Study on Zr-xCu and Zr-xSi alloys with low elastic modulus for improving stress shield effect
10.14815/kjdm.2021.48.3.175
- Author:
Seung-Won KU
1
;
Chung-Seok KIM
;
Yeong-Mu KO
Author Information
1. Department of Dental Materials, School of Dentistry, Chosun University, Gwangju, Republic of Korea
- Publication Type:Original Article
- From:
Korean Journal of Dental Materials
2021;48(3):175-190
- CountryRepublic of Korea
- Language:English
-
Abstract:
The objective of this study was to fabricate Zr-xCu and Zr-xSi alloys with low elastic modulus for preventing bone resorption in dental biomaterials. Metallic materials are widely used for orthopedic and dental applications due to their superior characteristics of mechanical properties and biocompatibility. Many metals and alloys, such as stainless steel, Co-Cr alloys, and Ti-based alloys are commonly used. Among these dental metallic materials, pure Ti and Ti-6Al-4V alloy have become the most popular metals used for the endosseous parts of the implant, bone plates, and artificial joints due to their excellent specific corrosion resistance and high biocompatibility with natural bone. Stress shield effect results in the reduction in bone density as a result of the removal of typical stress from the bone by an implant. In general, the bone in a healthy person will remodel in response to the loads it is placed under. Therefore, if the loading on a bone decreases, the bone will become less dense and weaker because there is no stimulus for continued remodeling that is required to maintain bone mass. Although Ti-based alloys have been widely used as implant components and devices, its elastic modulus (110 GPa) is much higher than that of natural human bone (10–30 GPa). Serious damage may be easily caused in the human body when the modulus of implant materials does not match the natural bone due to the stress shield effects. Therefore, in recent, persistent efforts have been done to obtain biological hard tissue materials with low elastic modulus to transfer stress to the surrounding bones effectively. The Zr-xCu binary alloy exhibited moderate compressive strength (1291-1411 MPa), yield stress (517-552 MPa), favorable elongation (16.4–49.2%), elastic energy (6.76–7.43 MJ/m3 ) and low elastic modulus (18.5–23.1 GPa). The Zr-xSi binary alloy exhibited high compressive strength (1105-1623 MPa), yield stress (673-1514 MPa), favorable elongation (6.0–27.2%), high elastic energy (10.2–34.6 MJ/m3 ) and low elastic modulus (22.3–33.1 GPa). Consequently, Zr-xCu and Zr-xSi binary alloys have the potential to be used as biomaterials with nullifying stress shield effects for biological hard tissue materials.
