Early implant failure and bone resorption may occur in load-bearing conditions as a result of
stress shielding brought on by a mismatch in the bone-Ti-implant modulus. A review with a …

The study aimed to analyze how milling time (2 h-24 h) affects structural, mechanical, and
tribological properties of Ti-15Mo alloys, these last has evaluated by using XRD, SEM, and a …

A new porous Ti–35Nb–5In alloy was designed to join the advantages of low elastic
modulus and non-toxicity, which are critical factors for biomedical implants. The Ti–35Nb …

Non-toxic biomedical HEAs by powder metallurgy methods have been scarcely studied
despite their promising mechanical and biological behaviors. This work studied the …

The use of cheap alloying elements and alternative manufacturing techniques are two
strategies that can be used to reduce the high cost of Ti alloys. Furthermore, heat treatments …

Biomaterials have always been the focus of material scientists and engineers. Titanium and
its alloys have favorable properties, such as high strength, low density, good corrosion …

Abstract Innovative Ti–3Al-xMo-yCr-0.1 B (x= 4, 2, 4; y= 2, 4, 4, wt.%) alloys were developed
via powder metallurgy by varying the contents of Mo and Cr. The aim is to reduce costs and …

The present study demonstrates the development of novel Ti-xZr (x= 5, 10, 15 and 20 wt.%)
via vacuum sealing-assisted sintering technique. The microstructure, phase composition …

Abstract A new Ti–Mo–In alloy was designed for biomedical implant applications and
produced by powder metallurgy. Mechanical properties, ion release, and electrochemical …

The performance of Ti alloys are directly related to their composition, where Zr and Cu are
generally used, respectively, because of their non-toxic and antibacterial behaviour. As not …