Experimental Investigation on Efficacy of Eudragit RS 100 Polymer in Prolonging Glibenclamide Release by Intragastric Floating Microsphere Formulation and Physicochemical Evaluation

Devika Tripathi, Princy Yadav, Gauransh Mishra, A. Rai
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Abstract

The amalgamation of targeted transportation and enhancement of the release profile of the active pharmaceutical ingredient is a contemporary trend in the evolution of oral medicinal products. A renowned method to actualize this concept is to develop floating gastroretentive delivery systems that ensure an extended stay of the dosage form on the gastric surface. The success of drug delivery is largely dependent on the type of polymer used that sustains the release and avoids any toxic effects. Intragastric floating drug delivery systems are designed to remain buoyant in the stomach without affecting the gastric emptying rate for a prolonged period. This allows for a slow release of the drug in the stomach, which can be particularly beneficial for drugs with a narrow absorption window, like Glibenclamide, an anti-diabetic medication. The current research focused on the sustained drug delivery of Glibenclamide as intragastric floating microspheres. The goal was to adjust the floatation and drug release pattern using Eudragit RS 100 and magnesium stearate as a droplet stabilizer. Different batches of floating microspheres were optimized based on the polymer, drug-polymer concentration, and the amount of magnesium stearate. The strategy aimed to enhance the effectiveness of Glibenclamide, particularly for individuals with diabetes, by facilitating a controlled and consistent release of the drug in the gastric environment. The solvent evaporation method was used to create four batches of intragastric microspheres. The maximum absorbance of the drug, also known as lambda max, was observed at 212 nm. The prepared batches were evaluated for various in-vitro physicochemical parameters. The average particle size was found to be 619 nm. Rheological studies indicated excellent flow properties. The microspheres exhibited in-vitro buoyancy for up to 7 hours The entrapment efficiency was as high as 93.19%. Scanning Electron Microscopy (SEM) analysis revealed that the microspheres have a porous structure, which allows for the easy movement of solvents and solutes into and out of the microspheres. Differential Scanning Calorimetry (DSC) and Thermogravimetric Analysis (TGA) indicated the physical and chemical properties of the microspheres. All in-vitro drug release and kinetic studies for the optimized batch (F-M4) revealed that Eudragit RS 100 effectively sustained the intragastric delivery of Glibenclamide. Floating drug delivery systems enhance oral dosage forms and the range of APIs by ensuring targeted gastric delivery and modified release. This improves bioavailability, reduces drug losses, and partially mitigates side effects.
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Eudragit RS 100 聚合物通过胃内漂浮微球配方延长格列本脲释放时间的功效实验研究与理化评价
将有针对性的运输和提高活性药物成分的释放性能结合起来,是口服药物发展的当代趋势。实现这一概念的著名方法是开发浮动胃牵引给药系统,以确保剂型在胃表面的长时间停留。药物输送的成功与否在很大程度上取决于所使用的聚合物类型,这种聚合物能维持药物的释放并避免任何毒性作用。胃内漂浮给药系统的设计目的是在不影响胃排空率的情况下在胃内长期保持浮力。目前的研究重点是以胃内漂浮微球的形式持续给药格列本脲。目前的研究重点是格列本脲作为胃内漂浮微球的持续给药,目标是使用 Eudragit RS 100 和硬脂酸镁作为液滴稳定剂来调整漂浮和药物释放模式。根据聚合物、药物-聚合物浓度和硬脂酸镁的用量,对不同批次的漂浮微球进行了优化。该策略旨在通过促进药物在胃内环境中的可控和稳定释放,提高格列本脲的疗效,尤其是对糖尿病患者。在 212 纳米波长处观察到了药物的最大吸光度,也称为 lambda max。对制备的各批次药物进行了各种体外理化参数评估,发现平均粒径为 619 nm。流变学研究表明微球具有良好的流动性。微球在体外具有长达 7 小时的浮力,包埋效率高达 93.19%。扫描电子显微镜(SEM)分析表明,微球具有多孔结构,使溶剂和溶质易于进出微球。差示扫描量热法(DSC)和热重分析法(TGA)显示了微球的物理和化学特性。对优化批次(F-M4)进行的所有体外药物释放和动力学研究表明,Eudragit RS 100 能有效维持格列本脲的胃内给药。浮动给药系统通过定向胃内给药和改变释放方式,提高了口服剂型和原料药的范围,从而改善了生物利用度,减少了药物流失,并部分减轻了副作用。
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来源期刊
Micro and Nanosystems
Micro and Nanosystems Engineering-Building and Construction
CiteScore
1.60
自引率
0.00%
发文量
50
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