Optimization of Glyburide-Loaded Nanosuspensions via Ball Milling and Homogenization Techniques: A Central Composite Design Approach for Enhanced Solubility.

IF 2.6 4区 医学 Q2 PHARMACOLOGY & PHARMACY Current pharmaceutical design Pub Date : 2024-09-20 DOI:10.2174/0113816128321501240828054050
Damla Gungor, Eren Aytekin, Yagmur Akdag, Selma Sahin, Tugba Gulsun
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Abstract

Introduction: Glyburide is a drug for the treatment of diabetes mellitus and has a potential effect on Alzheimer's disease. It is also a BCS Class 2 drug with low solubility and low permeability. Developing a nanosuspension formulation and increasing the solubility and dissolution rate of glyburide is required to overcome this challenge.

Methods: Thus, the goal of this work was to create glyburide nanosuspensions by ball milling and homogenizing glyburide to increase its solubility and rate of dissolution. To achieve this, the nanosuspension formulation was optimized using a central composite design. Zeta potential, particle size distribution and solubility were selected by way of dependent variables, and ball milling time, homogenization cycles, and Pluronic F-127/glyburide ratio were chosen as independent variables. Glyburide nanosuspensions were obtained with a particle size of 244.6 ± 2.685 nm. In vitro release and solubility studies were conducted following optimization.

Results: The saturation solubility of glyburide was nearly doubled as a result of the nanocrystal formation. Xray diffraction (XRD), scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and Fourier-transform infrared spectroscopy (FT-IR) were used to assess the nanosuspension. SEM images confirmed that the nanocrystal formation process was successful. Glyburide and the excipients have no incompatibilities, their physical states have not changed, and the preparation method has not affected the stability of glyburide, according to DCS, XRD, and FT-IR analyses.

Conclusion: These studies indicated that a combination of ball milling and homogenization techniques significantly enhanced the solubility of glyburide and its release from the formulation. Consequently, this approach can be applied to formulations characterized by low absorption and limited bioavailability.

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通过球磨和均质化技术优化糖肽载体纳米悬浮剂:提高溶解度的中心复合设计方法
简介格列本脲是一种治疗糖尿病的药物,对老年痴呆症有潜在疗效。它也是一种 BCS 2 级药物,具有低溶解度和低渗透性。要克服这一难题,就必须开发出一种纳米悬浮制剂,并提高甘布肽的溶解度和溶解速率:因此,这项工作的目标是通过球磨和均质化甘布肽来制造甘布肽纳米悬浮液,以提高其溶解度和溶解速率。为此,采用中心复合设计法对纳米悬浮剂配方进行了优化。Zeta电位、粒度分布和溶解度被选为因变量,球磨时间、均质周期和Pluronic F-127/格列本脲的比例被选为自变量。格列本脲纳米悬浮剂的粒径为 244.6 ± 2.685 nm。优化后进行了体外释放和溶解度研究:结果:由于纳米晶体的形成,格列本脲的饱和溶解度几乎增加了一倍。X 射线衍射(XRD)、扫描电子显微镜(SEM)、差示扫描量热法(DSC)和傅立叶变换红外光谱(FT-IR)用于评估纳米悬浮液。扫描电镜图像证实纳米晶体的形成过程是成功的。根据 DCS、XRD 和 FT-IR 分析,格列本脲与辅料不存在不相容性,它们的物理状态没有发生变化,制备方法也没有影响格列本脲的稳定性:这些研究表明,球磨和均质化技术相结合能显著提高甘布肽的溶解度,并增加其从制剂中的释放。因此,这种方法可用于吸收率低和生物利用度有限的制剂。
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来源期刊
CiteScore
6.30
自引率
0.00%
发文量
302
审稿时长
2 months
期刊介绍: Current Pharmaceutical Design publishes timely in-depth reviews and research articles from leading pharmaceutical researchers in the field, covering all aspects of current research in rational drug design. Each issue is devoted to a single major therapeutic area guest edited by an acknowledged authority in the field. Each thematic issue of Current Pharmaceutical Design covers all subject areas of major importance to modern drug design including: medicinal chemistry, pharmacology, drug targets and disease mechanism.
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