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42. | | BARBOZA, H. T. G.; SOARES, A. G.; FERREIRA, J. C. S.; FREITAS-SILVA, O. Filmes e revestimentos comestíveis: conceito, aplicação e uso na pós-colheita de frutas, legumes e vegetais. Research, Society and Development, v. 11, n. 9, e9911931418, 2022. Edible films and coatings: concept, application, and use in post-harvested fruits and vegetables. Películas y recubrimientos comestibles: concepto, aplicación y uso postcosecha de frutas y hortalizas. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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49. | | BITTENCOURT, A. M.; FARIAS, A. X.; FREITAS-SILVA, O.; ROCHA, E. S.; CORREA, T. B. S. Identificacao rapida de linhagens de Aspergillus flavus isoladas em graos de milho pos-colheita. In: CONGRESSO BRASILEIRO DE MICOLOGIA, 3., 2001, Aguas de Lindoia, SP. Micologia: desenvolvimento e perspectivas para o milenio. Sociedade Brasileira de Micologia, 2001. p.51, ref. AL.022. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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51. | | GOMES, I. A.; MARKOVÁ, E.; SILVA, J. P. L. da; VENÂNCIO, A.; FREITAS-SILVA, O. Global trends for patulin adsorption: A review. Research, Society and Development, v. 10, n. 6, e58310616162, 2021. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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53. | | PORTO, H.; OLIVEIRA, E. M. M.; MATOS, A.; CUNHA, F. Q. da; FREITAS-SILVA, O. B-tubulina: avaliação da amplificabilidade do DNA genômico obtidos por dois protocolos in-house da sequência conservada da via de biosíntese de fungos filamentosos produtores de aflatoxinas. Revista de Ciências da Vida, Seropédica, v. 28, p. 210-212, 2008. Suplemento. Edição do XIII Encontro Nacional de Micotoxinas, Rio de Janeiro, ago. 2008. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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57. | | CORREA, T. B. S.; FARIAS, A. X.; FREITAS-SILVA, O.; ASSAD, E. D.; VARGAS, E. A. Avaliacao da sanidade em sementes de amendoim quanto a presenca de fungos toxigenos e deteccao de aflatoxinas, em condicoes de cerrado. In: ENCONTRO NACIONAL DE MICOTOXINAS, 9., 1998, Florianopolis,. Livro de Resumos... Florianopolis, 1988. p.110. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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58. | | CORREA, T. B. S.; ROBBS, C. F.; BITTENCOURT, A. M.; FREITAS-SILVA, O. Controle biologico de Aspergillus na rizosfera do cafeeiro por acao antagonica de Trichoderma harzianum. In: SIMPOSIO DE PESQUISA DE CAFES DO BRASIL, 13., 2000, Pocos de Caldas, MG. Resumos expandidos... Brasilia: Embrapa Cafe.; MINISPLAN, 2000. v.1, p.26-29. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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59. | | FREITAS-SILVA, O.; SOARES, A. G.; ROZA, J. H. I.; SILVA, A. F. Cuantificación de las pérdidas bióticas en papayo (Carica papaya L.) comercializado en el Estado de Rio de Janeiro, Brasil. In: CONGRESO NACIONAL DE HORTICULTURA, 8.; SEMINARIO REGIONAL DE FRUTILLA, 2001, Salto, Uruguay. Resúmenes. Montevideo: Sociedad Uruguaya de Horticultura; Instituto Nacional de Investigación Agropecuaria, 2001. p. 85. Biblioteca(s): Embrapa Agroindústria de Alimentos. |
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Registro Completo
Biblioteca(s): |
Embrapa Agroindústria de Alimentos. |
Data corrente: |
07/12/2023 |
Data da última atualização: |
21/05/2024 |
Tipo da produção científica: |
Capítulo em Livro Técnico-Científico |
Autoria: |
FREITAS-SILVA, O.; COELHO, C. C. DE S.; RODRIGUES, J. P.; AMANCIO, D. F. |
Afiliação: |
OTNIEL FREITAS SILVA, CTAA; CAROLINE CORRÊA DE SOUZA COELHO, UNIVERSIDADE FEDERAL DO ESTADO DO RIO DE JANEIRO; JULIANA PEREIRA RODRIGUES, UNIVERSIDADE FEDERAL DO ESTADO DO RIO DE JANEIRO; DAIANA FERREIRA AMANCIO, UNIVERSIDADE FEDERAL DO ESTADO DO RIO DE JANEIRO. |
Título: |
Nanoscience and nanomaterials to control postharvest fungal diseases. |
Ano de publicação: |
2023 |
Fonte/Imprenta: |
In: RAI, M.; AVILA QUEZADO, G.D. (ed.). Nanotechnology in plant healt. Boca Raton: CRC PRESS, 2023. ch. 14, p. 211-235. |
Idioma: |
Inglês |
Conteúdo: |
During transport, distribution, and storage, fruits and vegetables suffer quality loss due to postharvest physiological reactions, such as respiration, maturation, ethylene production, and senescence. These reactions can lead to water loss, softening of tissues, color change, and degradation of nutrients, which usually depend on their physiological nature (climacteric and non-climacteric fruits), chemical composition, and surface structure. At the same time, along the distribution chain fruits and vegetables can suffer injury, triggering microbial growth, and reducing the shelf life of these perishable products (Mali and Grossmann 2003; Vu et al. 2011; Thakur et al. 2018). Although cold chain distribution is a way to minimize these reactions, this method may not be sufficient to mitigate quality losses of fruits and vegetables, prolong shelf life, and preserve sensory characteristics. Thus, the use of innovative technologies, such as nanotechnology, has been investigated to meet the needs of the market (Fakhouri et al. 2014; Rocha et al. 2019). Various studies have investigated the use of nanomaterials as technological tools to reduce postharvest deterioration. The use of nanoparticles has grown over the last few years due to their unique properties in relation to conventional materials at micro- and macro-scales. The protective properties of nanomaterials are due to their high surface area/volume ratio and their ability to incorporate biomolecules (Akhila et al. 2022; Pushparaj et al. 2022). MenosDuring transport, distribution, and storage, fruits and vegetables suffer quality loss due to postharvest physiological reactions, such as respiration, maturation, ethylene production, and senescence. These reactions can lead to water loss, softening of tissues, color change, and degradation of nutrients, which usually depend on their physiological nature (climacteric and non-climacteric fruits), chemical composition, and surface structure. At the same time, along the distribution chain fruits and vegetables can suffer injury, triggering microbial growth, and reducing the shelf life of these perishable products (Mali and Grossmann 2003; Vu et al. 2011; Thakur et al. 2018). Although cold chain distribution is a way to minimize these reactions, this method may not be sufficient to mitigate quality losses of fruits and vegetables, prolong shelf life, and preserve sensory characteristics. Thus, the use of innovative technologies, such as nanotechnology, has been investigated to meet the needs of the market (Fakhouri et al. 2014; Rocha et al. 2019). Various studies have investigated the use of nanomaterials as technological tools to reduce postharvest deterioration. The use of nanoparticles has grown over the last few years due to their unique properties in relation to conventional materials at micro- and macro-scales. The protective properties of nanomaterials are due to their high surface area/volume ratio and their ability to incorporate biomolecules (Akhila et al. 2022; Pushp... Mostrar Tudo |
Thesaurus NAL: |
Antifungal agents; Postharvest diseases; Postharvest systems; Postharvest technology; Postharvest treatment. |
Categoria do assunto: |
Q Alimentos e Nutrição Humana |
Marc: |
LEADER 02240naa a2200217 a 4500 001 2159262 005 2024-05-21 008 2023 bl uuuu u00u1 u #d 100 1 $aFREITAS-SILVA, O. 245 $aNanoscience and nanomaterials to control postharvest fungal diseases.$h[electronic resource] 260 $c2023 520 $aDuring transport, distribution, and storage, fruits and vegetables suffer quality loss due to postharvest physiological reactions, such as respiration, maturation, ethylene production, and senescence. These reactions can lead to water loss, softening of tissues, color change, and degradation of nutrients, which usually depend on their physiological nature (climacteric and non-climacteric fruits), chemical composition, and surface structure. At the same time, along the distribution chain fruits and vegetables can suffer injury, triggering microbial growth, and reducing the shelf life of these perishable products (Mali and Grossmann 2003; Vu et al. 2011; Thakur et al. 2018). Although cold chain distribution is a way to minimize these reactions, this method may not be sufficient to mitigate quality losses of fruits and vegetables, prolong shelf life, and preserve sensory characteristics. Thus, the use of innovative technologies, such as nanotechnology, has been investigated to meet the needs of the market (Fakhouri et al. 2014; Rocha et al. 2019). Various studies have investigated the use of nanomaterials as technological tools to reduce postharvest deterioration. The use of nanoparticles has grown over the last few years due to their unique properties in relation to conventional materials at micro- and macro-scales. The protective properties of nanomaterials are due to their high surface area/volume ratio and their ability to incorporate biomolecules (Akhila et al. 2022; Pushparaj et al. 2022). 650 $aAntifungal agents 650 $aPostharvest diseases 650 $aPostharvest systems 650 $aPostharvest technology 650 $aPostharvest treatment 700 1 $aCOELHO, C. C. DE S. 700 1 $aRODRIGUES, J. P. 700 1 $aAMANCIO, D. F. 773 $tIn: RAI, M.; AVILA QUEZADO, G.D. (ed.). Nanotechnology in plant healt. Boca Raton: CRC PRESS, 2023. ch. 14, p. 211-235.
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