Obtainment and characterization of a silicon alkoxides-based coating applied to a substrate of stainless steel 316L for use in biomaterials

The silicon alkoxides-based coating is an alternative to control the release of cytotoxic ions through metal implants. This study evaluated the influence of the number of layers of a hybrid coating on the surface of austenitic stainless steel AISI 316L on the corrosion resistance. This coating was produced from the precursors of silicon alkoxides 3-(trimethoxysilyl)propyl methacrylate (MAP) and tetraethoxisylane (TEOS) obtained by sol-gel process, and easily applied by dip-coating. Results indicated that a single layer of coating in the substrate showed a better protection than two layers. This single layer developed by the combination of the precursors TEOS-MAP was enough to create a compact and uniform film with good adherence to AISI 316L and higher electrochemical development. A single layer of TEOS-MAP coating is more adequate as a protective coating for the AISI 361L than the sample subjected to two layers and the non-coated substrate, because this film ensures its integrity in an aggressive environment

HA-hybrid matrix composite coating on Ti-Cp for biomedical application

Calcium phosphate coatings have been applied to titanium metal substrates and their alloys as a synergistic alternative capable of combining the mechanical properties of metals and the excellent bioactive properties provided by ceramic materials. However, the unsatisfactory adhesion of hydroxyapatite coatings on metallic substrates, as well as their limitation when subjected to mechanical stresses have been reported as a limitation. Biofunctional coatings have been proposed as an alternative to single ceramic coatings, aiming at optimizing the long-term clinical success of biomaterials such as Ti. This work aims at evaluating the morphological properties and biological behavior of Ti-cp coated with matrix composite coating hydroxyapatite-containing hybrid. The hybrid matrix was obtained from TEOS and MTES silicon precursors, with dispersed hydroxyapatite suspended by dip coating. For the morphological characterization FTIR, SEM/FEG, AFM and contact angle measurement were used. Biological behavior was evaluated for toxicity, cell viability and the osteogenic differentiation capacity of mesenchymal stem cells. The composite coatings obtained showed regular dispersion of hydroxyapatite particles in the hybrid matrix, with uniform coating adhering to the Ti-Cp substrate. Nevertheless, although they provided similar viability behavior of mesenchymal stem cells to the Ti-Cp substrate, the evaluated coatings did not present osteoinductive properties. This result is probably due to the pronounced hydrophobic behavior caused by the incorporation of HA

Electrochemical and mechanical behavior of UV curing paint on hybrid films modified with polyethyleneglycol plasticizer applied on tinplate

The objective of this work is to coat tinplate with a hybrid film obtained from a sol-gel process constituted by the alkoxide precursor tetraethoxysilane (TEOS) and 3-trimethoxysilylpropyl methacrylate (TMSM), with the addition of cerium nitrate (0.01 M) and polyethyleneglycol plasticizer (20 g.L-1) to the sol formulation. The films were obtained by dip-coating, applying one and two layers and curing them at different temperatures (60°C and 90°C) for 20 minutes, and adhering UV curing paint to each film respectively. The results showed that the double layered hybrid film obtained at 60°C had a higher layer of thickness and the best performance in the electrochemical assays, in other words, higher resistance to corrosion. Furthermore, in studies following the application of UV coating, the hybrid-film monolayer cured at 60°C wich had an organic coating of cured UV applied to it, achieved a performance similar to that of the pretreated alkyd greenhouse currently used in the metal packaging industry

Titânio revestido com recobrimento de matriz híbrida contendo hidroxiapatita visando a diferenciação osteogênica de células-tronco mesenquimais

O titânio comercialmente puro (Ti-Cp) e suas ligas destacam-se como biomateriais metálicos devido a sua biocompatibilidade sendo amplamente utilizados. Buscando aprimorar o sucesso clínico dos implantes de Ti-Cp em longo prazo, é necessário revestir a sua superfície, proporcionando uma eficiente ancoragem mecânica do implante com o tecido ósseo. Dentre os diversos revestimentos superficiais destacam-se os revestimentos híbridos orgânicos-inorgânicos à base de precursores alcóxidos de silício, obtidos via processo sol-gel. Para que ocorra uma satisfatória adesão do revestimento no substrato, precisa-se levar em consideração a natureza e a preparação da superfície metálica antes da aplicação deste revestimento. Na etapa inicial do trabalho, pré-tratamentos superficiais foram propostos previamente à aplicação dos revestimentos buscando aumentar a aderência entre o titânio e este revestimento híbrido. Utilizou-se três diferentes pré-tratamentos na superfície do Ti-Cp: o "piranha" (ácido sulfúrico e peróxido de hidrogênio), o "kroll" (ácido fluorídrico, ácido nítrico e água) e o "hidróxido de sódio". Em sequência, aplicou-se por processo de dip-coating sobre as superfícies tratadas, um revestimento híbrido produzido a partir dos precursores alcóxidos de silício tetraetoxisilano (TEOS) e metiltrietoxisilano (MTES), obtido pelo processo de sol-gel. Em uma segunda etapa, sobre a superfície do Ti-Cp com o pré-tratamento superficial que proporcionou uma maior aderência do revestimento híbrido ao titânio, aplicou-se por dip-coating, um revestimento híbrido à base de precursores alcóxidos de silício TEOS e MTES com adição de partículas de hidroxiapatita buscando aprimorar a diferenciação celular sobre o revestimento híbrido. O pré-tratamento com o hidróxido de sódio promove o melhor resultado dentre os pré-tratamentos, pois o revestimento híbrido aplicado posteriormente apresenta recobrimento regular e adesão ao substrato de Ti-Cp. Os resultados morfológicos por MEV-FEG mostraram um revestimento híbrido com boa dispersão da hidroxiapatita e um recobrimento regular e adesão ao substrato de Ti-Cp. Nos resultados biológicos Ti-Cp revestido com TEOS/MTES com a presença de partículas de hidroxiapatita obteve uma adesão celular semelhante ao Ti-Cp sem tratamento. Porém este mesmo revestimento não propiciou a proliferação e diferenciação celular. Os resultados indicaram que a combinação de fatores como a sua superfície hidrofóbica (91°) e a presença da hidroxiapatita no revestimento tornou a superfície desorganizada, acarretando em uma superfície com comportamento desfavorável para o desenvolvimento das células-tronco mesenquimais.Commercially pure titanium (cp-Ti) and its alloys stand out among the metallic materials due to their biocompatibility being widely used in biomaterials. In order to improve the clinical success of cp-Ti implants in the long term, it is necessary to coat the surface, providing an efficient mechanical anchoring of the implant with the bone tissue. Among the various surface coatings are the hybrid coatings based on silicon alkoxide precursors, obtained by the sol-gel process, however, considering the nature and the preparation of the metal surface prior to the application of this coating. In the initial stage of the work, surface pre-treatments were proposed prior to the application of the coatings seeking to increase the adhesion between the titanium and this hybrid coating. Three different pretreatments were used on the cp-Ti surface: "piranha" (sulfuric acid and hydrogen peroxide), "kroll "(hydrofluoric acid, nitric acid and water) and "sodium hydroxide". Subsequently, a hybrid coating produced by the tetraethoxysilane silicon (TEOS) and methyltriethoxysilane (MTES) precursors obtained by the sol-gel process was applied by the dip-coating process onto the treated surfaces. In a second step, on the surface of the cp-Ti with the surface pretreatment that gave a greater adhesion of the hybrid coating to the titanium, dip-coating, a hybrid coating based on precursors silicon alkoxides TEOS and MTES with the addition of hydroxyapatite particles to enhance cell differentiation on the hybrid coating. Pretreatment with sodium hydroxide promotes the best result among the pre-treatments, since the hybrid coating applied afterwards presents regular coating and adhesion to the cp-Ti substrate. The morphological results by SEM-FEG showed a hybrid coating with good dispersion of the hydroxyapatite and a regular coating and adhesion to the cp-Ti substrate. In the biological results Ti-Cp coated with TEOS / MTES with the presence of hydroxyapatite particles obtained a cell adhesion similar to Ti-Cp without treatment. However, this same coating did not promote cell proliferation and differentiation. The results indicated that the combination of factors such as its hydrophobic surface (91°) and the presence of the hydroxyapatite encapsulated in the coating rendering the surface disorganized led to a surface with unfavorable behavior for the development of mesenchymal stem cells

Titânio revestido com recobrimento de matriz híbrida contendo hidroxiapatita visando a diferenciação osteogênica de células-tronco mesenquimais

O titânio comercialmente puro (Ti-Cp) e suas ligas destacam-se como biomateriais metálicos devido a sua biocompatibilidade sendo amplamente utilizados. Buscando aprimorar o sucesso clínico dos implantes de Ti-Cp em longo prazo, é necessário revestir a sua superfície, proporcionando uma eficiente ancoragem mecânica do implante com o tecido ósseo. Dentre os diversos revestimentos superficiais destacam-se os revestimentos híbridos orgânicos-inorgânicos à base de precursores alcóxidos de silício, obtidos via processo sol-gel. Para que ocorra uma satisfatória adesão do revestimento no substrato, precisa-se levar em consideração a natureza e a preparação da superfície metálica antes da aplicação deste revestimento. Na etapa inicial do trabalho, pré-tratamentos superficiais foram propostos previamente à aplicação dos revestimentos buscando aumentar a aderência entre o titânio e este revestimento híbrido. Utilizou-se três diferentes pré-tratamentos na superfície do Ti-Cp: o "piranha" (ácido sulfúrico e peróxido de hidrogênio), o "kroll" (ácido fluorídrico, ácido nítrico e água) e o "hidróxido de sódio". Em sequência, aplicou-se por processo de dip-coating sobre as superfícies tratadas, um revestimento híbrido produzido a partir dos precursores alcóxidos de silício tetraetoxisilano (TEOS) e metiltrietoxisilano (MTES), obtido pelo processo de sol-gel. Em uma segunda etapa, sobre a superfície do Ti-Cp com o pré-tratamento superficial que proporcionou uma maior aderência do revestimento híbrido ao titânio, aplicou-se por dip-coating, um revestimento híbrido à base de precursores alcóxidos de silício TEOS e MTES com adição de partículas de hidroxiapatita buscando aprimorar a diferenciação celular sobre o revestimento híbrido. O pré-tratamento com o hidróxido de sódio promove o melhor resultado dentre os pré-tratamentos, pois o revestimento híbrido aplicado posteriormente apresenta recobrimento regular e adesão ao substrato de Ti-Cp. Os resultados morfológicos por MEV-FEG mostraram um revestimento híbrido com boa dispersão da hidroxiapatita e um recobrimento regular e adesão ao substrato de Ti-Cp. Nos resultados biológicos Ti-Cp revestido com TEOS/MTES com a presença de partículas de hidroxiapatita obteve uma adesão celular semelhante ao Ti-Cp sem tratamento. Porém este mesmo revestimento não propiciou a proliferação e diferenciação celular. Os resultados indicaram que a combinação de fatores como a sua superfície hidrofóbica (91°) e a presença da hidroxiapatita no revestimento tornou a superfície desorganizada, acarretando em uma superfície com comportamento desfavorável para o desenvolvimento das células-tronco mesenquimais.Commercially pure titanium (cp-Ti) and its alloys stand out among the metallic materials due to their biocompatibility being widely used in biomaterials. In order to improve the clinical success of cp-Ti implants in the long term, it is necessary to coat the surface, providing an efficient mechanical anchoring of the implant with the bone tissue. Among the various surface coatings are the hybrid coatings based on silicon alkoxide precursors, obtained by the sol-gel process, however, considering the nature and the preparation of the metal surface prior to the application of this coating. In the initial stage of the work, surface pre-treatments were proposed prior to the application of the coatings seeking to increase the adhesion between the titanium and this hybrid coating. Three different pretreatments were used on the cp-Ti surface: "piranha" (sulfuric acid and hydrogen peroxide), "kroll "(hydrofluoric acid, nitric acid and water) and "sodium hydroxide". Subsequently, a hybrid coating produced by the tetraethoxysilane silicon (TEOS) and methyltriethoxysilane (MTES) precursors obtained by the sol-gel process was applied by the dip-coating process onto the treated surfaces. In a second step, on the surface of the cp-Ti with the surface pretreatment that gave a greater adhesion of the hybrid coating to the titanium, dip-coating, a hybrid coating based on precursors silicon alkoxides TEOS and MTES with the addition of hydroxyapatite particles to enhance cell differentiation on the hybrid coating. Pretreatment with sodium hydroxide promotes the best result among the pre-treatments, since the hybrid coating applied afterwards presents regular coating and adhesion to the cp-Ti substrate. The morphological results by SEM-FEG showed a hybrid coating with good dispersion of the hydroxyapatite and a regular coating and adhesion to the cp-Ti substrate. In the biological results Ti-Cp coated with TEOS / MTES with the presence of hydroxyapatite particles obtained a cell adhesion similar to Ti-Cp without treatment. However, this same coating did not promote cell proliferation and differentiation. The results indicated that the combination of factors such as its hydrophobic surface (91°) and the presence of the hydroxyapatite encapsulated in the coating rendering the surface disorganized led to a surface with unfavorable behavior for the development of mesenchymal stem cells

Effect of concentrations of plasticizers on the sol-gel properties developed from alkoxides precursors

Coatings developed through sol-gel method is presented as an interesting replacement to chromium coating. Sol-gel method present advantages as high purity and excellent distribution of the components. The objective of this work is to synthesize and characterize a film obtained by sol-gel route. The film was prepared with 3-(trimethoxysilylpropyl) methacrylate (TMSPMA), tetraethoxysilane (TEOS) and cerium nitrate, using water and ethanol as solvents. Polyethyleneglycol (PEG) plasticizer was added at four different concentrations. The sol was characterized by techniques of viscosity, thermogravimetric analysis (TGA), X-ray diffraction (XRD) nuclear magnetic resonance spectroscopy (NMR) and Fourier transform infrared spectroscopy (FT-IR). The results showed that tetrafunctional alkoxides condensation was retarded by the plasticizer, forming a compact film. The film with 20 g.L-1 of PEG showed the best electrochemical behavior

Effect of concentrations of plasticizers on the sol-gel properties developed from alkoxides precursors

Abstract Coatings developed through sol-gel method is presented as an interesting replacement to chromium coating. Sol-gel method present advantages as high purity and excellent distribution of the components. The objective of this work is to synthesize and characterize a film obtained by sol-gel route. The film was prepared with 3-(trimethoxysilylpropyl) methacrylate (TMSPMA), tetraethoxysilane (TEOS) and cerium nitrate, using water and ethanol as solvents. Polyethyleneglycol (PEG) plasticizer was added at four different concentrations. The sol was characterized by techniques of viscosity, thermogravimetric analysis (TGA), X-ray diffraction (XRD) nuclear magnetic resonance spectroscopy (NMR) and Fourier transform infrared spectroscopy (FT-IR). The results showed that tetrafunctional alkoxides condensation was retarded by the plasticizer, forming a compact film. The film with 20 g.L-1 of PEG showed the best electrochemical behavior

Photocatalytic Nanostructured Self-Assembled Poly(allylamine hydrochloride)/Poly(acrylic acid) Polyelectrolyte Films Containing Titanium Dioxide–Gold Nanoparticles for Hydrogen Generation

In this study, we developed a facile layer-by-layer (LbL) method of incorporating gold (Au) and titanium dioxide (TiO₂) nanoparticles (NPs) into self-assembled photocatalytic films (SAPFs). The resulting SAPFs were then systematically characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), high-resolution transmission electron microscopy (HRTEM), UV–vis spectrophotometry, profilometry, and atomic force microscopy (AFM). The results revealed that the SAPFs incorporated TiO₂ and Au NPs with sizes of 21.2 ± 0.30 and 12.5 ± 0.05 nm, respectively. Moreover, the SAPFs with 40, 60, 80, and 100 layers exhibited thicknesses of 410, 472, 917, and 945 nm, respectively. The hydrogen produced by the SAPFs increased with increasing UV irradiation time in a linear relationship. Hydrogen was also produced within the bulk of the polymer/TiO₂–Au NP assemblies because water hydrates the network, allowing for facile hydrogen production in the bulk under irradiation. The present approach represents a significant advance over traditional nanostructured catalysts, for which the highest possible surface area is desired to maximize photocatalytic activity