Hydrolytic Expansion Induces Corrosion Propagation for Increased Fe Biodegradation

Abstract: Fe is regarded as a promising bone implant material due to inherent degradability and high mechanical strength, but its degradation rate is too slow to match the healing rate of bone. In this work, hydrolytic expansion was cleverly exploited to accelerate Fe degradation. Concretely, hydrolyzable Mg2Si was incorporated into Fe matrix through selective laser melting and readily hydrolyzed in a physiological environment, thereby exposing more surface area of Fe matrix to the solution. Moreover, the gaseous hydrol… Show more

“…Our recent studies focus on the use of SLS or SLM to fabricate biocermets for orthopedic applications, such as Mg-mesoporous silica (MS) [138], Mg-β-TCP [139], Mg-Zn-HA [140], Zn-SiC [120], Fe-Mg 2 Si [138] and so on. Concretely, we introduced MS into Mg alloy by using SLM to improve the degradation behavior.…”

Advances in biocermets for bone implant applications

“…Our recent studies focus on the use of SLS or SLM to fabricate biocermets for orthopedic applications, such as Mg-mesoporous silica (MS) [138], Mg-β-TCP [139], Mg-Zn-HA [140], Zn-SiC [120], Fe-Mg 2 Si [138] and so on. Concretely, we introduced MS into Mg alloy by using SLM to improve the degradation behavior.…”

Advances in biocermets for bone implant applications

Dilemmas and countermeasures of Fe-based biomaterials for next-generation bone implants

Challenges in the use of Fe-based materials for bone scaffolds applications: Perspective from in vivo biocorrosion