Improving the biocompatibility of implants is an extremely important step towards improving their quality. In this review, we recount the technological and biological process for coating implants with thin films enriched in titanium carbide (TiC), which provide improved cell growth and osseointegration. At first, we discuss the use of a Pulsed Laser Ablation Deposition, which produced films with a good biocompatibility, cellular stimulation and osseointegration. We then describe how Ion Plating Plasma Assisted technology could be used to produce a nanostructured layer composed by graphitic carbon, whose biocompatibility is enhanced by titanium oxides and titanium carbide. In both cases, the nanostructured coating was compact and strongly bound to the bulk titanium, thus particularly useful to protect implants from the harsh oxidizing environment of biological tissues. The morphology and chemistry of the nanostructured coating were particularly desirable for osteoblasts, resulting in improved proliferation and differentiation. The cellular adhesion to the TiC-coated substrates was much stronger than to uncoated surfaces, and the number of philopodia and lamellipodia developed by the cells grown on the TiC-coated samples was higher. Finally, tests performed on rabbits confirmed in vivo that the osseointegration process of the TiC-coated implants is more efficient than that of uncoated titanium implants.

A review of the effect of a nanostructured thin film formed by titanium carbide and titanium oxides clustered around carbon in graphitic form on osseointegration / Scandurra, Roberto; Scotto D'Abusco, Anna; Giovanni Longo, And. - In: NANOMATERIALS. - ISSN 2079-4991. - (2020). [10.3390/nano10061233]

A review of the effect of a nanostructured thin film formed by titanium carbide and titanium oxides clustered around carbon in graphitic form on osseointegration

Roberto Scandurra
;
Anna Scotto d’Abusco;
2020

Abstract

Improving the biocompatibility of implants is an extremely important step towards improving their quality. In this review, we recount the technological and biological process for coating implants with thin films enriched in titanium carbide (TiC), which provide improved cell growth and osseointegration. At first, we discuss the use of a Pulsed Laser Ablation Deposition, which produced films with a good biocompatibility, cellular stimulation and osseointegration. We then describe how Ion Plating Plasma Assisted technology could be used to produce a nanostructured layer composed by graphitic carbon, whose biocompatibility is enhanced by titanium oxides and titanium carbide. In both cases, the nanostructured coating was compact and strongly bound to the bulk titanium, thus particularly useful to protect implants from the harsh oxidizing environment of biological tissues. The morphology and chemistry of the nanostructured coating were particularly desirable for osteoblasts, resulting in improved proliferation and differentiation. The cellular adhesion to the TiC-coated substrates was much stronger than to uncoated surfaces, and the number of philopodia and lamellipodia developed by the cells grown on the TiC-coated samples was higher. Finally, tests performed on rabbits confirmed in vivo that the osseointegration process of the TiC-coated implants is more efficient than that of uncoated titanium implants.
2020
titanium; titanium carbide; fulsed laser deposition; Ion plating plasma assisted; tic coating; graphitic carbon; thin film; biocompatibility; implant osseointegration;human primary steoblasts
01 Pubblicazione su rivista::01a Articolo in rivista
A review of the effect of a nanostructured thin film formed by titanium carbide and titanium oxides clustered around carbon in graphitic form on osseointegration / Scandurra, Roberto; Scotto D'Abusco, Anna; Giovanni Longo, And. - In: NANOMATERIALS. - ISSN 2079-4991. - (2020). [10.3390/nano10061233]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1422515
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