提高酮洛芬的溶解度:使用固体分散和响应面方法的战略方法。

IF 1.5 4区 医学 Q3 PHARMACOLOGY & PHARMACY
Devika Tripathi, Dinesh Kumar Sharma, Jagannath Sahoo
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引用次数: 0

摘要

背景:在制药科学中,治疗分子的溶解度曲线对于确定和配制药物以及根据口服生物利用度、代谢转化、生物分布动力学和潜在的毒理学影响等因素评估药物质量至关重要。本研究旨在提高酮洛芬(BCS-II 类)的溶解度参数,因为酮洛芬具有低溶解度和高渗透性:方法:本方法采用芳香族苯甲酸钠和电解质醋酸钠的水托混合物来提高酮洛芬的溶解度参数。采用溶剂蒸发法制备了多批酮洛芬固体分散体,并采用响应面法 3² 因式设计找到了最佳配方。对优化后的配方 KSD9 进行了体外药物溶解、DSC、pXRD 和 SEM 研究:结果:优化后的批次大大提高了酮洛芬的溶解度,这归功于混合水化作用。结果表明,使用水托剂后,溶解度和CDR%都有所提高,这表明溶解度和CDR%的提高成正比。制剂 KSD1-KSD9 的溶解度提高了 2.23 至 5.77 倍,CDR%也从 72.28% 提高到 94.76%。这意味着 CDR 百分比受水力介质的调节,特别是受自变量浓度水平的影响。水力介质浓度的增加对应于 CDR 百分比的增加。CDR%二次方程中的正系数强调了这些自变量在增加酮洛芬体外释放中的重要作用。同样,在溶出度比较研究中,与传统的酮洛芬分散片相比,优化后的 KSD9 制剂在溶出度和药物含量方面都有显著提高:結論:結合兩種促水劑的協同效應可顯著提高酮洛芬的溶解度達 58 倍。结果表明,自变量对溶解度和 CDR%产生了积极影响。此外,反应还取决于作为自变量的特定水处理剂的选择。分析 r² 和方差分析结果表明,因变量与所选模型非常吻合。三维响应面图和等值线图等可视化图示显示了每种水力措施单独使用和组合使用时的影响。总体而言,使用水力喷射剂提高了溶解度和 CDR%,突出了溶解度和 CDR%之间的正比关系。混合水托品降低了与单独水托品浓度相关的毒性,同时也提供了一种可持续的环保替代品。这项研究为今后旨在提高低溶解度药物溶解度的研究铺平了道路,从而扩大了这些药物的临床应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhancing Ketoprofen Solubility: A Strategic Approach Using Solid Dispersion and Response Surface Methodology.

Background: In the pharmaceutical sciences, the solubility profile of therapeutic molecules is crucial for identifying and formulating drugs and evaluating their quality across the drug discovery pipeline based on factors like oral bioavailability, metabolic transformation, biodistribution kinetics, and potential toxicological implications. The investigation aims to enhance the solubility parameters of ketoprofen (BCS-II class), which exhibits low solubility and high permeability.

Methods: In this method, hydrotrope blends of aromatic sodium benzoate and electrolyte sodium acetate were employed to enhance the solubility parameter of ketoprofen. Several batches of solid dispersion of ketoprofen were made using a solvent evaporation method, and the response surface method 3² factorial design was used to find the best one. The optimised formulation, KSD9, underwent in-vitro drug dissolution, DSC, pXRD, and SEM studies.

Results: The optimized batch demonstrated substantial improvement in ketoprofen solubility, attributed to mixed hydrotropy. The results indicated that both solubility and %CDR improved when hydrotropes were employed, suggesting a direct proportionality between the rise in solubility and %CDR. Formulations KSD1-KSD9 exhibited solubility enhancements ranging from 2.23 to 5.77-fold, along with an elevation in %CDR from 72.28% to 94.76%. This implies that the %CDR was modulated by the hydrotropes, specifically influenced by the concentration levels of the independent variables. An increase in hydrotrope levels corresponded to an increase in %CDR. The positive coefficients in the quadratic equation for %CDR underscored the significant role of these independent variables in augmenting the in-vitro release of Ketoprofen. Similarly, during a comparative dissolution investigation, the optimized KSD9 formulation exhibited remarkable solubility and drug content compared to conventional Ketoprofen dispersible tablets.

Conclusion: The synergistic effect of combining two hydrotropic agents significantly increased the solubility of ketoprofen by up to 58 times. The results indicated that the independent variables exerted a positive influence on solubility and %CDR. Furthermore, the responses were contingent on the specific hydrotropes selected, which functioned as the independent variables. Analyzing the r² and ANOVA results suggested that the dependent variables aligned well with the chosen model. Visual representations, such as the 3D response surface plot and contour plot, demonstrated the impact of each hydrotrope individually and when combined. Overall, employing hydrotropes led to improved solubility and %CDR, highlighting a direct proportionality between the rise in solubility and %CDR. Mixed hydrotropic lessens the toxicity associated with individual hydrotrope concentrations while also offering a sustainable and eco-friendly alternative. This study paves the way for future research aiming to improve the solubility of low- solubility drugs, broadening their clinical applications.

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来源期刊
Current radiopharmaceuticals
Current radiopharmaceuticals PHARMACOLOGY & PHARMACY-
CiteScore
3.20
自引率
4.30%
发文量
43
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