Response Surface Methodology: An Optimization of Process Variables for the Nanoencapsulation of Anthocyanins from Black Rice Bran

R. M. Bulatao, P. Eugenio, John Paulo A. Samin, J. R. Salazar, J. Monserate
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Abstract

Nanoencapsulation technology has been used in food and pharmaceutical applications to increase bioactive chemical functioning and stability against external influences. To develop a cost-effective encapsulating procedure, additional optimization is required. This study employed response surface methodology (RSM) to optimize the encapsulation of anthocyanin-rich extract from black rice bran. The extract was encapsulated through pre-gelation and polyelectrolyte complex formation processes. Box-Behnken design was employed to determine the optimum conditions for the encapsulation process with the following process variables: chitosan concentration, pH, and CaCl2 concentration. Chemical characteristics, surface morphology, and particle size were used to describe the resultant capsules, which were then subjected to phytochemical analysis. The optimal encapsulation conditions for anthocyanin were 6.30 mg/mL chitosan, pH 5.5, and 36 mM CaCl2, with a 51.20 % encapsulation efficiency. The developed anthocyanin-loaded nanocapsule has a high TPC (3.87 mg GAE/g) and potent antioxidant activity (5.69 mg TE/g). SEM images revealed a smooth surface area and spherical particles that clumped together, with an average particle size of 94.70 nm. FTIR analysis corroborates the well-incorporation of anthocyanin into the nanocapsules. The encapsulation process of anthocyanin-rich extract from black rice bran was successfully optimized via RSM.
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响应面方法学:黑米糠花青素纳米封装工艺变量优化
纳米封装技术已被应用于食品和医药领域,以提高生物活性化学功能和稳定性,抵御外部影响。要开发出具有成本效益的封装程序,还需要进行额外的优化。本研究采用响应面方法(RSM)优化了黑米糠中富含花青素提取物的封装。通过预凝胶和聚电解质复合物形成过程对提取物进行封装。采用 Box-Behnken 设计来确定封装过程的最佳条件,其中包括以下过程变量:壳聚糖浓度、pH 值和 CaCl2 浓度。用化学特征、表面形态和粒度来描述所得胶囊,然后对胶囊进行植物化学分析。花青素的最佳封装条件为 6.30 mg/mL壳聚糖、pH 5.5 和 36 mM CaCl2,封装效率为 51.20%。所开发的花青素负载纳米胶囊具有较高的 TPC(3.87 毫克 GAE/克)和较强的抗氧化活性(5.69 毫克 TE/克)。扫描电子显微镜图像显示,纳米胶囊表面光滑,颗粒呈球形,并聚集在一起,平均粒径为 94.70 nm。傅立叶变换红外光谱分析证实了花青素与纳米胶囊的良好结合。通过 RSM 成功优化了富含花青素的黑米糠提取物的封装工艺。
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