523 resultados para hydroxyapatite
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Desde 1965 em que se colocaram as primeiras próteses osteointegradas sob os princípios de Brånemark, a implantologia sofreu uma constante e notória evolução e consiste, hoje, na primeira linha de tratamento em reabilitação oral. Os mecanismos que induzem a adesão óssea ou a união entre o implante e o osso, ainda não são perfeitamente conhecidos. As conclusões que se obtiveram das pesquisas, demostraram que a taxa de osteointegração dos impantes e o índice de sucesso relacionam-se com a composição química e com a rugosidade da superfície. Os implantes com rugosidades superficiais possuem maior estabilidade primária e modificam os mecanismos de interação das células com a superfície, quando comparados com os de superfície lisa. Quanto à composição química das superfícies dos implantes, as enriquecidas com cálcio e hidroxiapatite, favorecem e promovem o processo de cicatrização e de deposição óssea. Os estudos comparativos entre as superfícies modificadas por métodos de tratamento físicos e/ou químicos, quando comparados com as superfícies maquinadas, demonstram a superioridade das superfícies rugosas em muitos aspectos biomecânicos, sendo hoje um consenso entre a comunidade científica, a superioridade das superfícies modificadas. Independentemente das evidências científicas apontarem para maiores taxas de sucesso associadas ás superfícies tratadas, ainda há um longo caminho a percorrer para colmatar todas as falhas existentes na atualidade. O objetivo deste trabalho foi a realização de uma revisão bibliográfica, através da pesquisa de artigos da Pubmed, B-On, Science Direct, Scielo de forma a aprofundar conhecimentos das vantagens e desvantagens da rugosidade presente na superfície implantar, assim como alertar os médicos dentistas para a importância a ter com a rugosidade em excesso e tentar perceber qual a rugosidade dita ideal. Não se limitou o tempo de pesquisa mas deu-se relevância a referências científicas dos últimos 20 anos, publicados em língua portuguesa e inglesa.
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Giant cell-rich osteolytic lesions may have overlapping clinical, radiologic, and histopathologic features, with an important degree of difficulty of diagnosis and treatment. We report a case of double osteolytic lesion at the middle-finger in a young man without previous history of hand trauma. He underwent en-bloc resection of the bone lesions and reconstruction by graft of hydroxyapatite, resulting in a good morpho-functional result. Histological diagnosis was giant cell reparative granuloma (GCRG), although several features were considered atypical, including the appearance of the giant cells and the areas of the stroma that more closely resembled a giant cell tumor. GCRG is a benign rare intraosseous lesion and the true nature is controversial and unknown. The theories are that it could be a reactive lesion, a developmental anomaly or a benign neoplasm. It appears as an osteolytic lesion that must be considered in the differential diagnosis of other “critical” bone lesions similar in clinical, as well as radiologic and pathological appearance. Further characterization studies are helpful and necessary for the proper management.
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For in vitro differentiation of bone marrow-derived mesenchymal stem cells/mesenchymal stromal cells into osteoblasts by 2-dimensional cell culture a variety of protocols have been used and evaluated in the past. Especially the external phosphate source used to induce mineralization varies considerably both in respect to chemical composition and concentration. In light of the recent findings that inorganic phosphate directs gene expression of genes crucial for bone development, the need for a standardized phosphate source in in vitro differentiation becomes apparent. We show that chemical composition (inorganic versus organic phosphate origin) and concentration of phosphate supplementation exert a severe impact on the results of gene expression for the genes commonly used as markers for osteoblast formation as well as on the composition of the mineral formed. Specifically, the intensity of gene expression does not necessarily correlate with a high quality mineralized matrix. Our study demonstrates advantages of using inorganic phosphate instead of beta-glycerophosphate and propose colorimetric quantification methods for calcium and phosphate ions as cost-and time-effective alternatives to X-ray diffraction and Fourier-transform infrared spectroscopy for determination of the calcium phosphate ratio and concentration of mineral matrix formed under in vitro-conditions. We critically discuss the different assays used to assess in vitro bone formation in respect to specificity and provide a detailed in vitro protocol that could help to avoid contradictory results due to variances in experimental design.
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Tooth loss is a common result of a variety of oral diseases due to physiological causes, trauma, genetic disorders, and aging and can lead to physical and mental suffering that markedly lowers the individual’s quality of life. Tooth is a complex organ that is composed of mineralized tissues and soft connective tissues. Dentin is the most voluminous tissue of the tooth and its formation (dentinogenesis) is a highly regulated process displaying several similarities with osteogenesis. In this study, gelatin, thermally denatured collagen, was used as a promising low-cost material to develop scaffolds for hard tissue engineering. We synthetized dentin-like scaffolds using gelatin biomineralized with magnesium-doped hydroxyapatite and blended it with alginate. With a controlled freeze-drying process and alginate cross-linking, it is possible to obtain scaffolds with microscopic aligned channels suitable for tissue engineering. 3D cell culture with mesenchymal stem cells showed the promising properties of the new scaffolds for tooth regeneration. In detail, the chemical–physical features of the scaffolds, mimicking those of natural tissue, facilitate the cell adhesion, and the porosity is suitable for long-term cell colonization and fine cell–material interactions.
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This report shows 2232 times purification of a βNAcetylhexosaminidase from hepatic extracts from the sea mammal Sotalia fluviatilis homogenate with final recovery of 8,4%. Sequenced steps were utilized for enzyme purification: ammonium sulfate fractionation, Biogel A 1.5 m, chitin, DEAESepharose and hydroxyapatite chromatographies. The protein molecular mass was estimated in 10 kDa using SDSPAGE and confirmed by MALDITOF. It was found to have an optimal pH of 5.0 and a temperature of 60°C. Using pnitrophenylNAcetylβDglycosaminide apparent Km and Vmax values were of 2.72 mM and 0.572 nmol/mg/min, respectively. The enzyme was inhibited by mercury chloride (HgCl2) and sodium dodecil sulfate (SDS)
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El hidroxiapatito es el biomineral de los tejidos duros de los mamíferos y por ello ha sido ampliamente estudiado como biomaterial en cementos óseos, recubrimientos de metales implantables y scaffold en ingeniería de tejidos. En este trabajo, se estudia un proceso síntesis y caracterización de un derivado de este material, donde el ion fosfonato: 2- hidroxifosfonoacetato sustituye parcialmente al ion fosfato [1-10%]. El proceso de síntesis de hidroxiapatito consiste en dos etapas: (1) una reacción a 100ºC entre el ácido fosfórico (añadido lentamente) y una mezcla de hidróxido de calcio + 2-hidroxifosfonoacetato de calcio (Relación Ca/P=1.67). (2) un tratamiento térmico de los sólidos obtenidos en (1) a 150ºC. Los productos finales se han caracterizado mediante análisis químico, análisis termogravimétrico, difracción de rayos-X con análisis de Rietveld, microscopía SEM y determinación de la superficie específica y porosidad. En las fases cristalinas, el grado de pureza de los hidroxiapatitos oscila entre 91-100%. Todos presentan estructura monoclínica, en contraste con la estructura hexagonal que habitualmente se obtiene aplicando métodos de síntesis similares. Esta variación se atribuye a la presencia de fosfonato. El contenido de éste también influye en la morfología y en la porosidad de los materiales, siendo las muestras con más fosfonato las más porosas. Los materiales, al menos aquellos con una cantidad menor o igual 5% de fosfonato, muestran una biocompatibilidad similar a un material de hidroxiapatito de referencia.
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International audience
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International audience
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International audience
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International audience
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This study describes a new synthesis route for bone chars using a CO2 atmosphere and their behavior as adsorbent for fluoride removal from water. Specifically, we have performed a detailed analysis of the adsorption properties of bone char samples obtained at different carbonization conditions and a comparative study with samples of bone char obtained via pyrolysis under nitrogen. Experimental results show that the nature of the gas atmosphere (CO2 versus N2) and the carbonization temperature play a major role to achieve an effective bone char for water defluoridation. In particular, the best adsorption properties of bone char for fluoride removal are obtained with those samples synthesized at 700 °C. Carbonization temperatures above 700 °C under CO2 atmosphere cause the dehydroxylation of the hydroxyapatite in the bone char, thus reducing its fluoride adsorption capacity. The maximum fluoride adsorption capacity for the bone char obtained in this study under CO2 atmosphere (i.e., 5.92 mg/g) is higher than those reported for commercial bone chars.
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Surface properties such as physicochemical characteristics and topographical parameters of biomaterials, essentially determining the interaction between the biological cells and the biomaterial, are important considerations in the design of implant materials. In this study, a layer of SrTiO3-TiO2 nanoparticle-nanotube heterostructures on titanium has been fabricated via anodization combined with a hydrothermal process. Titanium was anodized to create a layer of titania (TiO2) nanotubes (TNTs), which was then decorated with a layer of SrTiO3 nanoparticles via hydrothermal processing. SrTiO3-TiO2 heterostructures with high and low volume fraction of SrTiO3 nanoparticle (denoted by 6.3-Sr/TNTs and 1.4-Sr/TNTs) were achieved by using a hydrothermal processing time of 12 and 3 h, respectively. The in vitro biocompatibility of the SrTiO3-TiO2 heterostructures was assessed by using osteoblast cells (SaOS2). Our results indicated that the SrTiO3-TiO2 heterostructures with different volume fractions of SrTiO3 nanoparticles exhibited different Sr ion release in cell culture media and different surface energies. An appropriate volume fraction of SrTiO3 in the heterostructures stimulated the secretion of cell filopodia, leading to enhanced biocompatibility in terms of cell attachment, anchoring, and proliferation on the heterostructure surface.
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A systematic approach was developed to investigate the stability of gentamicin sulfate (GS) and GS/poly (lactic-co-glycolic acid) (PLGA) coatings on hydroxyapatite surfaces. The influence of environmental factors (light, humidity, oxidation and heat) upon degradation of the drug in the coatings was investigated using liquid chromatography with evaporative light scattering detection and mass spectrometry. GS coated rods were found to be stable across the range of environments assessed, with only an oxidizing atmosphere resulting in significant changes to the gentamicin composition. In contrast, rods coated with GS/PLGA were more sensitive to storage conditions with compositional changes being detected after storage at 60 °C, 75% relative humidity or exposure to light. The effect of γ-irradiation on the coated rods was also investigated and found to have no significant effect. Finally, liquid chromatography–mass spectrometry analysis revealed that known gentamines C1, C1a and C2 were the major degradants formed. Forced degradation of gentamicin coatings did not produce any unexpected degradants or impurities.
