Litcius/Paper detail

Porous Titanium by Additive Manufacturing: A Focus on Surfaces for Bone Integration

Sara Ferraris, Silvia Spriano

2021Metals20 citationsDOIOpen Access PDF

Abstract

Additive manufacturing (AM) is gaining increasing interest for realization of customized porous titanium constructs for biomedical applications and, in particular, for bone substitution. As first, the present review gives a short introduction on the techniques used for additive manufacturing of Ti/Ti-Alloys (Direct Energy Deposition—DED, Selective Laser Melting—SLM and Electron Beam Melting—EBM) and on the main bulk properties of additively manufactured titanium porous structures. Then, it discusses the main advancements in surface modifications of additively manufactured titanium constructs for bone contact applications. Even if specific surface modifications of constructs from AM are currently not widely explored, it is a critical open issue for application in biomedical implants. Some thermal, chemical, electrochemical, and hydrothermal treatments as well as different coatings are here described. The main aim of these treatments is the development of surface micro/nano textures, specific ion release, and addition of bioactivity to induce bone bonding and antibacterial activity. Physicochemical characterizations, in vitro bioactivity tests, protein absorption, in vitro (cellular/bacterial) and in vivo tests reported in the literature for bare and surface modified AM Ti-based constructs are here reviewed. Future perspectives for development of innovative additively manufactured titanium implants are also discussed.

Topics & Concepts

TitaniumMaterials scienceSelective laser meltingPorosityNanotechnologySurface modificationDeposition (geology)Scanning electron microscopeScaffoldTitanium alloyBiomedical engineeringMetallurgyChemical engineeringComposite materialMicrostructurePaleontologyMedicineEngineeringBiologyAlloySedimentAdditive Manufacturing Materials and ProcessesBone Tissue Engineering MaterialsAdditive Manufacturing and 3D Printing Technologies