探索水飞蓟素负载纳米颗粒作为癌症治疗的有效给药系统的潜力:体内、体外和硅学实验

Mohammad Reza Hajinezhad, Maryam Roostaee, Zahra Nikfarjam, Sanaz Rastegar, Ghasem Sargazi, Mahmood Barani, Saman Sargazi
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引用次数: 0

摘要

我们的目的是对作为潜在药物输送系统的水飞蓟素(Syl)负载型niosomes的开发和特性进行全面研究。研究结果在形态、尺寸分布、包封效率、体外释放行为、Syl 穿过niosome双分子层的自由能曲线、氢键相互作用、抗菌特性、细胞毒性和体内评估等方面都显示出了巨大的新颖性和良好的结果。对游离的niosomes和负载Syl的niosomes进行的物理外观、尺寸和形态评估表明,它们具有稳定、成型良好的囊泡结构,适合药物输送。透射电子显微镜(TEM)分析表明,每种制剂都具有大小不同的球形,证实了其分布均匀。动态光散射(DLS)分析证实了粒度分布结果,Syl负载的niosomes具有更高的多分散指数。Syl在niosomes中的包封效率非常高,约为91%,确保了药物的保护和控制释放。体外释放研究表明,Syl负载的niosomes具有持续释放的特性,可随着时间的推移提高疗效。自由能谱分析确定了阻碍希尔通过niosome双分子层渗透的能量障碍,强调了给药系统设计所面临的挑战。Syl和niosome成分之间的氢键相互作用造成了能量障碍,影响了药物的渗透性。抗菌评估显示,对金黄色葡萄球菌和大肠杆菌的抑制效果存在显著差异。细胞毒性评估表明,与游离 Syl 相比,负载 Syl 的niosomes 具有更强的肿瘤杀伤潜力。体内研究表明,与散装 Syl 相比,niosome 制剂在肝脏和肾脏参数方面具有安全性,从而展示了临床应用的潜力。总之,这项研究凸显了Syl负载的niosomes作为有效给药系统的巨大潜力,它具有更高的稳定性、可控释放性和更好的治疗效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Exploring the potential of silymarin-loaded nanovesicles as an effective drug delivery system for cancer therapy: in vivo, in vitro, and in silico experiments

Exploring the potential of silymarin-loaded nanovesicles as an effective drug delivery system for cancer therapy: in vivo, in vitro, and in silico experiments

We aimed to perform a comprehensive study on the development and characterization of silymarin (Syl)-loaded niosomes as potential drug delivery systems. The results demonstrate significant novelty and promising outcomes in terms of morphology, size distribution, encapsulation efficiency, in vitro release behavior, free energy profiles of Syl across the niosome bilayer, hydrogen bonding interactions, antimicrobial properties, cytotoxicity, and in vivo evaluations. The physical appearance, size, and morphology assessment of free niosomes and Syl-loaded niosomes indicated stable and well-formed vesicular structures suitable for drug delivery. Transmission electron microscopy (TEM) analysis revealed spherical shapes with distinct sizes for each formulation, confirming uniform distribution. Dynamic light scattering (DLS) analysis confirmed the size distribution results with higher polydispersity index for Syl-loaded niosomes. The encapsulation efficiency of Syl in the niosomes was remarkable at approximately 91%, ensuring protection and controlled release of the drug. In vitro release studies showed a sustained release profile for Syl-loaded niosomes, enhancing therapeutic efficacy over time. Free energy profiles analysis identified energy barriers hindering Syl permeation through the niosome bilayer, emphasizing challenges in drug delivery system design. Hydrogen bonding interactions between Syl and niosome components contributed to energy barriers, impacting drug permeability. Antimicrobial assessments revealed significant differences in inhibitory effects against S. aureus and E. coli. Cytotoxicity evaluations demonstrated the superior tumor-killing potential of Syl-loaded niosomes compared to free Syl. In vivo studies indicated niosome formulations’ safety profiles in terms of liver and kidney parameters compared to bulk Syl, showcasing potential for clinical applications. Overall, this research highlights the promising potential of Syl-loaded niosomes as effective drug delivery systems with enhanced stability, controlled release, and improved therapeutic outcomes.

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