BEATRIZ KUCHINSKI CAVALCANTE

Projetos de Pesquisa
Unidades Organizacionais
Cargo

Filtros

20182
Limpar filtros

Configurações

Data inicial: 2018 × Autor: ADEMAR BENEVOLO LUGAO ×

Resultados de Busca

Agora exibindo 1 - 2 de 2
  • Imagem de Miniatura
    Resumo IPEN-doc 25921
    In vitro and in vivo toxicity evaluation of silver nanoparticles stabilized with gum arabic
    2018 - MAZIERO, J.S.; CAVALCANTE, A.K.; MARTINI, G.A.; DAMASCENO, K.C.; ORMENIO, M.B.; CAVALCANTE, B.K.; ROGERO, S.O.; ROGERO, J.R.; LUGAO, A.B.
    Due to its properties such as size, varied shape, high surface area and high bactericidal properties, silver nanoparticles (AgNP) have been widely used in several sectors of the industry: bandages; inside food coolers, to retard spoilage; in antimicrobial insoles, to prevent odors; in air purifiers; in surgical instruments and etc [1] [2]. Considering the range of applications a great concern in the academic field, mainly ecotoxicological, as the potential impacts and risks that AgNP can cause to the environment and human health has increased. During the synthesis of AgNP it is necessary to use stabilizing agents such as gum arabic (GA), which is an exudate of dried gum, edible, from the stems and branches of Acacia senegal and A. seyal, rich in soluble fiber not viscous. GA has broad industrial use as stabilizer, thickening agent and emulsifier [3]. Based on these considerations, this work aimed to verify and compare the toxicity level of two GA-stabilized AgNP samples (Sample 1: AgNP at 147 ppm concentration, approximately 25 nm in size; and Sample 2: AgNP at concentration of 174 ppm with approximate size of 75 nm) using in vitro and in vivo assays. The in vitro cytotoxicity test was performed according to ISO 10993-5 by the neutral red uptake method in cells of the NCTC-L929 line, to obtain the IC50 (cytotoxicity index, which is the concentration of the substance causing it 50% mortality of exposed cells); and the in vivo acute ecotoxicity assay, according to the Brazilian standard ABNT NBR 12713, using Daphnia similis as the test organism to obtain EC50 (effective concentration that causes immobility in 50% of exposed organisms). The results obtained for Sample 1 were IC50 of 2.57 mg L-1 and EC50 of 4.40 μg L-1; and Sample 2: IC50 of 2.61 mg L-1 and EC50 of 6.55 μg L-1. These results demonstrated that aquatic organisms are much more sensitive to AgNP than cells in culture, raising the importance of conducting further studies related to the adversities that these nanoparticles can cause to the environment and human health. In addition, it is necessary to verify the disposal of the same in the environment, since in Brazil there are still no legislation that quantifies the permissible limits for this disposal.
  • Imagem de Miniatura
    Resumo IPEN-doc 25916
    Evaluation of the toxicity of gold nanoparticles produced by green nanotechnology in Zebrafish (Danio rerio)
    2018 - CAVALCANTE, A.K.; BATISTA, J.G.S.; MAZIERO, J.S.; DAMASCENO, K.C.; ORMENIO, M.B.; CAVALCANTE, B.K.; ROGERO, S.O.; ROGERO, J.R.; LUGAO, A.B.
    Gold nanoparticles (AuNPs) of different sizes and shapes have been extensively studied by researchers and laboratories around the world. Several studies have demonstrated the applicability of gold nanoparticles in the treatment and diagnosis of cancer, in the treatment of chronic inflammation, infections, degenerative diseases and autoimmune diseases [1]. The synthesis of AuNPs generally involves reducing agents which present problems related to toxicity. In order to address this issue, metabolites present in various plant extracts have been exploited for the preparation of different nanoparticles. The methods that use phytochemicals to reduce metal ions provide a green approach to nanotechnology, known as green nanotechnology [2]. Researchers have shown that some phytochemicals, such as mangiferin (MGF) and epigallocatechin-gallate (EGCG), in addition to reducing and stabilizing the gold nanoparticles, are able to functionalize them. These molecules have chemical groups that allow binding to overexpressed receptors on some types of tumor cells [3]. The objective of this study was to evaluate the level of toxicity of the gold nanoparticles, reduced and stabilized with epigallocatechin-gallate (EGCG-AuNPs) in Zebrafish embryos (Danio rerio), as an indication of a possible environmental effect. To assess the developmental impact of embryos, organisms were exposed to different dilutions of the EGCG-AuNPs suspension for a 96-hour period according to OECD Protocol 236 (Fish Embryo Acute Toxicity Test-FET). Zebrafish is an established vertebrate model for the study of development, disease and is being increasingly used for both pre-clinical studies and toxicological applications due to a range of favorable traits [4]. EGCG-AuNPs demonstrated toxicity, with organ lethality being less than 33% at all concentrations used. The work provided a contribution on the toxicity of AuNPs synthesized and stabilized with the epigallocatechin-gallate reducing agent and using Zebrafish embryos as an animal.