Osteoblast response and osseointegration of a Ti–6Al–4V alloy implant incorporating strontium

## Abstract Corrosion of implant alloys releasing metal ions has the potential to cause adverse tissue reactions and implant failure. We hypothesized that macrophage cells and their released reactive chemical species (RCS) affect the alloy's corrosion properties. A custom cell culture corrosion box

## Abstract We have evaluated the __in‐vitro__ biocompatibility of Ti6Al4V alloy coated by plasma spraying with an identical alloy. These surfaces are widely used in cementless prosthetic components, although osteoblasts behavior on this treated alloy has not been evaluated to date. Cross sectional

## Abstract Due to excellent mechanical properties and good corrosion resistance, titanium–aluminium–vanadium (Ti‐6Al‐4V) and titanium–aluminium–niobium (Ti‐6Al‐7Nb) are extensively used for orthopedic surgery. Concern has been voiced concerning the implications of the constituent vanadium in Ti‐6A

This work studies the influence of the sintering conditions of a Ti-6Al-4V alloy on its corrosion performance. The alloy was vacuum sintered in different conditions of time and temperature. The density and microstructure (designating phase distribution) are evaluated. Corrosion resistance through el

The metal/ ceramic interface that constitutes an important part of the plasma-sprayed HA-coated Ti-6A1-4V system may, in fact, represent the "weak link in the implant design. A post-plasma-spray heat treatment to enhance chemical bonding at the metal/ ceramic interface and, hence, improve the mechan