Nanofibers functionalized with surfactants to Eliminate SARS-CoV-2 and other airborne pathogens

Autores

  • Gustavo Cardoso da Mata UFSCar https://orcid.org/0000-0002-5843-8094
  • Daniela Sanches de Almeida Universidade Federal de São Carlos - UFSCAR
  • Wanderley Pereira de Oliveira Universidade de São Paulo - USP
  • Mônica Lopes Aguiar Universidade Federal de São Carlos - UFSCAR

DOI:

https://doi.org/10.53660/CONJ-708-A18

Palavras-chave:

SARS-CoV-2, Air filters, Electrospinning, Bioaerosols, Biocide

Resumo

The recent SARS-CoV-2 pandemic brought to light the difficulty in controlling the pathogenic bioaerosols present in the air. So, several studies have sought efficient and mainly sustainable technologies to develop new filtering media and new biocidal and virucidal agents. Filter media composed of nanofibers stand out for having high collection efficiencies and high permeability. For this reason, they have been widely used in filters for indoor environments and in face masks. Combined with nanofibers or conventional filtering media, the addition of quaternary ammonium surfactants to provide biocidal action proves to be an ecologically sustainable alternative. Thus, the present work reviews these filtering mechanisms, their applications, and perspectives for novel uses of these technologies in engineering and materials science.

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Biografia do Autor

Daniela Sanches de Almeida, Universidade Federal de São Carlos - UFSCAR

Graduada em Tecnologia em Processos Químicos (2013), Mestre em Engenharia Ambiental (2016) , ambos pela Universidade Tecnológica Federal do Paraná e Doutorado em Engenharia Química (2020) pela Universidade Estadual de Maringá. Atualmente é pesquisadora a nível de Pós-Doutorado na Universidade Federal de São Carlos atuando na área de controle de poluição atmosférica, em especial no desenvolvimento de meios filtrantes com ação biocida e virucida. Tem experiência no monitoramento e análises de exposição pessoal a poluentes atmosféricos, além de estudos utilizando membranas de nanofibras produzidas por eletrofiação.

Wanderley Pereira de Oliveira, Universidade de São Paulo - USP

Wanderley Pereira de Oliveira concluiu o Doutorado em Engenharia Química pela Universidade Federal de São Carlos em 1996. Realizou pós-doutorado na University of British Columbia (Vancouver - Canadá), no período 03/2006 a 04/2007. Realizou várias visitas técnicas em laboratórios de conceituadas instituições internacionais, que geraram vários trabalhos em colaboração. Atualmente e Professor Associado III da Universidade de São Paulo. Implantou e Coordenador do Laboratório de P&D em Processos Farmacêuticos da FCFRP/USP (LAPROFAR). Publicou 102 artigos em periódicos especializados e 212 trabalhos em anais/proceedings de eventos, sendo 105 completos. Possui 09 capítulos de livros publicados, sendo 07 internacionais, e é editor de 1 Livro Internacional (CRC Press). Editor do livro ?Phytotechnology A Sustainable Platform for the Development of Herbal Products?, publicado em 2021/2022 pela Taylor & Francis. Editor convidado da Edição especial ?Phytopharmaceutical Technology? da Revista Pharmaceutics (FI; 6,321), sendo também membro do ?Topical Advisory Panel? da seção ?Physical Pharmacy and Formulation?, desde 2021. Foi membro de Comissão Organizadora do International Drying Symposium (IDS 2004), do 12th International Congress on Pharmaceutical Sciences (CIFARP 2019). Organizou e coordenou o I Workshop on Phytopharmaceutical Technology, evento satélite do CIFARP 2019. Coordenou vários projetos de pesquisa tecnológica e atualmente coordena 1 projeto de pesquisa e participa como membro de 01 projeto CAPES/Endemias. Foi membro do INCT - Inovação Farmacêutica, do CNPq (INCT-IF) e do Projeto CNPq Instituto de Milênio Inovação e Desenvolvimento de Fármacos e Medicamentos (IM-INOFAR). Possui 03 patentes nacionais concedidas, 03 pedidos de patentes nacionais junto ao INPI e mais de 200 itens de produção bibliográfica, entre trabalhos completos em periódicos (104), em Proceedings de Eventos nacionais e Internacionais, apresentações em eventos, livros e capítulos de livros, e resumos em eventos. Participou de 30 eventos no exterior e 63 no Brasil. Orientou 13 dissertações de mestrado, 09 teses de doutorado, supervisionou 04 projetos de Pós-doutorado, 34 trabalhos de iniciação cientifica nas áreas de farmácia, engenharia química e engenharia agrícola, e 10 orientações de outra natureza. Orienta atualmente 04 Doutorados, 02 Mestrados, 05 Iniciação Cientificas. Recebeu 06 prêmios e/ou homenagem. Possui colaborações científicas com núcleos de excelência nacionais e internacionais, que tem gerado várias publicações na forma de artigos em revistas, capítulos de livros, e outras. Também tem realizado atividades de assessoria científica e prestação de serviços a empresas do setor produtivo. Atua nas áreas de farmácia e engenharia química, com ênfase em processos farmacêuticos e operações industriais e equipamentos para engenharia química. Em suas atividades profissionais interagiu com 110 colaboradores em co-autorias de trabalhos científicos. Em seu currículo Lattes, os termos mais freqüentes na contextualização da produção cientifica, tecnológica e artístico-cultural são: Sistemas de liberação de ativos naturais, nanoencapsulação, microencapsulação, secagem, leito de jorro, revestimento de partículas, spray drying, spouted bed, drying, extrato seco, reologia, medicinal plants, plantas medicinais e spray dryer. É Assessor Científico de Agências de Fomento Nacionais e Internacionais, e atua como revisor de vários periódicos científicos indexados, em diversas especialidades. É Editor de tópicos da Revista Pharmaceutics (FI 6,321). É membro do Bioencapsulation Research Group (http://bioencapsulation.net).

Mônica Lopes Aguiar, Universidade Federal de São Carlos - UFSCAR

Professora Titular do Departamento de Engenharia Química da Universidade Federal de São Carlos. Possui doutorado e mestrado em Engenharia Química pela Universidade Federal de São Carlos (1995, 1991) e graduação em Engenharia Química pela Universidade Federal de Uberlândia (1988). Atualmente é colaboradora da Universidade de São Paulo, colaboradora da Universidade Federal do Espírito Santo. Tem experiência na área de Engenharia Química, com ênfase em Operações de Separação e Mistura, atuando principalmente nos seguintes temas: filtração de ar e gases, filtros de tecido, filtros de mangas, nanofiltração, meios filtrantes, caracterização de partículas, monitoramento do ar atmosférico e indoor.

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2022-03-16

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Cardoso da Mata, G., de Almeida, D. S., Oliveira, W. P. de, & Aguiar, M. L. . (2022). Nanofibers functionalized with surfactants to Eliminate SARS-CoV-2 and other airborne pathogens. Conjecturas, 22(1), 1929–1961. https://doi.org/10.53660/CONJ-708-A18

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v. 22 n. 1 (2022): jan./fev. 2022

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