Advanced Ti-Nb-Ta Alloys for Bone Implants with Improved Functionality.
Jan-Oliver SassMarie-Luise SellinElisa KauertzJan JohannsenMarkus WeinmannMelanie StenzelMarcus FrankDanny VogelRainer BaderAnika Jonitz-HeinckePublished in: Journal of functional biomaterials (2024)
The additive manufacturing of titanium-niobium-tantalum alloys with nominal chemical compositions Ti-xNb-6Ta (x = 20, 27, 35) by means of laser beam powder bed fusion is reported, and their potential as implant materials is elaborated by mechanical and biological characterization. The properties of dense specimens manufactured in different build orientations and of open porous Ti-20Nb-6Ta specimens are evaluated. Compression tests indicate that strength and elasticity are influenced by the chemical composition and build orientation. The minimum elasticity is always observed in the 90° orientation. It is lowest for Ti-20Nb-6Ta (43.2 ± 2.7 GPa) and can be further reduced to 8.1 ± 1.0 GPa for open porous specimens ( p < 0.001). Furthermore, human osteoblasts are cultivated for 7 and 14 days on as-printed specimens and their biological response is compared to that of Ti-6Al-4V. Build orientation and cultivation time significantly affect the gene expression profile of osteogenic differentiation markers. Incomplete cell spreading is observed in specimens manufactured in 0° build orientation, whereas widely stretched cells are observed in 90° build orientation, i.e., parallel to the build direction. Compared to Ti-6Al-4V, Ti-Nb-Ta specimens promote improved osteogenesis and reduce the induction of inflammation. Accordingly, Ti-xNb-6Ta alloys have favorable mechanical and biological properties with great potential for application in orthopedic implants.
Keyphrases
- fine needle aspiration
- soft tissue
- minimally invasive
- oxidative stress
- mesenchymal stem cells
- endothelial cells
- single cell
- risk assessment
- human health
- cell death
- high resolution
- mass spectrometry
- cell therapy
- body composition
- cell cycle arrest
- signaling pathway
- high speed
- metal organic framework
- endoplasmic reticulum stress
- tissue engineering