the implant. In the present work, a fiber texture is developed in β type Ti-42Nb (wt%) alloy ingots generated by laser-directed energy deposition (LDED) in order to achieve anisotropic mechanical properties. In addition, we demonstrate that laser-deposited β type Ti-42Nb alloy ingots with an intense fiber texture exhibit a very low elastic modulus in the building direction (E[sub.z] < 50 GPa) and high yield (σ[sub.0.2z] > 700 MPa) and tensile (UTS[sub.z] > 700 MPa) strengths. Laser-deposited Ti-42Nb alloy enhances the osteoinductive effect, promoting the adhesion, proliferation, and spreading of human osteoblast-like cells. Hence, we propose that laser-deposited β type Ti-42Nb alloy is a potentially promising candidate for the manufacturing of pioneering biomedical implants with a very low elastic modulus that can suppress stress shielding.