Ni-Cr Alloys Assessment for Dental Implants Suitability

The performance of the field and the condition of success in oral implantology today require the review and reevaluation of the means that contribute essentially to ensuring the stability and durability of the implant, starting from the nature of the biomaterial and continuing with the characteristi...

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Bibliographic Details
Published in:Applied sciences 2022-12, Vol.12 (24), p.12814
Main Authors: Achitei, Dragos Cristian, Baltatu, Mădălina Simona, Vizureanu, Petrică, Sandu, Andrei Victor, Benchea, Marcelin, Istrate, Bogdan
Format: Article
Language:English
Subjects:
Alloys
Biocompatibility
Biomaterials
Biomedical materials
cast samples
Casting alloys
Comparative analysis
Corrosion
Dendritic structure
Dental alloys
Dental implants
Dental prosthetics
Dentistry
Design
Durability
Hardness
Indentation
Mechanical properties
Metals
Modulus of elasticity
Ni-Cr
Nickel
properties
Prostheses
Silicon
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Summary:The performance of the field and the condition of success in oral implantology today require the review and reevaluation of the means that contribute essentially to ensuring the stability and durability of the implant, starting from the nature of the biomaterial and continuing with the characteristics of the optimally designed biosurface. This paper proposes a comparative analysis of three commercial alloys, VeraBond, Kera N, and VeraSoft, compared to a modified dental alloy, with the aim of improving some mechanical properties. They have been studied structurally and mechanically. The microstructural structure shows that the alloys crystallize in the face-centered cube system, and the cast alloy has a dendritic structure with large grains. XRD diffractograms highlight that alloys exhibit three compounds Cr156.00 Al596.00: 9013031, Ni4.00, and Cr30.00Al48.00. The hardness measurements showed values between 203 HV and 430 HV. As the percentage of silicon increases, the hardness decreases. The modulus of elasticity obtained by the indentation method for the dental alloys was in the range of 46–153 GPa. The results showed that the hardness and elastic modulus of the new alloy was significantly minimized compared to the classical alloys used.
ISSN:2076-3417
2076-3417
DOI:10.3390/app122412814