In vitro evaluation of biocompatibility of Ti-Mo-Sn-Zr superelastic alloy
Autor: | Tada Aki Kudo, Hiroyasu Kanetaka, Hideki Hosoda, Kazuki Endoh, Shoko Nunome, Kaoru Igarashi |
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Jazyk: | angličtina |
Rok vydání: | 2015 |
Předmět: |
Materials science
Biocompatibility Scanning electron microscope Cell Survival Alloy Biomedical Engineering chemistry.chemical_element Biocompatible Materials engineering.material Cell Line Biomaterials Mice Cricetinae Alloys Animals Molybdenum Titanium Metallurgy Cell Cycle technology industry and agriculture Biomaterial Shape-memory alloy DNA equipment and supplies SMA Elasticity chemistry Tin Pseudoelasticity engineering Stress Mechanical Zirconium Biomedical engineering |
Zdroj: | Journal of Biomaterials Applications. 25659946:1-12 |
Popis: | Shape memory alloys (SMAs) including superelastic alloys have unique properties such as shape memory and superelasticity, thus they are recognized as very useful biomaterials. These properties are very advantageous for medical use, and actually the SMA wires have been widely used in medical field. However, biocompatibility of nickel-titanium (Ni–Ti) alloy, which is the only practical SMA at present, has been questioned because of its high nickel content. The aim of this study was to evaluate the biocompatibility of a newly developed Ni-free Ti-based SMA for medical use. The newly developed SMA made of Ti–Mo–Sn–Zr system was processed into a disk of 15.1 mm in diameter. Pure titanium of the same shape was prepared as control. All the disk surfaces were polished using emery papers, #120, #400, and #600. Scanning electron microscopy and a 3D optics profiler were used to evaluate the surface of the materials. In vitro evaluations included colony examination for evaluation of the cell cytotoxicity, DNA quantification for the cell proliferation, Alamar blue assay for metabolic activity, FDA staining for the live cell imaging, and cell cycle analysis, using Chinese hamster fibroblastic V-79 cells and mouse osteoblastic MC3T3-E1 cells. In colony examination and DNA quantification, there was no significant difference between the Ti–Mo–Sn–Zr and the pure titanium. In FDA staining, cultured cells on the Ti–Mo–Sn–Zr alloy showed the same biocompatibility as those on the pure titanium. The present results suggest that the newly developed Ti–Mo–Sn–Zr alloy showed the high biocompatibility comparable to pure titanium and can be used as efficient biomaterial for medical use. |
Databáze: | OpenAIRE |
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