Próteses odontológicas associadas a Nanopartículas de Prata biogênicas: caracterização e atividade antimicrobiana

Santos, Mateus Leite

Campo DC

Valor

Idioma

dc.creator

Santos, Mateus Leite

dc.date.accessioned

2025-01-14T12:15:47Z

dc.date.available

2025-01-12

dc.date.available

2025-01-14T12:15:47Z

dc.date.issued

2024-12-21

dc.identifier.citation

SANTOS, Mateus Leite. Próteses odontológicas associadas a nanopartículas de prata biogênicas: caracterização e atividade antimicrobiana. Orientadora: Ana Rita Sokolonski Antón. 2024. 60 f. Dissertação (Mestrado em Processos Interativos de Órgãos e Sistemas) - Instituto de Ciências da Saúde, Universidade Federal da Bahia, Salvador, 2024.

pt_BR

dc.identifier.uri

https://repositorio.ufba.br/handle/ri/40895

dc.description.abstract

Introduction: The increased need for dental prostheses means that the implications of this treatment are the focus of many clinical and scientific discussions today. Poorly adapted and traumatogenic prostheses can be the main etiological factor of many diseases of the oral cavity. Given this, it is necessary, in addition to stimulating hygiene, to explore and develop new technologies to make PMMA antimicrobial. Biogenic AgNPs as a surface treatment for acrylic resin is one of the disruptive and innovative ways to make a prosthesis antimicrobial. Objective: the present study carried out the characterization, antimicrobial activity, durability determination, and roughness analysis of PMMA specimens treated with biogenic AgNP. Material and methods: The specimens were treated with a biogenic AgNP solution synthesized by the fungus fusarium oxysporum in different treatment groups, and then the physicochemical characteristics of the Nanoparticle, performance, sensitivity test to bacteria, thermal cycling, and contact test were proven. Modified direct, color evaluation through spectrophotometry testing and roughness testing. Results: The resins that received nanoparticles in the total mass did not show antimicrobial activity, despite the incorporation of AgNP significantly improving the surface roughness of the colorless resin. The other surface treatments showed high antibacterial activity and moderate antifungal activity. AgNP was not able to cause clinically significant color changes, it only showed a decrease in red saturation in the pink resin. Conclusion: Surface treatments with AgNP on thermopolymerizable acrylic resin can resist up to 30 days in the oral cavity, do not change the color or roughness of the material, and have high antimicrobial activity. More studies need to be carried out to determine the activity over longer periods, more challenging situations, and with other NPM species.

pt_BR

dc.description.sponsorship

Capes - Fundação Coordenação de Aperfeiçoamento de Pessoal de Nível Superior

pt_BR

dc.language

por

pt_BR

dc.publisher

Universidade Federal da Bahia

pt_BR

dc.rights

Acesso Aberto

pt_BR

dc.subject

Nanotecnologia

pt_BR

dc.subject

Nanopartículas metálicas

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dc.subject

Prótese dentária

pt_BR

dc.subject

Materiais dentários

pt_BR

dc.subject

Materiais biomédicos e odontológicos

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dc.subject.other

Nanotechnology

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dc.subject.other

Metal Nanoparticles

pt_BR

dc.subject.other

Dental Prosthesis

pt_BR

dc.subject.other

Dental Materials

pt_BR

dc.subject.other

Biomedical and Dental Materials

pt_BR

dc.title

Próteses odontológicas associadas a Nanopartículas de Prata biogênicas: caracterização e atividade antimicrobiana

pt_BR

dc.title.alternative

Dental prostheses pssociated with biogenic silver Nanoparticles: characterization and antimicrobial activity

pt_BR

dc.type

Dissertação

pt_BR

dc.publisher.program

Programa de Pós-Graduação em Processos Interativos dos Órgãos e Sistemas (PPGORGSISTEM)

pt_BR

dc.publisher.initials

UFBA

pt_BR

dc.publisher.country

Brasil

pt_BR

dc.subject.cnpq

CNPQ::CIENCIAS BIOLOGICAS::MICROBIOLOGIA

pt_BR

dc.subject.cnpq

CNPQ::CIENCIAS DA SAUDE::ODONTOLOGIA

pt_BR

dc.contributor.advisor1

Antón, Ana Rita Sokolonski

dc.contributor.advisor1ID

https://orcid.org/0000-0001-8089-4128

pt_BR

dc.contributor.advisor1Lattes

http://lattes.cnpq.br/1228384941765961

pt_BR

dc.contributor.referee1

Antón, Ana Rita Sokolonski

dc.contributor.referee1ID

https://orcid.org/0000-0001-8089-4128

pt_BR

dc.contributor.referee1Lattes

http://lattes.cnpq.br/1228384941765961

pt_BR

dc.contributor.referee2

Lira, Andréa Fabiana de

dc.contributor.referee2ID

https://orcid.org/0000-0003-3945-2613

pt_BR

dc.contributor.referee2Lattes

http://lattes.cnpq.br/1727445128048492

pt_BR

dc.contributor.referee3

Gabler, Ilanna Guimarães

dc.contributor.referee3Lattes

http://lattes.cnpq.br/1670478079353578

pt_BR

dc.creator.ID

https://orcid.org/0009-0003-0504-7043

pt_BR

dc.creator.Lattes

http://lattes.cnpq.br/5347295247563620

pt_BR

dc.description.resumo

Introdução: O aumento da necessidade pelo uso de próteses dentárias faz com que as implicações deste tratamento estejam sobre o foco de muitas discussões clínicas e científicas na atualidade. Próteses mal adaptadas e traumatogênicas podem ser o fator etiológico principal de muitas enfermidades da cavidade oral. Diante disso, é necessário além de estimular a higiene, a exploração e desenvolvimento de novas tecnologias para tornar o PMMA antimicrobiano. O uso de AgNP biogênicas como tratamento de superfície da resina acrílica é uma das formas disruptivas e inovadoras de tornar uma prótese antimicrobiana. Objetivo: o presente estudo realizou a caracterização, atividade antimicrobiana, determinação da durabilidade e análise da rugosidade de corpos de prova de PMMA tratados com AgNP biogênicas. Material e métodos: Os espécimes confeccionados em resina acrílica temropolimerizável foram tratados com uma solução de AgNP biogênica sintetizada pelo fungo fusarium oxysporum em diferentes grupos de tratamento, em seguida foram analisadas as características físico-químicas da Nanopartícula, realizando teste de sensibilidade a antibióticos, ciclagem térmica, teste de contato direto modificado, avaliação de cor através de ensaio de espectofotometria e ensaio de rugosidade. Resultados: Os espécimes de resinas que receberam nanopartículas na massa total não apresentaram atividade antimicrobiana, apesar da incorporação de AgNP melhorar significativamente a rugosidade superficial da resina incolor. Os demais tratamentos de superfície apresentaram alta atividade antibacteriana e moderada atividade antifúngica. AgNP não foi capaz de provocar alterações de cor clinicamente significativas, apresentou apenas diminuição da saturação de vermelho na resina rosa. Conclusão: Os tratamentos de superfície com AgNP em resina acrílica termopolimerizável podem resistir até 30 dias na cavidade oral, não alteram a cor ou a rugosidade do material e apresentam alta atividade antimicrobiana, mais estudos precisam ser realizados para a determinação da atividade em períodos mais longos, situações mais desafiadoras e com outras espécies de NPM.

pt_BR

dc.publisher.department

Instituto de Ciências da Saúde - ICS

pt_BR

dc.relation.references

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