Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari

Detalhes bibliográficos
Autor(a) principal: Aguiar, Anne Helena Duarte de
Data de Publicação: 2019
Tipo de documento: Dissertação
Idioma: por
Título da fonte: Biblioteca Digital de Teses e Dissertações da UFPB
Texto Completo: https://repositorio.ufpb.br/jspui/handle/123456789/19301
Resumo: Biomaterials have been widely used in the medical and dental fields due to their excellent properties. Among the biomaterials, calcium phosphate bioceramics stands out, among which, hydroxyapatite and tricalcium phosphate are the most studied and researched because they are naturally bioactive and exhibit excellent biocompatibility, bioactivity, dissolution rates, absence of toxicity and osteoconductivity (indicate the path for bone growth), thus favoring osteoinduction, osseointegration and bone neoformation when placed in a biological environment. With the advent of nanotechnology it has become possible to use bioceramics as root cements. A biocement that has gained a broad field of use in dentistry was the Mineral Trioxide Aggregate (MTA), which can be used in several dental procedures. The main objective of the present study was to prepare and characterize cements based on Portland CPV-Ari and Tricalcium Phosphate for dental use. Six cements were prepared: in the solid phase, 200g of pure CPV-Ari were used, added to 0.5%, 1%, 2%, 4% and 8% of Triccalcium Phosphate powder and mixed in a ball mill. The liquid phase was maintained at the ratio of 0.27 g of distilled water to all the cements. The cements were inserted into test bodies and the top of the test specimen was maintained in contact with artificial saliva. The cements were characterized at the ages of 7 days (168H) and 28 days (672H), in the top and middle regions of the sample. The techniques used were: Mass Loss and Solubility, Ph, Thermogravimetry, X-ray Fluorescence, X-Ray Diffraction, Scanning Electron Microscopy and Vickers Microhardness. The solubility test showed that most of the cements had solubility below the maximum recommended by ADA standards n.57 and ISO 6876/2001, which is 3%, except for CPV + 2% Tricalcium Phosphate for the experimental time of 28 days. The Ph variation test showed that all the cements provided alkalinity of the medium to which they were exposed, with the highest alkalinity obtained with cement CPV + 4% Tricalcium phosphate. Thermogravimetry showed that all the cements behaved in a similar way, where the mass loss occurred in five stages, and the cement CPV + 8% Tricalcium Phosphate was the one in which the mass loss was the lowest.. The XRF of all the cements showed the formation of the oxides present in the Portland cement, as well as the formation of the diphosphorus pentoxide, where in the top region of the sample in contact with saliva the P2O5/CaO content increased as the Triccalcium Phosphate present in the cement increased. In XRD, the presence of four phases was verified: Etringite; Portlandite; Hatrurite; Hydroxyapatite. The microhardness showed that due to leaching of the cement compounds the region of the top of the sample in contact with the saliva obtained results of microhardness inferior to the regions that were not in contact with the saliva. The SEM shows that all the micrographs of the region exposed to saliva obtained images compatible with those found in the literature of formation of hydroxyapatite. These results suggest that it is possible to develop a dental cement using Portland CPV-Ari + Triccalcium Phosphate
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spelling Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-AriBiomateriaisBiocerâmicasMTACimento PortlandFosfato TricálcicoBiomaterialsBioceramicsPortland CementTriccalcium PhosphateCNPQ::ENGENHARIASBiomaterials have been widely used in the medical and dental fields due to their excellent properties. Among the biomaterials, calcium phosphate bioceramics stands out, among which, hydroxyapatite and tricalcium phosphate are the most studied and researched because they are naturally bioactive and exhibit excellent biocompatibility, bioactivity, dissolution rates, absence of toxicity and osteoconductivity (indicate the path for bone growth), thus favoring osteoinduction, osseointegration and bone neoformation when placed in a biological environment. With the advent of nanotechnology it has become possible to use bioceramics as root cements. A biocement that has gained a broad field of use in dentistry was the Mineral Trioxide Aggregate (MTA), which can be used in several dental procedures. The main objective of the present study was to prepare and characterize cements based on Portland CPV-Ari and Tricalcium Phosphate for dental use. Six cements were prepared: in the solid phase, 200g of pure CPV-Ari were used, added to 0.5%, 1%, 2%, 4% and 8% of Triccalcium Phosphate powder and mixed in a ball mill. The liquid phase was maintained at the ratio of 0.27 g of distilled water to all the cements. The cements were inserted into test bodies and the top of the test specimen was maintained in contact with artificial saliva. The cements were characterized at the ages of 7 days (168H) and 28 days (672H), in the top and middle regions of the sample. The techniques used were: Mass Loss and Solubility, Ph, Thermogravimetry, X-ray Fluorescence, X-Ray Diffraction, Scanning Electron Microscopy and Vickers Microhardness. The solubility test showed that most of the cements had solubility below the maximum recommended by ADA standards n.57 and ISO 6876/2001, which is 3%, except for CPV + 2% Tricalcium Phosphate for the experimental time of 28 days. The Ph variation test showed that all the cements provided alkalinity of the medium to which they were exposed, with the highest alkalinity obtained with cement CPV + 4% Tricalcium phosphate. Thermogravimetry showed that all the cements behaved in a similar way, where the mass loss occurred in five stages, and the cement CPV + 8% Tricalcium Phosphate was the one in which the mass loss was the lowest.. The XRF of all the cements showed the formation of the oxides present in the Portland cement, as well as the formation of the diphosphorus pentoxide, where in the top region of the sample in contact with saliva the P2O5/CaO content increased as the Triccalcium Phosphate present in the cement increased. In XRD, the presence of four phases was verified: Etringite; Portlandite; Hatrurite; Hydroxyapatite. The microhardness showed that due to leaching of the cement compounds the region of the top of the sample in contact with the saliva obtained results of microhardness inferior to the regions that were not in contact with the saliva. The SEM shows that all the micrographs of the region exposed to saliva obtained images compatible with those found in the literature of formation of hydroxyapatite. These results suggest that it is possible to develop a dental cement using Portland CPV-Ari + Triccalcium PhosphateNenhumaOs biomaterias têm sido amplamente utilizados na área médica e odontológica por possuírem excelentes propriedades. Entre os biomateriais destacam-se as biocerâmicas de fosfato de cálcio, entre as quais, a hidroxiapatita e o fosfato tricálcico são os mais estudadas e pesquisadas por serem naturalmente bioativos e apresenterem excelente biocompatibilidade, bioatividade, diferentes taxas de dissolução, ausência de toxicidade e osteocondutividade (indicam o caminho para o crescimento ósseo), favorecendo dessa forma a osteoindução, osseointegração e a neoformação óssea quando colocados em meio biológico. Com o advento da nanotecnologia tornou-se possível utilizar biocerâmicas como cimentos radiculares. Um biocimento que conquistou um amplo campo de utilização na odontologia foi o Agregado de Trióxido Mineral (MTA), podendo ser utilizado em vários procedimentos odontológicos. O MTA apresenta, em sua composição, componentes semelhantes aos do cimento Portland.O presente estudo teve como objetivo principal preparar e caracterizar cimentos à base de Portland CPV-Ari e Fosfato Tricálcico para uso odontológico. Foram preparados seis cimentos: na fase sólida foram utilizados 200g de CPV-Ari puro e adicionado a 0.5%,1%,2%,4% e 8% de pó de Fosfato Tricálcico e misturados em moinho de bolas. A fase liquida foi mantida a proporção de 0,27g de água destilada para todos os cimentos. Os cimentos foram inseridos em corpos de prova e o topo do corpo de prova foi mantido em contato com saliva artificial. Os cimentos foram caracterizados nas idades de 7 dias (168H) e 28 dias (672H) e, nas regiões de topo da amostra e meio da amostra. As técnicas utilizadas foram: Perda de massa e Solubilidade, Ph, Termogravimetria, Fluorescência de RX, Difração de RX, Microscopia Eletrônica de Varredura e Microdureza Vickers. O teste de solubilidade mostrou que a maioria dos cimentos apresentaram solubilidade abaixo do máximo recomendado pelas normas da ADA n.57 e ISO 6876/2001, que é de 3%, exceto o CPV+2% Fosfato Tricálcico para o tempo experimental de 28 dias. O teste de variação do Ph evidenciou que todos os cimentos proporcionaram alcalinidade do meio ao qual foram expostos, sendo a maior alcalinidade obtida com o cimento CPV+4% Fosfato tricácico. A termogravimétria mostrou que todos os cimentos se comportaram de maneira semelhante, onde a perda de massa ocorreu em cinco etapas, e o cimento CPV+8% Fosfato Tricálcico foi o que perdeu menos massa. O FRX de todos os cimentos mostraram a formação dos óxidos presentes no cimento Portland, e também a formação do pentóxido de difósforo, onde na região do topo da amostra em contato com a saliva o teor de P2O5/CaO aumentou conforme o acréscimo de Fosfato Tricálcico presente no cimento. No DRX foi verificado basicamente a presença de quatro fases: Etringita; Portlandite Hatrurite; Hidroxiapatita. A microdureza mostrou que devido a lixiviação dos compostos do cimento a região do topo da amostra em contato com a saliva obteve resultados de microdureza inferiores as regiões que não estiveram em contato com a saliva. O MEV mostra que todos as micografias da região exposta a saliva obtiveram imagem compatíveis com as encontradas na literatura de formação de hidroxiapatita. Esses resultados sugerem que há possibilidade de desenvolver um cimento odontológico utilizando Portland CPV-Ari + Fosfato TricálcicoUniversidade Federal da ParaíbaBrasilEngenharia de MateriaisPrograma de Pós-Graduação em Ciência e Engenharia de MateriaisUFPBVieira, Andressa de Araújo Portohttp://lattes.cnpq.br/5279240919437112Aguiar, Anne Helena Duarte de2021-02-07T20:47:48Z2020-07-172021-02-07T20:47:48Z2019-07-17info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesishttps://repositorio.ufpb.br/jspui/handle/123456789/19301porhttp://creativecommons.org/licenses/by-nd/3.0/br/info:eu-repo/semantics/embargoedAccessreponame:Biblioteca Digital de Teses e Dissertações da UFPBinstname:Universidade Federal da Paraíba (UFPB)instacron:UFPB2021-08-16T14:35:10Zoai:repositorio.ufpb.br:123456789/19301Biblioteca Digital de Teses e Dissertaçõeshttps://repositorio.ufpb.br/PUBhttp://tede.biblioteca.ufpb.br:8080/oai/requestdiretoria@ufpb.br|| diretoria@ufpb.bropendoar:2021-08-16T14:35:10Biblioteca Digital de Teses e Dissertações da UFPB - Universidade Federal da Paraíba (UFPB)false
dc.title.none.fl_str_mv Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
title Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
spellingShingle Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
Aguiar, Anne Helena Duarte de
Biomateriais
Biocerâmicas
MTA
Cimento Portland
Fosfato Tricálcico
Biomaterials
Bioceramics
Portland Cement
Triccalcium Phosphate
CNPQ::ENGENHARIAS
title_short Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
title_full Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
title_fullStr Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
title_full_unstemmed Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
title_sort Obtenção e caracterização de cimento odontológico a partir da adição de Fosfato Tricálcico ao cimento Portland CPV-Ari
author Aguiar, Anne Helena Duarte de
author_facet Aguiar, Anne Helena Duarte de
author_role author
dc.contributor.none.fl_str_mv Vieira, Andressa de Araújo Porto
http://lattes.cnpq.br/5279240919437112
dc.contributor.author.fl_str_mv Aguiar, Anne Helena Duarte de
dc.subject.por.fl_str_mv Biomateriais
Biocerâmicas
MTA
Cimento Portland
Fosfato Tricálcico
Biomaterials
Bioceramics
Portland Cement
Triccalcium Phosphate
CNPQ::ENGENHARIAS
topic Biomateriais
Biocerâmicas
MTA
Cimento Portland
Fosfato Tricálcico
Biomaterials
Bioceramics
Portland Cement
Triccalcium Phosphate
CNPQ::ENGENHARIAS
description Biomaterials have been widely used in the medical and dental fields due to their excellent properties. Among the biomaterials, calcium phosphate bioceramics stands out, among which, hydroxyapatite and tricalcium phosphate are the most studied and researched because they are naturally bioactive and exhibit excellent biocompatibility, bioactivity, dissolution rates, absence of toxicity and osteoconductivity (indicate the path for bone growth), thus favoring osteoinduction, osseointegration and bone neoformation when placed in a biological environment. With the advent of nanotechnology it has become possible to use bioceramics as root cements. A biocement that has gained a broad field of use in dentistry was the Mineral Trioxide Aggregate (MTA), which can be used in several dental procedures. The main objective of the present study was to prepare and characterize cements based on Portland CPV-Ari and Tricalcium Phosphate for dental use. Six cements were prepared: in the solid phase, 200g of pure CPV-Ari were used, added to 0.5%, 1%, 2%, 4% and 8% of Triccalcium Phosphate powder and mixed in a ball mill. The liquid phase was maintained at the ratio of 0.27 g of distilled water to all the cements. The cements were inserted into test bodies and the top of the test specimen was maintained in contact with artificial saliva. The cements were characterized at the ages of 7 days (168H) and 28 days (672H), in the top and middle regions of the sample. The techniques used were: Mass Loss and Solubility, Ph, Thermogravimetry, X-ray Fluorescence, X-Ray Diffraction, Scanning Electron Microscopy and Vickers Microhardness. The solubility test showed that most of the cements had solubility below the maximum recommended by ADA standards n.57 and ISO 6876/2001, which is 3%, except for CPV + 2% Tricalcium Phosphate for the experimental time of 28 days. The Ph variation test showed that all the cements provided alkalinity of the medium to which they were exposed, with the highest alkalinity obtained with cement CPV + 4% Tricalcium phosphate. Thermogravimetry showed that all the cements behaved in a similar way, where the mass loss occurred in five stages, and the cement CPV + 8% Tricalcium Phosphate was the one in which the mass loss was the lowest.. The XRF of all the cements showed the formation of the oxides present in the Portland cement, as well as the formation of the diphosphorus pentoxide, where in the top region of the sample in contact with saliva the P2O5/CaO content increased as the Triccalcium Phosphate present in the cement increased. In XRD, the presence of four phases was verified: Etringite; Portlandite; Hatrurite; Hydroxyapatite. The microhardness showed that due to leaching of the cement compounds the region of the top of the sample in contact with the saliva obtained results of microhardness inferior to the regions that were not in contact with the saliva. The SEM shows that all the micrographs of the region exposed to saliva obtained images compatible with those found in the literature of formation of hydroxyapatite. These results suggest that it is possible to develop a dental cement using Portland CPV-Ari + Triccalcium Phosphate
publishDate 2019
dc.date.none.fl_str_mv 2019-07-17
2020-07-17
2021-02-07T20:47:48Z
2021-02-07T20:47:48Z
dc.type.status.fl_str_mv info:eu-repo/semantics/publishedVersion
dc.type.driver.fl_str_mv info:eu-repo/semantics/masterThesis
format masterThesis
status_str publishedVersion
dc.identifier.uri.fl_str_mv https://repositorio.ufpb.br/jspui/handle/123456789/19301
url https://repositorio.ufpb.br/jspui/handle/123456789/19301
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language por
dc.rights.driver.fl_str_mv http://creativecommons.org/licenses/by-nd/3.0/br/
info:eu-repo/semantics/embargoedAccess
rights_invalid_str_mv http://creativecommons.org/licenses/by-nd/3.0/br/
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dc.publisher.none.fl_str_mv Universidade Federal da Paraíba
Brasil
Engenharia de Materiais
Programa de Pós-Graduação em Ciência e Engenharia de Materiais
UFPB
publisher.none.fl_str_mv Universidade Federal da Paraíba
Brasil
Engenharia de Materiais
Programa de Pós-Graduação em Ciência e Engenharia de Materiais
UFPB
dc.source.none.fl_str_mv reponame:Biblioteca Digital de Teses e Dissertações da UFPB
instname:Universidade Federal da Paraíba (UFPB)
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repository.name.fl_str_mv Biblioteca Digital de Teses e Dissertações da UFPB - Universidade Federal da Paraíba (UFPB)
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