Tatiany J. de Faria scite author profile

g Nanoenabled drug delivery systems against tuberculosis (TB) are thought to control pathogen replication by targeting antibiotics to infected tissues and phagocytes. However, whether nanoparticle (NP)-based carriers directly interact with Mycobacterium tuberculosis and how such drug delivery systems induce intracellular bacterial killing by macrophages is not defined. In the present study, we demonstrated that a highly hydrophobic citral-derived isoniazid analogue, termed JVA, significantly increases nanoencapsulation and inhibits M. tuberculosis growth by enhancing intracellular drug bioavailability. Importantly, confocal and atomic force microscopy analyses revealed that JVA-NPs associate with both intracellular M. tuberculosis and cell-free bacteria, indicating that NPs directly interact with the bacterium. Taken together, these data reveal a nanotechnology-based strategy that promotes antibiotic targeting into replicating extra-and intracellular mycobacteria, which could actively enhance chemotherapy during active TB.

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Preparation and Characterization of Poly(D,L‐Lactide) (PLA) and Poly(D,L‐Lactide)‐Poly(Ethylene Glycol) (PLA‐PEG) Nanocapsules Containing Antitumoral Agent Methotrexate

Faria

Campos

Lemos‐Senna

2005

Macromolecular Symposia

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Summary: The aims of the present work were to prepare and characterize nanocapsules containing antitumoral agent methotrexate (MTX) from poly(D,L‐lactide) (PLA) and poly(D,L‐lactide)‐poly(ethylene glycol) diblock copolymer (PLA‐PEG) with the purpose of administrating this drug by topical ocular route for primary ocular lymphoma treatment. Nanocapsules were prepared by the interfacial deposition of preformed polymer. The influences of the initial amount of MTX on the encapsulation efficiency, drug recovery and drug content, as well as the physicochemical properties of the particles were evaluated. The particle mean diameters were 246 and 146 nm, and zeta potential values were −38.8 and −33.6 mV, for the MTX‐loaded nanocapsules prepared from PLA and PLA‐PEG, respectively. The methotrexate content in the particles increased with the increasing in the drug amount added to the formulations, but the drug recovery decreased significantly. After 4 h of in vitro release, 28 and 86% of MTX was released from PLA and PLA‐PEG nanocapsules, respectively.

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PLLA/PMMA blend in polymer nanoparticles: influence of processing methods

Peres

Faria

et al. 2017

Colloid Polym Sci

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Evaluation of the pro-inflammatory potential of nanostructured drug carriers in knee-joints of rats: Effect on nociception, edema, and cell migration

Faria

Souza-Silva

Oliveira

et al. 2009

Journal of Pharmaceutical Sciences

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Estudo de formulação de microesferas de acetobutirato de celulose com diferentes concentrações de Poloxamer 188

Araújo

Faria

Lemos‐Senna

2013

Semin. Cienc. Biol. Saude

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Microesferas de liberação prolongada de diclofenaco de sódio (DFS) foram preparadas empregando o acetobutirato de celulose (ABC) para obtenção da matriz polimérica. Buscando modular a velocidade de liberação do fármaco, a adição de Poloxamer 188 na formulação foi testada, com diferentes proporções de ABC: Pluronic F68 (1:0; 9:1; 3:1 e 1:1). Com exceção da formulação contendo ABC e Pluronic F68 na proporção de 1:1, as outras formulações testadas conduziram à formação de partículas esféricas de tamanho micrométrico. Quando a mistura ABC: Pluronic F68 (1:1) foi empregada, ocorreu à precipitação de uma massa polimérica, sendo este efeito relacionado à elevada concentração do polímero hidrofílico na preparação. Quando comparado com as microesferas preparadas unicamente com ABC, o teor e a eficiência de encapsulação aumentaram com o acréscimo de Poloxamer 188 às formulações. Efeito semelhante foi observado na avaliação da velocidade de liberação do fármaco em meio tampão fosfato pH 7,5. Enquanto as microesferas preparadas apenas com ABC conduziram à liberação de 25% do fármaco encapsulado após 12 horas de ensaio, as microesferas preparadas com relação ABC:Pluronic 9:1 e 3:1 conduziram à liberação de 30% e 70% do fármaco, respectivamente. Palavras-chave: Microesferas. Diclofenaco de sódio. Poloxamer 188. Acetobutirato de celulose. AbstractExtended-release microspheres containing sodium diclofenac were prepared using the cellulose acetate butyrate (CAB) to obtain the polymer matrix. Looking modulate the rate of drug release, the addition of Poloxamer 188 at different concentrations into formulations was tested in order to obtain CAB to Poloxamer ratio of 1:0, 9:1, 3:1 and 1:1. Excepting for the formulation containing CAB and Poloxamer 1:1, the other formulations resulted in formation of spherical particles of micrometer size range. When the mixture CAB:Poloxamer (1:1) was employed, the precipitation of a polymeric mass occorred, and this effect was related to the high concentration of the hydrophilic polymer in the preparation. When compared to the microspheres prepared only with CAB, the drug content and the encapsulation efficiency increased with the addition of Poloxamer 188 in the formulations. A similar effect was observed in the evaluation of the rate of drug release in pH 7.5 phosphate buffer. While the microspheres prepared with CAB led to release of 25% of the encapsulated drug after 12 hours of testing, the microspheres prepared with CAB: Poloxamer 9:1 and 3:1 resulted in release of 30% and 70% of the drug, respectively.

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