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W1958608613 abstract "Poly ε-caprolactone nanoparticles loaded with Uncaria tomentosa extract: preparation, characterization, and optimization using the Box–Behnken design Ana Ferreira Ribeiro, Ricardo Leite de Oliveira Rezende, Lúcio Mendes Cabral, Valéria Pereira de SousaDepartment of Pharmaceutics, Faculty of Pharmacy, Federal University of Rio de Janeiro, Rio de Janeiro, BrazilPurpose: The aim of this research was to develop and optimize a process for obtaining poly ε-caprolactone (PCL) nanoparticles loaded with Uncaria tomentosa (UT) extract.Methods: Nanoparticles were produced by the oil-in-water emulsion solvent evaporation method. Preliminary experiments determined the initial conditions of the organic phase (OP) and of the aqueous phase (AP) that would be utilized for this study. Ultimately, a three-factor three-level Box–Behnken design (BBD) was employed during the optimization process. PCL and polyvinyl alcohol (PVA) concentrations (X1 and X2, respectively) and the AP/OP volume ratio (X3) were the independent variables studied, while entrapment efficiency (Y1), particle mean diameter (Y2), polydispersity (Y3), and zeta potential (Y4) served as the evaluated responses.Results: Preliminary experiments revealed that the optimal initial conditions for the preparation of nanoparticles were as follows: OP composed of 5 mL ethyl acetate/acetone (3/2) mixture containing UT extract and PCL, and an AP of buffered PVA (pH 7.5) solution. Statistical analysis of the BBD results indicated that all of the studied factors had significant effects on the responses Y1, Y2, and Y4, and these effects are closely described or fitted by regression equations. Based on the obtained models and the selected desirability function, the nanoparticles were optimized to maximize Y1 and minimize Y2. These optimal conditions were achieved using 3% (w/v) PCL, 1% (w/v) PVA, and an AP/OP ratio of 1.7, with predicted values of 89.1% for Y1 and 280 nm for Y2. Another batch was produced under the same optimal conditions. The entrapment efficiency of this new batch was measured at 81.6% (Y1) and the particles had a mean size of 247 nm (Y2) and a polydispersity index of 0.062 (Y3).Conclusion: This investigation obtained UT-loaded nanoparticle formulations with desired characteristics. The BBD approach was a useful tool for nanoparticle development and optimization, and thus should be useful especially in the realm of phytotherapeutics, in which varied compositions may be assessed in quantitative and qualitative terms.Keywords: PCL, design of experiments, anti-tumorigenic, cat's claw, nanochemoprevention" @default.
W1958608613 created "2016-06-24" @default.
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W1958608613 date "2013-01-01" @default.
W1958608613 modified "2023-09-25" @default.
W1958608613 title "Poly ε-caprolactone nanoparticles loaded with Uncaria tomentosa extract: preparation, characterization, and optimization using the Box–Behnken design" @default.
W1958608613 cites W1966225030 @default.
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W1958608613 cites W1967435512 @default.
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W1958608613 cites W1980998274 @default.
W1958608613 cites W1982974605 @default.
W1958608613 cites W1984418916 @default.
W1958608613 cites W1987058852 @default.
W1958608613 cites W1990455420 @default.
W1958608613 cites W1995404096 @default.
W1958608613 cites W2003275588 @default.
W1958608613 cites W2006288240 @default.
W1958608613 cites W2006920458 @default.
W1958608613 cites W2007524359 @default.
W1958608613 cites W2009974403 @default.
W1958608613 cites W2010908849 @default.
W1958608613 cites W2011259879 @default.
W1958608613 cites W2013841546 @default.
W1958608613 cites W2015334077 @default.
W1958608613 cites W2019217706 @default.
W1958608613 cites W2022015635 @default.
W1958608613 cites W2022634779 @default.
W1958608613 cites W2023141576 @default.
W1958608613 cites W2025665604 @default.
W1958608613 cites W2038674347 @default.
W1958608613 cites W2047517907 @default.
W1958608613 cites W2049887749 @default.
W1958608613 cites W2051305606 @default.
W1958608613 cites W2058735358 @default.
W1958608613 cites W2062476487 @default.
W1958608613 cites W2066685510 @default.
W1958608613 cites W2074968605 @default.
W1958608613 cites W2079145795 @default.
W1958608613 cites W2081932329 @default.
W1958608613 cites W2084449190 @default.
W1958608613 cites W2094970696 @default.
W1958608613 cites W2140821114 @default.
W1958608613 cites W2151014676 @default.
W1958608613 cites W2163260744 @default.
W1958608613 cites W76381209 @default.
W1958608613 doi "https://doi.org/10.2147/ijn.s38491" @default.
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