Global ETD Search

1	Substrate Nanotopography and Stiffness Modulation of Cell Behavior Wang, Kai 05 1900 (has links) The physical characteristics (i.e., nanostructure and stiffness) of the extracellular matrix where cells reside have been shown to profoundly affect numerous cellular events in vivo and also been employed to modulate cell behavior in vitro, yet how these physical cues regulate cell behavior is still elusive. Therefore, we engineered a variety of nanotopographies with different shapes and dimensions, and investigated how the nanotopographical cue, through focal adhesions-cytoskeleton-nucleus pathway, affected cell phenotype and function. We further designed and fabricated well-defined substrates which had either identical biochemical cue (adhesive ligand presentation) but different nanotopographical cues or identical nanotopography but different biochemical cues, and dissected the roles of these cues in cell modulation. In addition, we revealed that the human mesenchymal stem cells (hMSCs) could obtain nanotopographical memory from the past culture environment, and the nanotopographical memory influenced the future fate decision of the hMSCs. Moreover, we evaluated the effects of substrate nanotopographical and stiffness cues on the fibrogenesis of human lung fibroblasts in response to carbon nanotubes and highlighted the significance of these physical cues in the development of physiologically relevant in vitro models for nanotoxicological study. The mechanistic understanding of the physical regulation of cell behaviors will provide important insight into the advancement of cell culture technologies and the recreation of biomimetic in vitro tissue/organ models. Nanotopography Stiffness Cell modulation Stem cells Nanotoxicity
2	Investigating the Influence of Nanotopography on the Migratory State of Glioblastoma Multiforme Cells Beliveau, Alexander 28 January 2016 (has links) Glioblastoma multiforme (GBM) is an aggressive Grade IV astrocytoma with a poor survival rate. This is largely due to the GBM tumor cells migrating away from the primary tumor site along white matter tracts and blood vessels leading to secondary tumor sites. It is unknown whether the microenvironment nanotopography influences the biomechanical properties of the tumor cells. Although these tumor cells have an innate propensity to migrate, we believe that the nanotopography changes the biomechanical properties to enhance the migratory phenotype. To study this, we used an in vitro polycaprolactone aligned nanofiber film that mimics the nanotopography of the white matter tracts and blood vessels to investigate the mechanical properties of the GBM tumor cells. Our data demonstrate that the cytoskeletal stiffness, traction force, and focal adhesion area are inherently lower in invasive GBM tumor cells compared to healthy astrocytes. Moreover, the tumor cytoskeletal stiffness was significantly reduced when cultured on the aligned nanofiber films compared to smooth and randomly aligned nanofibers films. Analysis of gene expression also showed that tumor cells cultured on the aligned nanotopography upregulated key migratory genes and downregulated key proliferative genes. In addition, cell cycle analysis exhibited a reduced proliferative state on aligned nanofibers, highlighting the dichotomy between proliferation and migration observed in GBM. Finally, focal adhesions of tumor cells were larger and more elliptical when grown on the aligned fibers, suggesting a more migratory state. Therefore, our data demonstrate that the invasive potential is elevated when the tumor cells are cultured on an aligned nanotopography. This in vitro model can further be used to identify the GBM tumor cellsâ€™ response in a mimetic in vivo tumor microenvironment and elucidate how the aligned nanotopography transduces into altered gene and protein expression, thus providing a mechanism to target to inhibit the enhanced migratory behavior observed in these cells. Cytoskeletal stiffness Migration Cancer initiating cells Nanotopography Glioblastoma multiforme
3	Participação de integrinas na diferenciação osteoblástica induzida por superfícies de titânio com nano e microtopografia / Role of integrins on the osteoblast differentiation induced by titanium surfaces with nano and microtopography Lopes, Helena Bacha 30 November 2018 (has links) As integrinas constituem uma família de receptores de membrana que tem como função primária a adesão de células a proteínas da matriz extracelular e alguns de seus membros estão envolvidos nos processos de diferenciação osteoblástica e formação óssea, eventos diretamente relacionados à osseointegração de implantes de titânio (Ti). Sabe-se que superfícies de Ti com nano e microtopografia podem favorecer a diferenciação osteoblástica e a mineralização da matriz extracelular. No entanto, os mecanismos celulares envolvidos nesses processos não são completamente entendidos. Neste contexto, os objetivos deste estudo foram: (1) caracterizar as superfícies de Ti com nano (Ti-Nano) e microtopografia (Ti-Micro), (2) investigar a participação da integrina V na diferenciação osteoblástica induzida pelo Ti-Nano e (3) investigar a participação da integrina β3 na diferenciação osteoblástica induzida por Ti-Nano e Ti-Micro. Para isso, discos de Ti-Nano e Ti-Micro foram preparados por ataque ácido com H2SO4/H2O2 ou com HNO3/H2SO4 / HCl, respectivamente, e caracterizados quanto à topografia, rugosidade e composição química de superfície. Discos de Ti usinados foram usados com controle (Ti-Controle) em alguns experimentos. Células-tronco mesenquimais derivadas de medula óssea de ratos foram cultivadas sobre as três superfícies de Ti e foi avaliada a expressão gênica de componentes envolvidos na via de sinalização das integrinas por PCR array. Com base nos resultados do PCR array, as integrinas αV e β3 foram selecionadas e silenciadas por RNA de interferência (shRNA) ou CRISPR/Cas9, respectivamente, em células pré-osteoblásticas da linhagem MC3T3-E1 para investigarmos a participação dessas integrinas na diferenciação osteoblástica induzida por superfícies de Ti com diferentes topografias. Os resultados deste estudo mostraram que os tratamentos empregados foram eficientes para a produção de superfícies de Ti com topografias nas escalas nano e micrométrica. Além disso, foi demonstrado que o maior potencial osteogênico do Ti-Nano se deve, ao menos em parte, à integrina αV, uma vez que seu silenciamento reduziu a diferenciação osteoblástica induzida pela nanotopografia. Por fim, também demonstramos que a via de sinalização ativada pela integrina β3 exerce um papel fundamental no potencial osteogênico do Ti-Nano, mas não do Ti-Micro. O silenciamento da integrina β3 reduziu a diferenciação osteoblástica, concomitantemente com a regulação negativa da expressão de vários componentes das vias de sinalização de Wnt e de BMP, apenas nas células crescidas sobre a nanotopografia. Em conjunto, nossos resultados revelam um novo mecanismo para explicar a maior diferenciação osteoblástica induzida pelo Ti-Nano, que envolve uma complexa rede regulatória ativada pela maior expressão das integrinas αV e β3, esta última gerando ativação da transdução de sinal das vias de Wnt e de BMP / Integrins are a family of membrane receptors that primarily mediate cell adhesion to extracellular matrix proteins and some members are involved in the process of osteoblast differentiation and bone formation, key events of titanium (Ti) implant osseointegration. It is well known that Ti surfaces with nano and microtopography may favor osteoblast differentiation and matrix mineralization. However, the cellular mechanisms involved in this process are not entirely understood. In this context, the aims of this study were: (1) to characterize the Ti surfaces with nano (Ti-Nano) and microtopography (Ti-Micro), (2) to investigate the participation of integrin V on osteoblast differentiation induced by Ti-Nano and (3) to investigate the participation of integrin β3 on osteoblast differentiation induced by Ti-Nano and Ti-Micro. Discs of Ti-Nano and Ti-Micro were prepared with acid etching with H2SO4/H2O2 or with HNO3/H2SO4 / HCl, respectively, and characterized in terms of surface topography, roughness and chemical composition. Machined Ti discs (untreated) were used as control (Ti-Control) in some experiments. Mesenchymal stem cells from rat bone marrow were cultured on Ti discs with the three different surfaces and the gene expression of members of the integrin signaling pathway was evaluated by PCR array. Based on PCR array results, the integrins αV and β3 were selected and silenced using RNA interference (shRNA) or CRISPR-Cas9, respectively, in pre-osteoblastic cell line MC3T3-E1 to investigate the participation of these integrins in osteoblast differentiation induced by Ti with different surface topographies. The results showed that the treatments used were efficient to generate Ti surfaces with topographies at the nano and micrometric scales. We showed that the higher osteogenic potential of Ti-Nano may be, at least in part, due to the integrin &alphaV, since its silencing reduced the osteoblast differentiation induced by nanotopography. We also demonstrated that the signaling pathway triggered by integrin β3 plays a key role in the osteogenic potential of Ti-Nano, but not of Ti-Micro. The silencing of integrin β3 reduced the osteoblast differentiation concomitantly with the negative regulation of the gene expression of several Wnt and BMP signaling components only in cells grown on Ti-Nano. Taken together, our results uncover a novel mechanism to explain the higher osteoblast differentiation induced by Ti-Nano that involves a complex regulatory network triggered by integrins αV and β3 upregulation, with the integrin β3 activating the Wnt and BMP signal transductions CRISPR/Cas9 CRISPR/Cas9 Integrin Integrina Nanotopografia Nanotopography Osteoblast Osteoblasto ShRNA ShRNA Titânio Titanium
4	Participação de integrinas e microRNAs no potencial osteogênico de superfície de titânio com nanotopografia / Participation of integrins and microRNAs on the osteogenic potential of titanium with nanotopography Kato, Rogério Bentes 25 April 2014 (has links) O objetivo desse estudo foi investigar a participação de integrina α1β1 e microRNAs (miRs) no potencial osteogênico de superfícies de titânio (Ti) com nanotopografia. Discos de Ti previamente polidos foram tratados quimicamente com H2SO4/H2O2 para obtenção de nanotopografia, que foi observada por microscopia eletrônica de varredura. Para o estudo da participação da integrina α1β1, células-tronco mesenquimais (CTMs) de ratos foram cultivadas em condições osteogênicas e não osteogênicas sobre superfícies de Ti com nanotopografia e sem tratamento químico (controle). O resultados mostraram que a nanotopografia de Ti aumentou a proliferação celular, a atividade de fosfatase alcalina (Alp) e regulou positivamente a expressão gênica de marcadores da diferenciação osteoblástica em CTMs cultivadas tanto em condições osteogênicas quanto em condições não osteogênicas. Além disso, uma maior expressão gênica para as integrinas α1 e β1 foi observada em culturas crescidas sobre nanotopografia em condições não osteogênicas em relação ao Ti controle. O uso de obtustatina, um inibidor de integrina α1β1, reduziu os efeitos da nanotopografia sobre os marcadores osteoblásticos, indicando a participação da via de sinalização dessa integrina nos efeitos da nanotopografia sobre CTMs. Para investigar a participação de miRs no efeito osseoindutor da nanotopografia de Ti, foram utilizadas CTMs humanas e células préosteoblásticas de camundongos da linhagem MC3T3-E1. A análise em larga escala da expressão de miRs revelou que 60 miRs foram regulados positivamente (no mínimo, 2x maior), enquanto 58 miRs foram regulados negativamente (no mínimo, 2x menor) em CTMs crescidas sobre a nanotopografia. Três desses miRs, miR-4448, -4708 e -4773, cuja expressão foi significativamente reduzida pela nanotopografia de Ti (no mínimo, 5x menor), afetaram a diferenciação osteoblástica de CTMs. Esses miRs atuam diretamente sobre SMAD1 e SMAD4, proteínas transdutoras da sinalização da proteína óssea morfogenética 2 (Bmp-2), conhecida por sua capacidade osseoindutora. Além disso, verificou-se que a sobreexpressão de miR-4448, -4708 e -4773 em células pré-osteoblásticas MC3T3-E1 inibiu a expressão gênica e proteica de SMAD1 e SMAD4 e, consequentemente, a expressão gênica de marcadores ósseos. Esses dados sugerem a influência do circuito miR-SMAD-Bmp-2 sobre o efeito osseoindutor da nanotopografia. Conjuntamente, os achados do presente estudo mostraram que o efeito da nanotopografia de Ti sobre a diferenciação osteoblástica resulta de um mecanismo regulatório complexo, do qual fazem parte as vias de sinalização da integrina α1β1 e da Bmp-2, com a participação de miRs. Esses resultados podem representar um avanço para o desenvolvimento de novas modificações de superfície, com o objetivo de acelerar e/ou melhorar o processo de osseointegração. / The aim of this study was to investigate the role of the α1β1 integrin and microRNAs (miRs) on the osteogenic potential of titanium (Ti) with nanotopography. Polished Ti discs were chemically treated with H2SO4/H2O2 to generate nanotopography, which was observed under scanning electron microscopy. For the study related to the α1β1 integrin, rat mesenchymal stem cells (MSCs) were cultured under osteogenic and non-osteogenic conditions on Ti with nanotopography and non-treated Ti discs (control). Nanotopography increased cell proliferation and alkaline phosphatase (Alp) activity and upregulated the gene expression of bone markers in cells cultured under osteogenic and non-osteogenic conditions. Furthermore, the gene expression of α1 and β1 integrins was higher in cells cultured on nanotopography under non-osteogenic conditions compared with control. Obtustatin, an inhibitor of α1β1 integrin, reduced the higher gene expression of the bone markers induced by nanotopography. These results indicate that α1β1 integrin signaling pathway determines the osteoinductive effect of nanotopography on MSCs. The role of miRs in the osteogenic potential of Ti with nanotopography was evaluated using human MSCs and MC3T3-E1 mouse pre-osteoblastic cells. The miR sequencing analysis revealed that 60 miRs were upregulated (> 2 fold), while 58 miRs were downregulated (< 2 fold) in MSCs grown on nanotopography. Three miRs, miR-4448, -4708 and -4773, which were significantly downregulated (< 5 fold) by nanotopography, affected the osteoblast differentiation of MSCs. These miRs directly target SMAD1 and SMAD4, both key transducers of the bone morphogenetic protein 2 (Bmp-2) osteogenic signal, which were upregulated by nanotopography. Overexpression of miR-4448 - 4708 and 4773 in MC3T3-E1 cells noticeably inhibited gene and protein expression of SMAD1 and SMAD4 and by targeting them, these miRs repressed gene expression of key bone markers. These results suggest that a miR-SMAD-Bmp-2 circuit acts in the Ti nanotopography-mediated osteoblast differentiation. Taken together, our data showed that the osteoblast differentiation induced by Ti with nanotopography is governed by a complex regulatory network involving a crosstalk between α1β1 integrin and Bmp-2 signaling pathways with participation of miRs. célula-tronco mesenquimal integrin integrina mesenchymal stem cell microRNA microRNA nanotopografia nanotopography osteoblast osteoblasto titânio titanium
5	Participação de quinases reguladas por sinais extracelulares na interação entre células-tronco mesenquimais e titânio durante a diferenciação osteoblástica e adipocítica / Participation of extracellular signal-regulated kinases in mesenchymal stem cells and titanium interaction during osteoblast and adipocyte differentiation Silva, Heitor Fontes da 23 September 2016 (has links) A osseointegração de implantes de titânio (Ti) é dependente da interação entre a superfície de Ti e células, a qual é modulada por diversas vias de sinalização intracelular. Sabe-se que as quinases reguladas por sinais extracelulares (ERKs), membros da família das proteínas quinases ativadas por mitógenos (MAPKs), atuam tanto na osteogênese, quanto na adipogênese e, portanto, podem estar envolvidas no processo de osseointegração de Ti. Nesse contexto, o objetivo do presente estudo foi avaliar se a interação entre células-tronco mesenquimais (CTMs) e superfícies de Ti usinada e com nanotopografia é modulada, ao menos em parte, por ERK1/2 e o consequente efeito da inibição dessas ERKs na diferenciação osteoblástica e adipocítica. Para isso, CTMs derivadas de medula óssea de ratos foram cultivadas sobre discos de Ti usinados e com nanotopografia em condições osteogênicas e adipogênicas, na presença ou não do inibidor de ERK1/2, PD98059, em concentração previamente determinada (25 μM) e foram avaliados parâmetros relacionados à diferenciação osteoblástica e adipocítica. Os resultados mostraram que a expressão gênica dos marcadores osteoblásticos RUNX2, osterix (OSX), fosfatase alcalina (ALP) e osteocalcina (OC) foi aumentada pela inibição da via de sinalização de ERK1/2 nas células crescidas sobre Ti usinado e apenas ALP e OC, naquelas crescidas sobre Ti com nanotopografia. A expressão proteica de RUNX2 foi discretamente maior nas células crescidas sobre Ti usinado, mas não sobre Ti com nanotopografia, quando ERK1/2 foram inibidas e essa inibição não afetou a formação de matriz extracelular mineralizada, independentemente da superfície de Ti avaliada. Com relação à diferenciação adipocítica, a inibição da via de sinalização de ERK1/2 aumentou a expressão gênica dos marcadores adipocíticos PPARγ, adiponectina (ADIPOQ) e proteína ligadora de ácido graxo do adipócito ( AP2) nas células crescidas sobre ambas as superfícies de Ti, com efeito mais acentuado na superfície usinada, sem afetar a formação de acúmulo lípidico. Em conclusão, os resultados mostraram que a inibição de ERK1/2 favoreceu a diferenciação osteoblástica de CTMs crescidas sobre a superfície de Ti usinada, mas não sobre Ti com nanotopografia. Além disso, a inibição de ERK1/2 favoreceu a diferenciação adipocítica de CTMs crescidas sobre as superfícies de Ti com nanotopografia e usinada, sendo o efeito mais acentuado na usinada. Considerando aplicações terapêuticas, esses resultados são relevantes para direcionar o desenvolvimento de superfícies de biomateriais que atuem em vias de sinalização que sabidamente modulam o processo de osteogênese. / Osseointegration of titanium (Ti) implants depends on interaction between Ti surface and cells, which is modulated by several intracellular signaling pathways. Extracellular signal-regulated kinases (ERKs) are members of mitogen-activated protein kinases (MAPKs) family and act on both osteogenesis and adipogenesis and, therefore, may be involved in the process of Ti osseointegration. In this context, the aim of this study was to evaluate if the interaction between mesenchymal stem cells (MSCs) and Ti surfaces, either machined or with nanotopography, is modulated, at least in part, by ERK1/2 and the effect of ERK1/2 inhibition on osteoblast and adipocyte differentiation. Rat bone marrow MSCs were cultured on Ti discs either machined or with nanotopography under osteogenic and adipogenic conditions, in presence or not of the ERK1/2 inhibitor, PD98059, at a concentration previously determined (25 μM) and it was evaluated parameters related to osteoblast and adipocyte differentiation. The results showed that gene expression of the bone markers RUNX2, osterix (OSX), alkaline phosphatase (ALP) and osteocalcin (OC) was increased by ERK1/2 signaling inhibition in cells grown on machined Ti and only ALP and OC in cells grown on Ti with nanotopography. RUNX2 protein expression was slightly higher in cells grown on machined Ti, but not on Ti with nanotopography, when ERK1/2 signaling was inhibited and such inhibition did not affect extracellular matrix mineralization, irrespective of the evaluated Ti surface. Regarding adipocyte differentiation, ERK1/2 signaling inhibition increased gene expression of the adipose tissue markers PPARγ, adiponectin (ADIPOQ) and adipocyte fatty acid-binding protein (AP2) in cells grown on both Ti surfaces, with more prominet effect on machined one, without affecting lipid accumulation. In conclusion, our results showed that ERK1/2 signaling inhibition favored osteoblast differentiation of MSCs grown on machined Ti, but not on Ti with nanotopography. In addition, ERK1/2 signaling inhibition favored adipocyte differentiation of MSCs grown on both Ti surfaces, being more noticeable on machined one. Considering therapeutical applications, these results are relevant to drive the development of biomaterial surfaces to act on signaling pathways that regulate the process of osteogenesis.
6	Desenvolvimento do fenótipo osteogênico in vitro sobre diferentes nanotopografias de titânio funcionalizadas com o fator de crescimento GDF-5 / Development of the osteogenic phenotype in vitro on titanium surface nanotopographies functionalized with GDF-5 Bueno, Renan de Barros e Lima 08 October 2010 (has links) Modificações bioquímicas de topografias complexas de Ti permitem o desenvolvimento de novas superfícies de implantes funcionalizadas com moléculas bioativas, visando a promover a osteogênese de contato e a osseointegração. O objetivo do presente estudo foi avaliar o desenvolvimento do fenótipo osteogênico in vitro sobre diferentes nanotopografias de titânio (Ti) funcionalizadas com o fator de crescimento GDF-5. Células osteogênicas derivadas de calvária de ratos recém-nascidos foram plaqueadas e cultivadas por até 14 dias sobre superfícies de discos de Ti: 1) Controle (usinada e polida); 2) 30′ (com nanotopografia de nanoporos menores, obtida por condicionamento em solução de H2SO4/H2O2 por 30 min); 3) 30′+GDF-5 (nanotopografia de 30′, pré-adsorvida com GDF-5 a 200 ng/mL); 4) 4h (com nanotopografia de nanoporos maiores, obtida por condicionamento em H2SO4/H2O2 por 4 h); 5) 4h+GDF-5 (nanotopografia de 4h, pré-adsorvida com GDF-5 a 200 ng/mL). A adsorção de GDF-5 foi realizada a 4 ºC por 12 h no dia anterior ao plaqueamento das células. Os resultados mostraram que não houve diferenças estatisticamente significantes entre os grupos para a viabilidade celular em 1, 3 e 7 dias. Em 3 dias, as células estavam aderidas e espraiadas sobre todas as superfícies e acúmulos extracelulares extensos de OPN foram encontrados apenas sobre superfícies com nanotopografia de 4h e de 30′+GDF-5. A expressão de RNAm para RUNX2 e ALP foi maior em 7 dias se comparada a 10 dias, sendo os menores valores encontrados para o grupo 4h+GDF-5. A expressão de OPN aumentou de 7 para 10 dias, exceto para 30′+GDF-5, que se manteve inalterada. Enquanto que os níveis de RNAm para BSP aumentaram de 7 para 10 dias no Controle, redução significativa foi observada para os demais grupos, exceto para 30′, em que se manteve constante. Culturas crescidas sobre nanotopografias funcionalizadas com GDF-5 exibiram os maiores valores de atividade de ALP em 10 dias e de áreas de matriz mineralizada/acúmulos de cálcio em 14 dias. Em conclusão, a funcionalização de nanotopografias de Ti com GDF-5 pode acelerar e/ou aumentar a expressão do fenótipo osteogênico in vitro. / Surface functionalization of metallic surfaces with bioactive molecules has been developed aiming to promote specific cellular responses at the biomaterial-tissue interface. The present study evaluated the development of the osteogenic phenotype in vitro on titanium (Ti) surface nanotopographies functionalized with growth and differentiation factor-5 (GDF-5). Osteogenic cells were obtained by enzymatic digestion of newborn rat calvarial bone and grown for periods of up to 14 days on the following Ti disc surfaces: 1) Machined; 2) 30′ Nanotopography created by a mixture of H2SO4/H2O2 for 30 min; 3) 30′+GDF-5 Nanotopography created by a mixture of H2SO4/H2O2 for 30 min and then adsorbed with 200 ng/mL GDF-5 (overnight at 4 °C); 4) 4h Nanotopography created by a mixture of H2SO4/H2O2 for 4 h; 5) 4h+GDF-5 Nanotopography created by a mixture of H2SO4/H2O2 for 4 h and then adsorbed with 200 ng/mL GDF-5 (overnight at 4 °C). At 4 h, nanotopographies adsorbed with GDF-5 exhibited a significantly lower proportion of spread cells. At days 1, 3 and 7 no major differences in terms of cell viability were detected among groups. At day 3, epifluorescence revealed large extracellular OPN accumulation only for 30′+GDF-5, 4h and 4h+GDF-5. Real time PCR analysis showed for GDF-5 groups: i) lower mRNA levels for RUNX2, ALP e BSP at day 10; ii) higher RUNX2 and ALP expression at day 7 compared with day 10, with the lowest levels for 4h+GDF-5; iii) increased OPN levels from day 7 to day 10, except for 30′+GDF-5, which remained unaltered. Cultures grown on nanotopographies adsorbed with GDF-5 exhibited significantly higher values for ALP activity at 10 days and enhanced mineralized matrix formation at day 14. In conclusion, surface functionalization of Ti nanotopographies with GDF-5 can accelerate and/or increase the expression of the osteogenic phenotype in vitro. Cell culture Cultura de células Fator de crescimento Funcionalização Functionalization Growth factors Nanotopografia Nanotopography Osteogênese Osteogenesis
7	Funcionalização de GDF-5 em superfície nanoestruturada de titânio: estudos in vitro e in vivo / Nanoscale titanium surface functionalization with GDF-5: in vitro and in vivo studies Bueno, Renan de Barros e Lima 27 March 2015 (has links) Estudo anterior de nosso grupo demonstrou que superfície de titânio (Ti) com nanotopografia obtida por condicionamento com H2SO4/H2O2 e funcionalizada com GDF-5 por simples adsorção promove o aumento da mineralização de culturas primárias de células osteogênicas. O presente estudo teve como objetivos avaliar: 1) os efeitos da pós-adsorção de proteínas principais do plasma- albumina, fibrinogênio e fibronectina, em superfícies de Ti controle e com nanotopografia, funcionalizadas com GDF-5 a 200 ng/mL por simples adsorção, sobre a formação de matriz mineralizada in vitro; 2) parâmetros moleculares e fenotípicos característicos da aquisição do fenótipo osteogênico in vitro sobre superfícies de Ti funcionalizadas com GDF-5 por simples adsorção ou por filmes LbL; 3) parâmetros de formação óssea adjacente a implantes de Ti com nanotopografia funcionalizada com GDF-5 pelos dois métodos, em modelo de tíbia de coelhos. Os resultados mostraram que a pós-adsorção de proteínas plasmáticas não afetou o potencial osteogênico in vitro, com exceção para o efeito inibidor da albumina, quando pós-adsorvida isoladamente. Tanto a superfície de Ti como o método de funcionalização de GDF-5 afetaram, quantitativamente, as formações de matriz mineralizada, com a maior diferenciação osteogênica para Ti com nanotopografia funcionalizada com GDF-5 por simples adsorção e a menor, para os filmes LbL, independentemente das superfícies sobre as quais eles eram montados. A atividade de ALP foi maior em culturas sobre nanotopografia de Ti, incluindo aquelas funcionalizadas com GDF-5, cujos valores, no entanto, não corresponderam, necessariamente, à maior atividade osteogênica. Apesar disso, todos os grupos exibiram expressão de marcadores de diferenciação osteoblástica, com sobre-expressão de osteopontina e osteocalcina para culturas sobre LbL. As análises microtomográfica, histológica e histomorfométrica não revelaram diferenças qualitativas e quantitativas in vivo entre nanotopografias de Ti funcionalizadas ou não com GDF-5, ainda que uma tendência à maior formação óssea tenha sido observada para as superfícies funcionalizadas e, entre essas, para os filmes LbL. Considerados conjuntamente, os resultados do presente estudo contribuem para o melhor entendimento das respostas de osteoblastos e do tecido ósseo quando se propõe a estratégia de funcionalização de superfícies de Ti com GDF-5 visando à otimização da osseointegração. / It has been demonstrated that a nanostructured titanium (Ti) surface obtained by treatment with H2SO4/H2O2 and functionalized with GDF-5 by simple adsorption promotes the enhancement of mineralized matrix formation in osteogenic cell cultures. This study aimed to evaluate: 1) the effects of post-adsorption of major plasma proteins, i.e. albumin, fibrinogen and fibronectin, on control and nanostructured Ti surfaces, functionalized with 200 ng/mL GDF-5 by simple adsorption, on mineralized matrix formation by calvarial osteogenic cell cultures; 2) molecular and phenotypic parameters characteristics of the acquisition of the osteogenic phenotype in vitro on Ti surfaces functionalized with GDF-5 by either simple adsorption or layer by layer (LbL) films; 3) parameters of bone formation adjacent to Ti implants with a nanostructured surface functionalized with GDF-5 by the two methods described in item 2, in a rabbit tibia model. The results showed that the post-adsorption of plasma proteins did not affect the osteogenic potential of cultures, except for the inhibitory effect of albumin when post-adsorbed alone. Either the Ti surface topography or the method for GDF-5 functionalization quantitatively affected mineralized matrix formation, with the higher osteogenic differentiation for nanostructured Ti functionalized with GDF-5 by simple adsorption and the lower one for LbL films, irrespective of the Ti surface topography on which they were mounted. ALP activity was higher for cultures grown on nanostructured Ti, including those functionalized with GDF-5, whose values, however, did not necessarily correspond to the higher osteogenic activity. Despite that, all groups expressed osteoblast differentiation markers, with a remarkable increase in osteopontin and osteocalcin mRNA levels for cultures grown on LbL films. The microtomographic, histologic and histomorphometric analyses revealed no qualitative or quantitative differences in vivo among the nanostructured Ti implants, yet a tendency for enhanced bone formation was observed for the functionalized surfaces and, between them, for the LbL films. Taken together, the results of the present in vitro and in vivo studies contribute to a better understanding of osteoblast and bone tissue responses to the functionalization of Ti surfaces with GDF-5 aiming to optimize osseointegration. Cell culture Cultura de células Fator de crescimento Funcionalização Functionalization Growth factors Nanotopografia Nanotopography Osteogênese Osteogenesis
8	Effect of Surface Nanotopography on Blood-Biomaterial Interactions Ferraz, Natalia January 2010 (has links) Biologically inspired materials are being developed with the aim of improving the integration of medical implants and minimizing non-desirable host reactions. A promising strategy is the design of topographically patterned surfaces that resemble those found in the extracellular environment. Nanoporous alumina has been recognized as a potential biomaterial and as an important template for the fabrication of nanostructures. In this thesis in vitro studies were done to elucidate the role of alumina nanoporosity on the inflammatory response. Specifically, by comparing alumina membranes with two pore sizes (20 and 200 nm in diameter). Complement and platelet activation were evaluated as well as monocyte/macrophage behaviour. Whole blood was incubated with the alumina membranes and thereafter the biomaterial surfaces were evaluated in terms of protein and platelet adhesion as well as procoagulant properties. The fluid phase was analyzed for complement activation products and platelet activation markers. Besides, human mononuclear cells were cultured on the alumina membranes and cell adhesion, viability, morphology and release of pro-inflammatory cytokines were evaluated. The results indicated that nanoporous alumina with 200 nm pores promotes higher complement activation than alumina with 20 nm pores. In addition, platelet response to nanoporous alumina was found to be highly dependent on the material porosity, as reflected by differences in adhesion, PMP generation and procoagulant characteristics. A clear difference in monocyte/macrophage adhesion and activation was found between the two pore size alumina membranes. Few but highly activated cells adhered to the 200 nm membrane in contrast to many but less activated monocytes/macrophages on the 20 nm surface. The outcome of this work emphasizes that nanotopography plays an important role in the host response to biomaterials. Better understanding of molecular interactions on nano-level will undoubtedly play a significant role in biomaterial implant development and will contribute to design strategies for controlling specific biological events. nanoporous alumina nanotopography biomaterial platelets complement system macrophages whole blood inflammatory response Chemistry Kemi Immunobiology Immunbiologi
9	Influence of Nanoscale Surface Modifications on the Fatigue Resistance of Medically Relevant Metals Ketabchi, Amirhossein 07 May 2013 (has links) With an increasingly aging population, a significant challenge in implantology is the creation of biomaterials that actively promote and accelerate tissue integration while offering excellent mechanical properties. Engineered surfaces with superimposed micro and nanoscale topographies showed great potential to control and direct biomaterial-host tissue interactions. However, these modified surfaces require a careful assessment to prevent potential adverse effects on the fatigue resistance, a factor which may ultimately cause premature failure of biomedical implants. In this context, the surfaces of two widely used biocompatible metals, namely CP Ti and Ti-6Al-4V, were engineered through simple yet efficient chemical treatments which demonstrated the ability to confer exciting new bioactive capacities. The qualitative and quantitative assessments of the fatigue resistance of polished and treated metals were carried out. Results from this study highlight the importance of mechanical considerations in the development and evaluation of nanoscale surface treatments for metallic biomedical implants. Titanium Ti-6Al-4V surface modifications fatigue resistance anodization oxidative nanopatterning nanotopography
10	Electrospinning of Bioactive Dex-PAA Hydrogel Fibers January 2011 (has links) abstract: In this work, a novel method is developed for making nano- and micro- fibrous hydrogels capable of preventing the rejection of implanted materials. This is achieved by either (1) mimicking the native cellular environment, to exert fine control over the cellular response or (2) acting as a protective barrier, to camouflage the foreign nature of a material and evade recognition by the immune system. Comprehensive characterization and in vitro studies described here provide a foundation for developing substrates for use in clinical applications. Hydrogel dextran and poly(acrylic acid) (PAA) fibers are formed via electrospinning, in sizes ranging from nanometers to microns in diameter. While "as-electrospun" fibers are continuous in length, sonication is used to fragment fibers into short fiber "bristles" and generate nano- and micro- fibrous surface coatings over a wide range of topographies. Dex-PAA fibrous surfaces are chemically modified, and then optimized and characterized for non-fouling and ECM-mimetic properties. The non-fouling nature of fibers is verified, and cell culture studies show differential responses dependent upon chemical, topographical and mechanical properties. Dex-PAA fibers are advantageously unique in that (1) a fine degree of control is possible over three significant parameters critical for modifying cellular response: topography, chemistry and mechanical properties, over a range emulating that of native cellular environments, (2) the innate nature of the material is non-fouling, providing an inert background for adding back specific bioactive functionality, and (3) the fibers can be applied as a surface coating or comprise the scaffold itself. This is the first reported work of dex-PAA hydrogel fibers formed via electrospinning and thermal cross-linking, and unique to this method, no toxic solvents or cross-linking agents are needed to create hydrogels or for surface attachment. This is also the first reported work of using sonication to fragment electrospun hydrogel fibers, and in which surface coatings were made via simple electrostatic interaction and dehydration. These versatile features enable fibrous surface coatings to be applied to virtually any material. Results of this research broadly impact the design of biomaterials which contact cells in the body by directing the consequent cell-material interaction. / Dissertation/Thesis / Ph.D. Bioengineering 2011 Biomedical Engineering Materials Science Polymer Chemistr bioactive biofunctionalization dextran electrospinning nanofibers nanotopography

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