O. Contreras-Almengor , J. Ordoño , M. Li , E. Matykina , M. Avella , M. Echeverry-Rendón , A. Diaz-Lantada , J.M. Molina-Aldareguia
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引用次数: 0
Abstract
Laser powder bed fusion (LPBF) has emerged as a promising additive manufacturing technique to produce complex and custom-shaped NiTi devices, but precise control and characterization of the post-printing processing parameters are still required to achieve optimal surface properties and allow expanding the use of 3D-printed NiTi in cardiovascular applications. This work studies the effect of different surface post-processing techniques, including chemical etching, electropolishing and combinations of the two, on the surface properties and biological response of NiTi parts manufactured by LPBF. The different surface treatments resulted in changes in the roughness, wettability and corrosion resistance, which were closely correlated with the nature, microstructure and thickness of the surface oxide layers that form in each case. Furthermore, the biocompatibility of the different NiTi surfaces to human endothelial and smooth muscle cells, the main components of cardiovascular tissue, were also assessed. Interestingly, while the different surfaces showed high biocompatibility in terms of viability and proliferation, cells showed distinct morphology and orientation, as well as inflammatory response (IL-6). Finally, differences were also observed in the hemocompatibility of the 3D-printed NiTi surfaces to human blood. Overall, this work provides new insights for the wide use of additive manufacturing to develop personalized NiTi implants for cardiovascular applications.
期刊介绍:
Biomaterials Advances, previously known as Materials Science and Engineering: C-Materials for Biological Applications (P-ISSN: 0928-4931, E-ISSN: 1873-0191). Includes topics at the interface of the biomedical sciences and materials engineering. These topics include:
• Bioinspired and biomimetic materials for medical applications
• Materials of biological origin for medical applications
• Materials for "active" medical applications
• Self-assembling and self-healing materials for medical applications
• "Smart" (i.e., stimulus-response) materials for medical applications
• Ceramic, metallic, polymeric, and composite materials for medical applications
• Materials for in vivo sensing
• Materials for in vivo imaging
• Materials for delivery of pharmacologic agents and vaccines
• Novel approaches for characterizing and modeling materials for medical applications
Manuscripts on biological topics without a materials science component, or manuscripts on materials science without biological applications, will not be considered for publication in Materials Science and Engineering C. New submissions are first assessed for language, scope and originality (plagiarism check) and can be desk rejected before review if they need English language improvements, are out of scope or present excessive duplication with published sources.
Biomaterials Advances sits within Elsevier''s biomaterials science portfolio alongside Biomaterials, Materials Today Bio and Biomaterials and Biosystems. As part of the broader Materials Today family, Biomaterials Advances offers authors rigorous peer review, rapid decisions, and high visibility. We look forward to receiving your submissions!
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