OPTIMIZATION AND CHARACTERIZATION OF MICROSPHERES OF BERBERINE HYDROCHLORIDE USING BOX-BEHNKEN DESIGN

Q2 Pharmacology, Toxicology and Pharmaceutics

International Journal of Applied Pharmaceutics Pub Date : 2024-01-07 DOI:10.22159/ijap.2024v16i1.49254

Gautam Kumar, Narendra Kumar Pandey, Vijay Mishra, Suraj Pal Verma, Jitender Singh, BIMLESH KUMAR, Sachin Kumar Singh, D. S. Baghel, Kalvatala Sudhakar, Saurabh Singh

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引用次数: 0

Abstract

Objective: The current work sought to optimize Berberine hydrochloride (BBH)-loaded microspheres by examining the link between design parameters and experimental results. Methods: BBH-loaded microspheres were prepared by using the water-in-oil emulsion cross-linking process and optimized with a three-factor, three-level Box-Behnken design (BBD). Grafted gum polyvinyl alcohol (PVA) ratio (w/w) (A), Revolutions per minute (RPM) (B), and Span 20 (%) (C) were independent variables. The dependent variables were Percent Entrapment Efficiency (% EE) (R1), Percent Drug Loading (% DL) (R2), and Particle Size (µm) (R3). The generated polynomial equations and response surface plots were used to relate the dependent and independent variables. Microscopic examination, %EE, and % DL were determined to evaluate the optimized formulation. Fourier transforms infrared (FT-IR) spectroscopy studies and stability studies of optimized formulation were also carried out. Results: The optimized formulation (FMS6) had a polymer content of 2% w/v [Grafted gum (36.96): PVA (63.04)], a span 20 (0.78 %), and a prepared at the speed of 1225.92 rpm. The observed responses were close to the improved formulation's predicted values. The particle size, % EE, and % DL were found to be 1.10 µm, 82.79% and 16.48%, respectively. FT-IR spectroscopy study indicated that the drug was entrapped in microspheres. Conclusion: BBD provides a systematic approach to optimize the BBH microsphere preparation process. Additionally, the stability study results confirmed that FMS6 is not only the ideal formulation but also stable, ensuring its suitability for practical applications.

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采用盒-贝肯设计优化盐酸小檗碱微球并确定其特性

目的本研究试图通过研究设计参数与实验结果之间的联系来优化盐酸小檗碱（BBH）负载微球：方法：采用油包水型乳液交联工艺制备盐酸小檗碱（BBH）负载微球，并通过三因素、三级方框-贝肯设计（BBD）进行优化。接枝胶聚乙烯醇（PVA）比率（w/w）（A）、每分钟转数（RPM）（B）和跨度 20（%）（C）为自变量。因变量为包埋效率百分比 (% EE) (R1)、药物负载百分比 (% DL) (R2) 和颗粒尺寸 (µm) (R3)。生成的多项式方程和响应面图用于将因变量和自变量联系起来。通过显微镜检查、确定 %EE 和 % DL 来评估优化配方。此外，还对优化配方进行了傅立叶变换红外光谱（FT-IR）研究和稳定性研究：优化配方（FMS6）的聚合物含量为 2% w/v[接枝胶（36.96）：PVA（63.04）]，跨度为 20（0.78%），制备速度为 1225.92 rpm。观察到的反应接近改进配方的预测值。粒度、EE % 和 DL % 分别为 1.10 µm、82.79% 和 16.48%。傅立叶变换红外光谱研究表明，药物被包裹在微球中：BBD为优化BBH微球的制备过程提供了一种系统方法。此外，稳定性研究结果证实，FMS6 不仅是理想的制剂，而且非常稳定，确保了其在实际应用中的适用性。

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来源期刊

International Journal of Applied Pharmaceutics Pharmacology, Toxicology and Pharmaceutics-Pharmacology, Toxicology and Pharmaceutics (miscellaneous)

CiteScore

1.40

自引率

0.00%

发文量

219

期刊介绍： International Journal of Applied Pharmaceutics (Int J App Pharm) is a peer-reviewed, bimonthly (onward March 2017) open access journal devoted to the excellence and research in the pure pharmaceutics. This Journal publishes original research work that contributes significantly to further the scientific knowledge in conventional dosage forms, formulation development and characterization, controlled and novel drug delivery, biopharmaceutics, pharmacokinetics, molecular drug design, polymer-based drug delivery, nanotechnology, nanocarrier based drug delivery, novel routes and modes of delivery; responsive delivery systems, prodrug design, development and characterization of the targeted drug delivery systems, ligand carrier interactions etc. However, the other areas which are related to the pharmaceutics are also entertained includes physical pharmacy and API (active pharmaceutical ingredients) analysis. The Journal publishes original research work either as a Original Article or as a Short Communication. Review Articles on a current topic in the said fields are also considered for publication in the Journal.