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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
41

Avaliação da biocompatibilidade e do efeito no reparo ósseo de um scaffold manufaturado a partir de um material vítreo fibroso / Biocompatibilty of a scaffold obtained from a fibrous glassy material and its effect on bone repair

Armelin, Paulo Roberto Gabbai 27 March 2015 (has links)
Submitted by Bruna Rodrigues (bruna92rodrigues@yahoo.com.br) on 2016-09-14T14:47:04Z No. of bitstreams: 1 TesePRGA.pdf: 5283158 bytes, checksum: c57ad9ff767d07147f784d369b1084cf (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-09-15T13:55:56Z (GMT) No. of bitstreams: 1 TesePRGA.pdf: 5283158 bytes, checksum: c57ad9ff767d07147f784d369b1084cf (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-09-15T13:56:08Z (GMT) No. of bitstreams: 1 TesePRGA.pdf: 5283158 bytes, checksum: c57ad9ff767d07147f784d369b1084cf (MD5) / Made available in DSpace on 2016-09-15T13:56:17Z (GMT). No. of bitstreams: 1 TesePRGA.pdf: 5283158 bytes, checksum: c57ad9ff767d07147f784d369b1084cf (MD5) Previous issue date: 2015-03-27 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Millions of bone fractures occur annually worldwide and the consequent bone repair process is complex, involving many biological events until it reaches the restoration of the tissue integrity. During that process some problems can occur due to delays in the bone healing, which does not allow the proper joining of the tissue. Thus, it is necessary to search for new technologies that work in restoring the integrity of the bone tissue and that promote the osteoconduction and the osteoinduction. In this sense, the use of bioactive materials in the bone repair process is a promising alternative. Following this, two studies (I and II) were developed in order to investigate a new fibrous glassy scaffold, and these studies were based in three lines of research: (i) the characterization of the new fibrous glassy scaffold; (ii) the biocompatibility evaluation of this bioactive material; (iii) the analysis of the biological performance of this new scaffold in the bone repair. More specifically, in the study I the developed scaffolds were characterized in terms of porosity, mineralization and morphological features. Additionally, fibroblast and osteoblast cells were seeded in contact with extracts of the scaffolds to assess cell proliferation and genotoxicity after 24, 72 and 144 h. Finally, scaffolds were placed subcutaneously in rats for 15, 30 and 60 days. In regards to study II, the morphological structure of the scaffolds upon incubation in phosphate buffered saline (PBS) (via scanning electron microscope) was assessed after 1, 7 and 14 days and, also, the in vivo tissue response to the new biomaterial was evaluated using implantation in rat tibial defects. The histopathological, immunohistochemistry and biomechanical analyzes after 15, 30 and 60 days of implantation were performed to investigate the effects of the material on bone repair. The scaffolds presented interconnected porous structures (porosity of ~75%), and the precursor bioglass could mineralize a hydroxycarbonate apatite (HCA) layer in SBF after only 12 h. The PBS incubation indicated that the fibers of the glassy scaffold degraded over time. With regards to the biological investigations, the biomaterial elicited increased fibroblast and osteoblast cell proliferation, and no DNA damage was observed. The in vivo experiment showed degradation of the biomaterial over time, with soft tissue ingrowth into the degraded area and the presence of multi-nucleated giant cells around the implant. At day 60, the scaffolds were almost completely degraded, and an organized granulation tissue filled the area. Additionally, the histological analysis of the implants in the bone defects revealed a progressive degradation of the material with increasing implantation time and also its substitution by granulation tissue and woven bone. Histomorphometry showed a higher amount of newly formed bone area in the control group (CG) compared to the biomaterial group (BG) 15 days post-surgery. After 30 and 60 days, CG and BG showed a similar amount of newly formed bone. The novel biomaterial enhanced the expression of RUNX-2 and RANK-L, and also improved the mechanical properties of the tibial callus at day 15 after surgery. These results indicate that the new fibrous glassy scaffold is bioactive, non-cytotoxic, biocompatible and promising for using in bone tissue engineering. / Milhões de fraturas ósseas ocorrem anualmente no mundo todo e o processo de reparo é complexo, envolvendo muitos eventos biológicos até que se atinja a restauração da integridade do tecido. Problemas nessa regeneração podem ocorrer, levando a não união óssea. Assim, faz-se necessária a busca por novas tecnologias que atuem na restauração da integridade do tecido ósseo e promovam a osteocondução e a osteoindução. Para tanto, uma alternativa promissora é a utilização de materiais bioativos para o reparo ósseo. Seguindo essa linha, foram realizados dois estudos (I e II) acerca de um novo scaffold vítreo fibroso, sendo estes estudos baseados em três linhas de investigação: (i) caracterização do novo scaffold vítreo fibroso; (ii) avaliação da biocompatibilidade desse material bioativo e (iii) análise do desempenho biológico desse novo scaffold no reparo ósseo. Mais especificamente, no estudo I foi feita a caracterização dos scaffolds em termos de porosidade, mineralização e características morfológicas. Adicionalmente, fibroblastos e osteoblastos foram cultivados em contato com extratos dos scaffolds para avaliação da proliferação celular e genotoxicidade após 24, 72 e 144 h. Finalmente, nesse mesmo estudo, os scaffolds foram implantados subcutaneamente em ratos por 15, 30 e 60 dias. No que se refere ao estudo II, foram feitas avaliações da estrutura morfológica dos scaffolds (via microscopia eletrônica de varredura) imersos em tampão fosfato salino (PBS) após 1, 7 e 14 dias, além de investigações do efeito no reparo ósseo do novo scaffold utilizando implantação do mesmo em defeitos ósseos tibiais em ratos. Análises histopatológicas, imunohistoquímicas e biomecânicas foram realizadas 15, 30 e 60 dias após a implantação. Os scaffolds apresentaram estruturas altamente porosas (porosidade de ~75%) e interconectadas, e o biovidro precursor mineralizou uma camada de hidroxicarbonatoapatita (HCA) em SBF (simulated body fluid) após o curto período de 12 h. A incubação em PBS indicou que as fibras do scaffold apresentaram sinais de degradação com o passar do tempo. Sobre os testes biológicos, o novo biomaterial levou a um aumento da proliferação de fibroblastos e osteoblastos, e nenhum dano ao DNA foi observado. Os experimentos de implantação do material no subcutâneo indicaram degradação do biomaterial acompanhada do crescimento interno de tecido mole e presença de células gigantes multinucleadas ao redor do implante. Após 60 dias, os scaffolds estavam quase completamente absorvidos e um tecido de granulação organizado preenchia a área de implantação. Adicionalmente, as análises histológicas dos scaffolds em defeitos ósseos revelaram uma degradação progressiva do biomaterial e substituição do mesmo por tecido de granulação e tecido ósseo neoformado. A histomorfometria mostrou uma maior quantidade de osso neoformado no grupo controle (CG) comparado ao grupo biomaterial (BG) 15 dias após a cirurgia. No entanto, depois de 30 e 60 dias, CG e BG apresentaram quantidades similares de osso neoformado. Além disso, o novo biomaterial aumentou a expressão de RUNX-2 e RANK-L, e também melhorou as propriedades mecânicas do calo tibial 15 dias após a cirurgia. Os resultados indicam que o novo scaffold vítreo fibroso é bioativo, não-citotóxico, biocompatível e promissor para utilização na engenharia do reparo ósseo.
42

Desenvolvimento de um compósito zircônia/vidro bioativo e estudo de filmes finos de sílica micro padronizada contendo nanohidroxiapatita aplicados sobre a zircônia / Develompment of a zirconia composite/bioativo glass and study of micropatterned silica thin films containing nanohydroxiapatite applied to zirconia

Ranulfo Benedito de Paula Miranda 11 May 2018 (has links)
Capítulo 1. A investigação teve como objetivo desenvolver filmes finos de sílica micropadronizada (FFSM) contendo micro-agregados de nanohidroxiapatita (nanoHA) que não ficassem totalmente cobertos pela sílica e assim pudessem interagir diretamente com as células vizinhas e o objetivo específico foi avaliar o efeito da presença de dois filmes (FFSM com ou sem a adição de nanohidroxiapatita) na resistência característica (?0) e no módulo de Weibull (m) de uma Y-TZP. Processamento sol-gel e litografia foram usados para aplicar o FFSM sobre os espécimes de Y-TZP. Três grupos experimentais foram produzidos: Y-TZP, Y-TZP+FFSM e Y-TZP+FFSM+nanoHA borrifada. Todas as superfícies foram caracterizadas por MEV/EDS e testadas em resistência à flexão em quatro pontos (n=30) em água a 37°C. A análise de Weibull foi usada para determinar ?0 e m (método de probabilidade máxima). A Y-TZP foi recoberta com êxito com o FFSM e FFSM+nanoHA. Micrografias indicaram que os micro-agregados de nanoHA não foram totalmente cobertos pela sílica. Não houve diferença estatisticamente significativa entre os grupos experimentais para ?0 e m. Essa investigação obteve sucesso em produzir filmes finos de sílica micropadronizada contendo micro-agregados de nanoHA que permaneceram expostos ao meio ambiente. Os filmes desenvolvidos não prejudicaram a confiabilidade estrutural da Y-TZP comercial, como confirmado pela estatística de Weibull. Capítulo 2. Objetivos: avaliar o efeito da concentração de vidro bioativo (VB), de zero e 10% em massa e da temperatura de sinterização (1.200°C e 1.300°C) na microestrutura, densidade relativa e resistência à flexão do compósito Y-TZP/VB. Material e métodos: os pós de Y-TZP e Y-TZP/VB foram prensados uniaxialmente e sinterizados a 1.200°C e 1.300°C por 1 hora. A microestrutura foi caracterizada pela análise de difração de raios X, microscopia eletrônica de varredura e espectroscopia de energia dispersiva (EDS). A densidade relativa foi calculada por meio dos valores de densidade obtidos pelo princípio de Archimedes. Para a resistência à flexão, espécimes (n=6) foram fraturados no teste de resistência à flexão biaxial usando um dispositivo de pistão sobre 3 esferas em uma máquina universal de ensaios. Resultados: a adição de VB diminuiu o tamanho de grão do compósito, aumentou as porosidades e causou uma diminuição significativa na densidade relativa (Y-TZP/1.300°C=97,7%a; Y-TZP/1.200°C=91,1%b; Y-TZP/VB/1.300°C 79,7%c e Y-TZP/VB/1.200°C 77,4%d) e diminuiu também significativamente a resistência à flexão (em MPa, Y-TZP/1.300°C=628,3a; Y-TZP/1.200°C=560,8b; Y-TZP/VB=1.300°C=189,1c e Y-TZP/VB/1.200°C=153,0c). As fases cristalinas de zircônia cúbica estabilizada por cálcio e silicato de sódio zircônio foram formadas após a adição de VB. Conclusão: a adição de vidro bioativo na Y-TZP aumentou a porosidade e resultou na formação de zircônia cúbica estabilizada com cálcio e silicato de sódio zircônio. A adição de vidro também resultou na diminuição do tamanho de grão, densidade e resistência à flexão. Os espécimes sinterizados a 1.300°C mostraram valores de densidade superior e grãos maiores quando comparados ao grupo sinterizado a 1.200°C. / Chapter 1. This investigation aimed at developing micropatterned silica thin films (MSTF) containing nanoHA micro-aggregates that were not completely covered by silica so that they could directly interact with the surrounding cells and the specific objectives was to evaluate the effect of the presence of two films (MSTF with or without nanoHA addition) on the characteristic strength (?0) and Weibull modulus (m) of a Y-TZP. Sol-gel process and soft-lithography were used to apply the MSTF onto the Y-TZP specimens. Three experimental groups were produced: Y-TZP, Y-TZP+MSTF and Y-TZP+MSTF+sprayed nanoHA. All surfaces were characterized by SEM/EDS and tested for four-point flexural strength (n=30) in water at 37°C. Weibull analysis was used to determine m and ?0 (maximum likelihood method). Y-TZP was successfully coated with MSFT and MSFT+nanoHA. SEM micrographs indicated that the micro-aggregates of nanoHA were not entirely covered by the silica. There was no statistically significant difference among the experimental groups for ?0 and m. This investigation was successful in producing a micropatterned silica thin film containing nanoHA micro-aggregates that remained exposed to the environment. The developed films did not jeopardize the structural reliability of a commercial Y-TZP, as confirmed by the Weibull statistics. Chapter 2. Objectives: to evaluate the effect the bioactive glass (BG) concentration (0 and 10wt%) and the sintering temperature (1.200°C and 1.300°C) on the microstructure, relative density and flexural strength of the composite Y-TZP/BG. Methods: The Y-TZP and Y-TZP/BG powders were uniaxially pressed and sintered at 1.200°C or 1.300°C for 1 h. The microstructure was characterized by X-ray diffraction analysis, scanning electron microscopy and Energy Dispersive X-ray Spectroscopy. Relative density was calculated from density values obtained using the Archimedes\' principle. For the flexural strength, specimens (n=6) were fractured in a biaxial flexural setup using a piston-on-3-balls fixture in a universal testing machine. Results: BG addition decreased the grain size of the composite, increased porosity and caused a significant decrease in the relative density (Y-TZP/1.300°C=97.7%a; Y-TZP/1.200°C=91.1%b; Y-TZP/BG/1.300°C 79.7%c and Y-TZP/BG/1.200°C 77.4%d) and flexural strength (in MPa, Y-TZP/1.300°C=628.3a; Y-TZP/1.200°C=560.8b; Y-TZP/BG=1.300°C=189.1c and Y-TZP/BG/1.200°C=153.0c). The crystalline phases of calcium stabilized cubic zirconia and sodium zirconium silicate were formed after the addition of BG. Conclusion: Addition of bioactive glass to Y-TZP increased porosity and resulted in the formation of calcium stabilized cubic zirconia and sodium zirconium silicate. Also, glass addition resulted in decrease in grain size, density and flexural strength. Composite specimens sintered at 1.300°C showed the highest density values and larger grains compared to those sintered at 1.200°C
43

Expressão dos fenótipos fibroblástico e osteoblástico em culturas tridimensionais na presença de partículas de vidro bioativo / Osteoblastic and fibroblastic phenotypes expression on three dimensional cell cultures in the presence of bioactive glass particles

Luciana Bastos Alves 05 October 2012 (has links)
O objetivo deste estudo foi analisar a expressão dos fenótipos fibroblástico e osteoblástico em culturas tridimensionais na presença ou não de partículas de vidro bioativo. Fibroblastos derivados do ligamento periodontal humano (hPDLF) e células osteogênicas da calvária de rato recém-nascidos foram plaqueadas em superfícies bidimensionais - lamínulas de plástico ThermanoxTM (controle); superfícies colágenas bidimensionais - ThermanoxTM revestidas por colágeno I sem partículas de vidro bioativo (2D) e com partículas de vidro bioativo (2D+VB); e em gel colágeno tridimensional sem vidro bioativo (3D) e com partículas (3D+VB). Foram avaliados: Viabilidade celular (MTT) nos tempos 3, 7 e 10 dias; Atividade de fosfatase alcalina (ALP) normalizada pelo conteúdo de proteína total em 7 e 14 dias; Immunolocalização de proteínas da matriz não-colágena (ALP e OPN em células hPDLF aos 7 e 14 dias e OPN e BSP em células osteogênicas aos 7 dias) por imunofluorescência indireta; Expressão quantitativa (PCR em tempo real) dos genes Periostina (PRT), Calcium-Binding Protein (S100A4) e Fibromodulina (FBM), marcadores do fenótipo fibroblástico, em células hPDLF e Fosfatase Alcalina (ALP), Osteopontina (OPN), Sialoproteína Óssea (BSP), Osteocalcina (OC), Colágeno I (COL I) e Runx2, marcadores osteoblásticos, em ambos os tipos celulares; e Mineralização (coloração por vermelho de Alizarina). Os resultados obtidos nas culturas de hPDLF mostraram que aos 3 dias a viabilidade celular em 2D+VB foi maior que no controle (p<0,05) e nenhuma diferença significante entre os grupos foi observada aos 7 e 10 dias. O conteúdo de proteína total aos 7 e 14 dias foi maior nas culturas 3D e 3D+VB, sendo aos 7 dias significantemente diferente de 2D+VB (p<0,05) e controle (p<0,05) e aos 14 dias observou-se diferença significativa entre 3D e 2D. A atividade de ALP aos 7 dias foi maior nos grupos 2D e 2D+VB comparados com 3D (p<0,05) e 3D+VB (p<0,05); e em 3D+VB menor que no controle (p<0,05). Entretanto, aos 14 dias 3D e 3D+VB apresentaram maior atividade de ALP que o controle (p<0,05). Imunomarcações para OPN e ALP foram observadas nas células em 3D em ambos os períodos avaliados, e em 2D, 2D+VB, e controle apenas aos 14 dias. A expressão de RNAm para PRT aos 7 dias apresentou um perfil upregulated em 3D e 3D+VB comparados ao controle (p<0,05); para FBM a expressão gênica foi maior em 3D e 2D que em 3D+VB (p<0,05), e menor em 3D+VB comparado ao controle (p<0,05). As células em 2D exibiram maiores níveis de expressão de RNAm para S100A4 que as cultivadas em 2D+VB (p<0,05) e controle (p<0,05). Os níveis de RNAm para COL I e ALP em 2D+VB e 3D, para RUNX2 e OPN em 3D e 2D, e para OC em 2D apresentaram-se upregulated em relação ao controle (p<0,05). Em 2D o nível de expressão de OC foi maior que em 2D+VB (p<0,05). Aos 14 dias houve uma diminuição da expressão de todos os genes analisados em relação às análises de 7 dias. Células em 3D+VB expressaram menores níveis de PRT que em 2D+VB (p<0,05). A expressão de RNAm para FBM foi maior em 2D e 2D+VB e para S100A4 maior em 2D comparado com 3D (p<0,05), nos quais os níveis de S100A4 ficaram downregulated com relação ao controle. COL I e ALP apresentaram-se downregulated em 3D (p<0,05) e 3D+VB (p<0,05) em relação ao controle. Entre 2D+VB e 3D+VB também foi observada diferença significativa para ALP. A expressão de RUNX2 foi maior em 3D que em 3D+VB (p<0,05) e de OC maior no controle. Nos grupos com VB foi observada maior formação de matriz calcificada aos 10 e 14 dias. Aos 10 dias não foram observadas áreas coradas por Alizarina através da microscopia, mas a quantidade de mineralização em 2D+VB e 3D+VB foi significativamente maior que no controle (p<0,05), 2D (p<0,05) e 3D (p<0,05). Aos 14 dias marcações mais extensas foram observadas nas culturas com VB, porém os nódulos mineralizados apresentavam-se independentes das partículas. 2D+VB e 3D+VB foram significativamente diferentes do controle (p<0,05) e 2D (p<0,05). As culturas de células osteogênicas mostraram que aos 7 dias as células crescidas sobre os arcabouços 3D+VB e 3D exibiram menores índices de viabilidade. Diferenças significativas foram observadas quando 3D+VB foi comparado aos grupos 2D+VB (p<0,05) e controle (p<0,05); e entre 2D e 3D (p<0,05). Aos 3 e 10 dias não foram encontradas diferenças significativas na viabilidade celular entre os grupos. O conteúdo de proteína total foi maior em 3D+VB que em 2D+VB (p<0,05) e no controle (p<0,05) aos 7 e 14 dias. Diferenças significantes também foram observadas entre 3D e 2D (p<0,05) aos 14 dias. A atividade de ALP aos 7 dias foi maior em 2D+VB e 3D+VB. Diferenças significantes foram encontradas entre 2D e 2D+VB (p<0,05), 3D e 3D+VB (p<0,05) e entre 3D e controle (p<0,05). Entretanto, aos 14 dias, 3D e 3D+VB apresentaram os menores valores de atividade de ALP, sendo a significantemente diferentes de 2D (p<0,05) e 2D+VB (p<0,05). Imunomarcações para OPN e BSP foram observadas aos 7 dias em 2D, 2D+VB, 3D e controle. Aos 7 dias os níveis expressão do RNAm para ALP, COL I e RUNX2 foram maiores em 3D e 3D+VB. Os genes OPN, OC e BSP exibiram níveis de expressão mais altos em 2D+VB. A expressão de COL I foi maior em 3D+VB que em 2D+VB (p<0,05). As células em 2D+VB apresentaram maiores níveis de expressão de OPN e OC que em 2D (p<0,05) e 3D+VB (p<0,05), nos quais a expressão desses genes e de BSP estavam downregulated em relação ao grupo controle. Aos 10 e 14 dias áreas coradas por vermelho de Alizarina foram observadas em todos os grupos, sendo mais extensas nos grupos que continham VB. Aos 10 dias a quantidade de cálcio em 3D+VB foi maior que no controle (p<0,05); e maior em 2D+VB comparado com 2D (p<0,05) e controle (p<0,05). Aos 14 dias 2D+VB e 3D+VB apresentaram uma quantidade de cálcio significativamente maior que no controle (p<0,05) e em 2D (p<0,05). Em conclusão, este estudo demonstrou que os arcabouços tridimensionais colágenos são capazes de suportar a viabilidade, proliferação e diferenciação celular se in vitro de hPDLF e células osteogênicas derivadas de calvária de rato recém-nascidos e de favorecerem a expressão dos fenótipos fibroblástico e osteoblástico em hPDLF. As partículas de VB em ambos os tipos celulares também contribuiram para viabilidade, diferenciação, formação de matriz mineralizada e expressão fenotípica. / The aim of this study was to analyze the fibroblastic and osteoblastic phenotypes expression on three-dimensional cultures in the presence or not of bioactive glass particles. Fibroblasts derived from human periodontal ligament (hPDLF) and osteogenic cells from newborn rat calvaria were cultured on bi-dimensional surfaces - plastic coverslips ThermanoxTM (control), bi-dimensional collagen surfaces - ThermanoxTM coated with collagen I without bioactive glass particles (2D) and with bioactive glass particles (2D+BG), on three-dimensional collagen gel without bioactive glass (3D) and with particles (3D+BG). Were evaluated: Cell viability (MTT) in 3 days, 7 and 10 days; Phosphatase alkaline activity (ALP) normalized by total protein content at 7 and 14 days; Immunolocalization of non-matrix proteins collagen (ALP and OPN in hPDLF at 7 and 14 days, OPN and BSP in osteogenic cells at 7 days) by indirect immunofluorescence; Genes expression (real-time PCR) for Periostin (PRT), Calcium-Binding Protein (S100A4) and Fibromodulin (FBM): fibroblastic markers in hPDLF, and Alkaline phosphatase (ALP), Osteopontin (OPN), Bone sialoprotein (BSP), Osteocalcin (OC), Collagen I (COL I) and RUNX2: osteoblastic markers in both cell types; and Mineralization (staining with Alizarin red). The results obtained on hPDLF cultures showed that cell viability on 2D+BG was higher than on control at 3 days (p<0.05), and no significant difference between groups was observed at 7 and 10 days. The total protein content at 7 and 14 days was higher on 3D and 3D+BG cultures compared those on 2D+BG (p<0.05) and control (p<0.05) at 7 days. Significant difference was also observed between 3D and 2D at 14 days. The ALP activity at 7 days was higher on 2D and 2D+BG compared with 3D (p<0.05) and 3D+BG (p<0.05), it was also lower on 3D+BG than on control (p<0.05). However, at 14 days 3D and 3D+BG showed higher ALP activity than control (p<0.05). Immunolabeling for OPN and ALP were observed in cells on 3D at both periods and on 2D, 2D+ BG and control only at 14 days. At 7 days, the expression of mRNA for PRT was upregulated on 3D and 3D+BG compared with control (p<0.05), for the FBM it was higher on 3D and 2D than on 3D+BG (p<0,05), but it was lower on 3D+BG than on control (p<0.05). Cells on 2D exhibited higher levels of S100A4 mRNA expression than those grown on 2D+BG (p<0.05) and control (p<0.05). The mRNA levels expression for COL I and ALP on 2D+BG and 3D, and for RUNX2 and OPN on 3D and 2D, and for OC on 2D presented upregulated compared with control (p<0.05). Also, cells on 2D showed the level expression of OC higher than those on and 2D+BG (p<0.05). At 14 days, there was a decrease in all evaluated genes expression compared with 7 days analyses. Cells on 2D+BG expressed higher levels of PRT than on 3D+BG (p<0.05). 2D and 2D+BG showed the highest levels of mRNA expression for FBM. Gene expression of S100A4 on 2D was higher than on 3D (p<0.05) and 3D+BG (p<0.05), in which the levels of S100A4 were downregulated compared to control. COL I and ALP were downregulated on 3D (p<0.05) and on 3D+BG (p<0.05) compared with control. There was also a significant difference between 2D+BG and 3D+BG for mRNA ALP expression. RUNX2 expression was higher on 3D than on 3D+BG (p<0.05), and OC expression was higher on control. Calcified matrix formation was observed on BG cultures at 10 and 14 days. At 10 days, areas stained by Alizarin were no observed by microscopy, but the amount of mineralization on 2D+BG and 3D+BG was significantly higher than on control (p<0.05), 2D (p<0.05) and 3D (p<0.05). At 14 days, more extensive staining was observed on cultures with BG, but the mineralized nodules formation was independent of the particles. Calcium content on 2D+BG and 3D+BG was significantly higher than control (p<0.05) and 2D (p<0.05). Osteogenic cell cultures showed that cells grown on 3D and 3D+BG surfaces exhibited the lowest levels of cell viability. Significant differences were observed when 3D+BG was compared with 2D+BG (p<0.05) and control (p<0.05) and also between 2D and 3D (p<0.05). At 3 and 10 days, there were no significant differences for cell viabililty between the cultures. The total protein content was higher on 3D+BG than on the control (p<0.05) and 2D+BG (p<0.05) at 7 and 14 days. Significant differences were also observed between 3D and 2D (p<0.05) at 14 days. ALP activity at 7 days was higher on 2D+BG and 3D+BG. Significant differences were found between 2D and 2D+BG (p<0.05), 3D and 3D+BG (p<0.05), and between 3D and control (p<0.05). However, at 14 days 3D and 3D+BG had the lowest levels of ALP activity, significantly different from 2D (p<0.05) and 2D+BG (p<0.05). Immunolabeling for OPN and BSP were observed at 7 days on 2D, 2D+BG, 3D and control. At 7 days, the expression levels of mRNA for ALP, COL I and RUNX2 were higher on 3D and 3D+BG. OPN, BSP and OC exhibited higher expression levels on 2D+BG. COL I expression was higher on 3D+BG than on 2D+BG (p<0.05). Cells on 2D+BG showed higher expression levels of OPN and OC than those on 2D (p<0.05) and 3D+BG (p<0.05), in which both of these genes and BSP expression were downregulated compared with control. At 10 and 14 days areas stained with Alizarin red were observed all evaluated groups, especially on BG cultures. At 10 days the amount of calcium on 3D+BG was higher than on control (p<0.05), and it was also higher on 2D+BG compared with 2D (p<0.05) and control (p<0.05). At 14 days, 2D+BG and 3D+BG showed greater calcium amount than control (p<0.05) and 2D (p<0.05). In conclusion, this study demonstrated that in vitro 3D cultures of hPDLF and osteogenic cells from newborn rats calvaria were able of support cell viability, differentiation, and to contribute to expression of fibroblastic and osteoblastic phenotype in hPDLF. The BG particles also favored the viability, differentiation, mineralized matrix formation and phenotypic expression in both cell types.
44

Effects of Transition Metal Oxide and Mixed-Network Formers on Structure and Properties of Borosilicate Glasses

Lu, Xiaonan 12 1900 (has links)
First, the effect of transition metal oxide (e.g., V2O5, Co2O3, etc.) on the physical properties (e.g., density, glass transition temperature (Tg), optical properties and mechanical properties) and chemical durability of a simplified borosilicate nuclear waste glass was investigated. Adding V2O5 in borosilicate nuclear waste glasses decreases the Tg, while increasing the fracture toughness and chemical durability, which benefit the future formulation of nuclear waste glasses. Second, structural study of ZrO2/SiO2 substitution in silicate/borosilicate glasses was systematically conducted by molecular dynamics (MD) simulation and the quantitative structure-property relationships (QSPR) analysis to correlate structural features with measured properties. Third, for bioactive glass formulation, mixed-network former effect of B2O3 and SiO2 on the structure, as well as the physical properties and bioactivity were studied by both experiments and MD simulation. B2O3/SiO2 substitution of 45S5 and 55S5 bioactive glasses increases the glass network connectivity, correlating well with the reduction of bioactivity tested in vitro. Lastly, the effect of optical dopants on the optimum analytical performance on atom probe tomography (APT) analysis of borosilicate glasses was explored. It was found that optical doping could be an effective way to improve data quality for APT analysis with a green laser assisted system, while laser spot size is found to be critical for optimum performance. The combined experimental and simulation approach adopted in this dissertation led to a deeper understanding of complex borosilicate glass structures and structural origins of various properties.
45

Synthesis and Evaluation of a Zn-Bioactive Glass Series to Prevent Post-Operative Infections in Craniofacial Applications

Raghuraman, Kapil 21 December 2018 (has links)
No description available.
46

Preparation of PVA / Bioactive Glass nanocomposite scaffolds : in vitro studies for applications as biomaterials : association with active molecule / Préparation du PVA / verre bioactif échafaudages nanocomposites : des études in vitro pour des applications en tant que biomatériaux : association avec molécule active

Mabrouk Mohamed, Mostafa 11 June 2014 (has links)
Le Poly Vinyl Alcohol (PVA) a été associé aux verres élaborés dans un système quaternaire (BG) 46S6 par les procédés cités (fusion, sol-gel et sacffolds). Différents paramètres intervenant dans les synthèses des verres bioactifs ont été étudiés, nous citons à titre d’exemple : la température, le pH, la taille des particules, le rapport Polymère / verres, la microstructure, la porosité et la biodégradation. Les caractéristiques thermiques des verres élaborés ont été également déterminées après chaque synthèse par analyse thermique différentielle (DSC/TG, DTA/TG). Ainsi, la température de fusion, la température de transition vitreuse et la température de cristallisation ont été élucidées. Ces caractéristiques thermiques changent lorsque la composition chimique du verre est modifiée. A ce titre, les compositions chimiques ont été étudiées par Fluorescence (XRF) et Inductively Coupled Plasma-Opticale Emission Spectroscopy (ICP-OES) après chaque synthèse pour s’assurer de la pureté des verres bioactifs élaborés et destinés à des applications médicales. Plusieurs techniques physico chimiques d’analyses (DRX, MEB, MET, FT-IR, XRF, ICPOES) ont été mises en oeuvre pour déterminer les propriétés physico chimiques de nos verres bioactifs avant et après expérimentations « in vitro ». Le nano composite Polymère-Verres scaffolds que nous avons obtenu présente des particules de tailles comprises entre 40 et 61 nm et une porosité d’environ 85%. La biodégradation des verres scaffolds décroît lorsque la teneur en verre scaffolds dans le nano composite croît. Les expérimentations « in vitro » montrent qu’après immersion de ces nano composites dans un liquide physiologique synthétique (SBF), une couche d’apatite (phosphate de calcium) se forme à leur surface. L’épaisseur de la couche formée dépend clairement de la taille des particules et du rapport polymère / verre scaffolds. / The aim of the present work is the preparation of Bioactive Glass (BG) 46S6 by different techniques. Fabrication of composite scaffolds by using of Poly Vinyl Alcohol (PVA) and quaternary BG (two methods melting and sol-gel) with different ratios to the prepared scaffolds was carried out. Different factor affecting the final properties of the prepared composite scaffolds were investigated in this study, such as; temperature of treatment, BG particle size, polymer/glass ratio, microstructure, porosity, biodegradation, bioactivity, and drug release. The thermal behavior of the prepared bioactive glass by sol-gel and melting techniques were identified using Differential Scanning Calorimetric/Thermo Gravimetric (DSC/TG) or Differential Thermal Analysis/Thermo Gravimetric (DTA /TG). The elemental composition of the prepared bioactive glasses was determined by X-rays Fluorescence (XRF) to confirm that the prepared bioactive glasses have the same elemental compositions and high purity for biomedical applications. The particle size of the prepared bioactive glass was determined by Transmission Electron Microscopic (TEM). Nano-bioactive glass could be obtained by modified sol-gel and the obtained particle size ranged between 40 to 61 nm. The prepared bioactive glass by both applied methods has the same amorphous phase and all identified groups as well as. The porous scaffold has 85% porosity with a slight decrease by increasing the glass contents. The degradation rate decreased by increasing of glass content in the prepared scaffolds. The bioactivity of the prepared composite scaffolds was evaluated by XRD, FTIR, SEM coupled with EDX and Inductively Coupled Plasma-Optical Emission Spectroscopic (ICP-OES). It has been observed that after soaking in Simulated Body Fluid (SBF), there was an apatite layer formed on the surface of the prepared samples with different thickness depending on the glass particle size and polymer/glass ratio.
47

Composite Bioinks With Mesoporous Bioactive Glasses - A Critical Evaluation of Results Obtained by In Vitro Experiments

Guduric, Vera, Wieckhusen, Johannes, Bernhardt, Anne, Ahlfeld, Tilman, Lode, Anja, Wu, Chengtie, Gelinsky, Michael 04 April 2024 (has links)
Besides osteoconductivity and a high degradation rate, mesoporous bioactive glasses (MBGs) are specific for their highly ordered channel structure and high specific surface area, making them suitable as drug and/or growth factor delivery systems. On the other hand, the mesoporous channel structure and MBG composition can have an effect on common cell evaluation assays, leading to inconclusive results. This effect is especially important when MBG is mixed in composite bioinks, together with cells. Additionally, the hydrogel component of the ink can influence the degradation of MBG, leading to different ion releases, which can additionally affect the analyses. Hence, our aim here was to show how the MBG structure and composition influence common cell viability and differentiation assays when calcium (Ca)- or magnesium (Mg)-containing glass is part of an alginate-based composite bioink. We suggested pre-labeling of cells with DiI prior to bioprinting and staining with calcein-AM to allow identification of metabolically active cells expressing signals in both green and red channels, allowing the use of fluorescence imaging for cell viability evaluations in the presence of high amounts (7 wt %) of MBGs. The release and uptake of ions during degradation of CaMBG and MgMBG were significantly changed by alginate in the composite bioinks, as confirmed by higher release and uptake from bulk glasses. Additionally, we detected a burst release of Mg²⁺ from composites only after 24 h of incubation. Furthermore, we demonstrated that released ions and the mesoporous channel structure affect the measurement of lactate dehydrogenase (LDH) and alkaline phosphatase activity (ALP) in bioprinted composite scaffolds. Measured LDH activity was significantly decreased in the presence of CaMBG. On the other hand, the presence of MgMBG induced increased signal measured for the ALP. Taken together, our findings show how composite bioinks containing MBGs can interfere with common analyses, obtaining misleading results.
48

Análise in vitro da morfologia superficial de uma nova formulação de biovidro associado ao laser de Nd:YAG e laser de CO2 sobre dentina humana / In vitro analysis of the surface morphology of a new bioglass formulation associated with Nd: YAG laser and CO2 laser on human dentin

Lee, Ester Mi Ryoung 13 June 2017 (has links)
Dentre as opções de terapias dessensibilizantes, a proposta mais recente para o tratamento da Hipersensibilidade Dentinária é o uso do biovidro. Esse novo material apresenta a capacidade de promover a formação de hidroxiapatita na superfície da dentina, representando uma união química mais estável e duradoura sobre os túbulos dentinários. Este trabalho comparou o efeito de uma nova formulação de biovidro disperso em ácido fosfórico 30%, associado ao laser de Nd:YAG e ao laser de CO2 na obliteração de túbulos dentinários expostos. Foram obtidas 96 amostras de dentina humana que foram divididas em 6 grupos experimentais (n=16) e distribuídas como a seguir: G1 -­ controle negativo (nenhum tratamento adicional);? G2 -­ laser de Nd:YAG;? G3 -­ laser de CO2;? G4 -­ pasta de biovidro (biovidro + ácido fosfórico 30%);? G5 -­ pasta de biovidro + laser de Nd:YAG;? G6 -­ pasta de biovidro + laser de CO2. Os grupos G5 e G6 foram irradiados com laser de Nd:YAG e laser de CO2, respectivamente, após tratamento com a pasta de biovidro disperso em ácido fosfórico. Ao final do experimento, os grupos foram analisados qualitativamente por Espectroscopia de Infravermelho na Transformada de Fourier (FTIR), Difração de Raios X (DRX), Microscopia Eletrônica de Varredura (MEV) e Espectroscopia de Dispersão de Energia de Raios X (EDS). As análises evidenciaram que a dipersão do biovidro em ácido fosfórico 30% é capaz de formar cristais de hidrogenofosfato de cálcio e, quando a pasta formulada é aplicada sobre a dentina, ocorrem reações químicas com a estrutura dental, formando cristais de monetita. Ao irradiar os cristais formados com laser de Nd:YAG e CO2, ocorreu a desidratação desses cristais, levando à formação de hidroxiapatita. As imagens de MEV demonstram a formação de precipitados cristalinos e amorfos de dimensões variadas sobre a superfície de dentina e na entrada dos túbulos dentinários em todos os grupos que receberam o tratamento com a formulação de biovidro. O laser de CO2 foi capaz de promover alterações na morfologia do material formado de maneira ainda mais evidente especialmente nas dimensões e disposição dos cristais de hidroxiapatita formado sobre a superfície. A análise de EDS evidenciou presença de silício, composto que não está presente naturalmente na estrutura dentária, mas somente na composição do biovidro. Dessa forma, pode-­se concluir que a associação do pó de biovidro com ácido fosfórico 30% permitiu a formação de uma camada de cristais na superfície e entrada dos túbulos dentinários, evidenciando que a pasta formulada viabiliza a aplicação e manutenção do biovidro sobre a superfície dentinária. Sua associação com o laser de Nd:YAG e CO2 parece melhorar a interação desses cristais com a dentina, formando cristais de hidroxiapatita. Nesse estudo, o laser de CO2 promoveu a melhor distribuição e conformação dos cristais sobre a dentina. / Among desensitizing therapies options, the most recent proposal for Dentin Hypersensitivity treatment is the use of bioglass. This new material presents the ability to promote the formation of hydroxyapatite on dentin surface, representing a more stable and lasting chemical bond on dentin tubules. This work compared the effect of a new formulation of bioglass dispersed in 30% phosphoric acid, associated with Nd: YAG laser and CO2 laser in the obliteration of exposed dentin tubules. 96 human dentin samples were obtained, divided into 6 experimental groups (n = 16) and distributed as follows: G1 -­ negative control (no additional treatment);? G2-­ Nd: YAG laser;? G3 - CO2 laser;? G4 -­ bioglass paste (bioglass + 30% phosphoric acid);? G5 -­ bioglass paste + Nd: YAG laser;? G6 -­ bioglass paste + CO2 laser. Groups G5 and G6 were irradiated with Nd:YAG laser and CO2 laser, respectively, after treatment with the slurry dispersed in phosphoric acid. At the end of the experiment, all groups were qualitatively analyzed by Fourier Transform Infrared Spectroscopy (FTIR), X-­ray Diffraction (XRD), Scanning Electron Microscopy (SEM) and X-­ray Energy Dispersion Spectroscopy (EDS). The analysis showed that the dispersion of bioglass in 30% phosphoric acid forms calcium hydrogen phosphate crystals and when the formulated paste is applied on dentin surface, chemical reactions occur with the dental structure, forming monetite crystals. When irradiating these crystals with Nd: YAG and CO2 laser, dehydration of these crystals occurred leading to the formation of hydroxyapatite. MEV images demonstrate the formation of crystalline and amorphous precipitates of varying dimensions on the dentin surface and at the entrance of dentinal tubules in all groups receiving treatment with the bioglass formulation. The CO2 laser was able to promote changes in the morphology of the formed material even more evident especially in the dimension and arrangement of hydroxyapatite crystals formed on the surface. The analysis of EDS showed the presence of silicon, a compound that is not naturally present in the tooth structure, but only in the bioglass composition. Thus, it can be concluded that the association of bioglass powder with 30% phosphoric acid allowed the formation of a layer of crystals on the surface and its entrance of the dentinal tubules, evidencing that the formulated paste enables the application and maintenance of bioglass on dentin surface. Its association with the Nd:YAG and CO2 laser seems to improve the interaction of these crystals with dentin, forming hydroxyapatite crystals. In this study. CO2 laser promoted better crystals distribution and conformation on dentin surface.
49

Análise in vitro da morfologia superficial de uma nova formulação de biovidro associado ao laser de Nd:YAG e laser de CO2 sobre dentina humana / In vitro analysis of the surface morphology of a new bioglass formulation associated with Nd: YAG laser and CO2 laser on human dentin

Ester Mi Ryoung Lee 13 June 2017 (has links)
Dentre as opções de terapias dessensibilizantes, a proposta mais recente para o tratamento da Hipersensibilidade Dentinária é o uso do biovidro. Esse novo material apresenta a capacidade de promover a formação de hidroxiapatita na superfície da dentina, representando uma união química mais estável e duradoura sobre os túbulos dentinários. Este trabalho comparou o efeito de uma nova formulação de biovidro disperso em ácido fosfórico 30%, associado ao laser de Nd:YAG e ao laser de CO2 na obliteração de túbulos dentinários expostos. Foram obtidas 96 amostras de dentina humana que foram divididas em 6 grupos experimentais (n=16) e distribuídas como a seguir: G1 -­ controle negativo (nenhum tratamento adicional);? G2 -­ laser de Nd:YAG;? G3 -­ laser de CO2;? G4 -­ pasta de biovidro (biovidro + ácido fosfórico 30%);? G5 -­ pasta de biovidro + laser de Nd:YAG;? G6 -­ pasta de biovidro + laser de CO2. Os grupos G5 e G6 foram irradiados com laser de Nd:YAG e laser de CO2, respectivamente, após tratamento com a pasta de biovidro disperso em ácido fosfórico. Ao final do experimento, os grupos foram analisados qualitativamente por Espectroscopia de Infravermelho na Transformada de Fourier (FTIR), Difração de Raios X (DRX), Microscopia Eletrônica de Varredura (MEV) e Espectroscopia de Dispersão de Energia de Raios X (EDS). As análises evidenciaram que a dipersão do biovidro em ácido fosfórico 30% é capaz de formar cristais de hidrogenofosfato de cálcio e, quando a pasta formulada é aplicada sobre a dentina, ocorrem reações químicas com a estrutura dental, formando cristais de monetita. Ao irradiar os cristais formados com laser de Nd:YAG e CO2, ocorreu a desidratação desses cristais, levando à formação de hidroxiapatita. As imagens de MEV demonstram a formação de precipitados cristalinos e amorfos de dimensões variadas sobre a superfície de dentina e na entrada dos túbulos dentinários em todos os grupos que receberam o tratamento com a formulação de biovidro. O laser de CO2 foi capaz de promover alterações na morfologia do material formado de maneira ainda mais evidente especialmente nas dimensões e disposição dos cristais de hidroxiapatita formado sobre a superfície. A análise de EDS evidenciou presença de silício, composto que não está presente naturalmente na estrutura dentária, mas somente na composição do biovidro. Dessa forma, pode-­se concluir que a associação do pó de biovidro com ácido fosfórico 30% permitiu a formação de uma camada de cristais na superfície e entrada dos túbulos dentinários, evidenciando que a pasta formulada viabiliza a aplicação e manutenção do biovidro sobre a superfície dentinária. Sua associação com o laser de Nd:YAG e CO2 parece melhorar a interação desses cristais com a dentina, formando cristais de hidroxiapatita. Nesse estudo, o laser de CO2 promoveu a melhor distribuição e conformação dos cristais sobre a dentina. / Among desensitizing therapies options, the most recent proposal for Dentin Hypersensitivity treatment is the use of bioglass. This new material presents the ability to promote the formation of hydroxyapatite on dentin surface, representing a more stable and lasting chemical bond on dentin tubules. This work compared the effect of a new formulation of bioglass dispersed in 30% phosphoric acid, associated with Nd: YAG laser and CO2 laser in the obliteration of exposed dentin tubules. 96 human dentin samples were obtained, divided into 6 experimental groups (n = 16) and distributed as follows: G1 -­ negative control (no additional treatment);? G2-­ Nd: YAG laser;? G3 - CO2 laser;? G4 -­ bioglass paste (bioglass + 30% phosphoric acid);? G5 -­ bioglass paste + Nd: YAG laser;? G6 -­ bioglass paste + CO2 laser. Groups G5 and G6 were irradiated with Nd:YAG laser and CO2 laser, respectively, after treatment with the slurry dispersed in phosphoric acid. At the end of the experiment, all groups were qualitatively analyzed by Fourier Transform Infrared Spectroscopy (FTIR), X-­ray Diffraction (XRD), Scanning Electron Microscopy (SEM) and X-­ray Energy Dispersion Spectroscopy (EDS). The analysis showed that the dispersion of bioglass in 30% phosphoric acid forms calcium hydrogen phosphate crystals and when the formulated paste is applied on dentin surface, chemical reactions occur with the dental structure, forming monetite crystals. When irradiating these crystals with Nd: YAG and CO2 laser, dehydration of these crystals occurred leading to the formation of hydroxyapatite. MEV images demonstrate the formation of crystalline and amorphous precipitates of varying dimensions on the dentin surface and at the entrance of dentinal tubules in all groups receiving treatment with the bioglass formulation. The CO2 laser was able to promote changes in the morphology of the formed material even more evident especially in the dimension and arrangement of hydroxyapatite crystals formed on the surface. The analysis of EDS showed the presence of silicon, a compound that is not naturally present in the tooth structure, but only in the bioglass composition. Thus, it can be concluded that the association of bioglass powder with 30% phosphoric acid allowed the formation of a layer of crystals on the surface and its entrance of the dentinal tubules, evidencing that the formulated paste enables the application and maintenance of bioglass on dentin surface. Its association with the Nd:YAG and CO2 laser seems to improve the interaction of these crystals with dentin, forming hydroxyapatite crystals. In this study. CO2 laser promoted better crystals distribution and conformation on dentin surface.
50

Biodegradable Composites : Processing of thermoplastic polymers for medical applications.

Damadzadeh, Behzad, Jabari, Hamideh January 2009 (has links)
Despite the recent development in PLA and PLGA based medical devices, there are still needs to further improve the mechanical performance of bioresorbable medical implants and their bioactivity. This is normally done by optimizing the filler compositions in selected groups ofbiodegradable polymer matrices. In this study, the effects of various filler levels on mechanical strength and thermal properties of PLA and PLGA composites were investigated. Composites containing different dosage of osteoconductive HAp with various particles size (0-5μm, 0-50 μm, nano size), β-TCP, bioactive glass and biodegradable Poly-L-lactide and Polylactide-glycolic acid was manufactured with melt blending, using a twin-screw extruder.The samples were investigated by Differential Scanning Calorimetry (DSC), thermo gravimetric analysis (TGA), Scanning Electron Microscopy (SEM), viscometer, three points bending machine, and Optical Microscopy (OM). The Extruder produced a porous profile. The result from TGA and SEM indicated that there was homogenous filler dispersion in the matrix after compounding.The result from DSC and Viscometer shows that there was some degradation duringcompounding. Mechanical properties of composites were modified by adding filler to matrix. The addition of Bioactive glass, as a filler, increases the degradation of the polymer matrix. The best filler that was applied is 0-5μm and nano HAp. Also in in-vitro degradation part of this thesis work, the effects of calcium phosphate materialsare investigated on degradation process.

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