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3D printing of metallic framework coated with a bioglass matrix for implant applications
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Journal of Tissue Science and Engineering

ISSN: 2157-7552

Open Access

3D printing of metallic framework coated with a bioglass matrix for implant applications


16th International Conference on Tissue Engineering and Regenerative Medicine

October 06-07, 2021 | Webinar

Khalil El Mabrouk

Euromed Research Center, Euromed Engineering Faculty, Euromed University of Fes, Eco- Campus, Meknes Road, 30 000, BP51, Fes, Morocco

Scientific Tracks Abstracts: J Tissue Sci Eng

Abstract :

In a new approach combining Additive Manufacturing with Bioceramics, a metallic 3D porous structure coated with bioactive glass was produced for possible use in orthopedic implants. This approach aims to combine high mechanical properties of the metallic structure (stress shielding) with enhanced biological activity. 316L stainless steel (316L-SS) lattice structures, based on rhombic dodecahedron unit cell with a relative density of 20%, were designed and fabricated using Selective Laser Melting (SLM). Despite its good mechanical properties, 316L-SS (as many other metals) lacks the biofunctionality required to achieve longterm implantation. To be successfully used as biomaterial, these porous 3D lattice structures were thus coated by 58S bioglass through a simple impregnation method. The use of a silica layer was evaluated as possible pretreatment to improve bioglass adhesion. The coated parts are then assessed by scanning electron microscopy (SEM) coupled with energy dispersive spectrometry (EDS) to qualify the coating. Porous sample parts pretreated with a silica layer presented a denser coating structure when compared with untreated porous metallic structures. In the following round of characterization, parts were immersed in a simulated body fluid to study their ability to grow new bone tissue. Results show the formation of a uniform apatite layer after seven days of immersion, showing the bioregeneration capability. This, combined with the lightweight framework structure provided by 316-SS, will increase the lifetime of this new generation of orthopedic implants.

Biography :

PhD in Chemical Engineering on 2005 at Laval University-Canada; Postdoctoral in both Queen’s University- Canada and in Dow Chemical New Jersey-USA for more than one year. 2008-2013 Research Director in Moroccan Foundation for advanced Science Innovation and Research and in the meantime, Director of Technology Platform. Since 2013 Full Professor at Euromed University of Fes-Morocco.

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Citations: 807

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