Computational and experimental insights into glycyrrhizin-loaded nanostructured lipid carriers: docking, dynamics, design optimization, and anticancer efficacy in lung cancer cells

IF 3.4 Q2 PHARMACOLOGY & PHARMACY
Amit Kumar, Abhishek Tiwari, Varsha Tiwari
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引用次数: 0

Abstract

Background

Lung cancer (LC) remains a predominant global health concern, especially with escalating tobacco-smoking rates. Present study provides computational screening, molecular dynamics, DFT and simulation analysis of phytoconstituents on EGFR receptors (2ITY and W2O), followed by selection of highest docking score phytoconstituents among 45 for further analysis. The formulation was optimized by Central composite design. Nanostructured-lipid carriers were prepared by high-speed homogenization, combining a 1:1 ratio of liquid lipid (Castor oil) and melted solid lipid (glyceryl monostearate) with 4% surfactant (tween 80) in a water phase containing Glycyrrhizin. The resulting mixture underwent high-speed homogenization at 8000 rpm for 40 min, followed by sonication for 15 min to achieve formulation development of GNLC. The anticancer potential of GNLC have been proved by experimental analysis through MTT assay using A549 Cell lines.

Results

Glycyrrhizin was found to possess maximum docking score − 8.863 and − 8.837 on both 2ITY and W2O respectively. The study unveils Glycyrrhizin’s interactions with EGFR pivotal in cancer progression and treatment. Molecular dynamics simulations highlighted the structural and dynamic interactions within a protein–ligand complex, indicating both stability and flexibility characteristics. DFT analysis of Glycyrrhizin revealed its molecular properties, suggesting stability and potential reactivity. Glycyrrhizin loaded nanostructured lipid carriers (GNLC) have been developed and analysed by various parameters like particle size and drug release zeta potential, SEM analysis, and solubility analysis reveals critical insights into their optimization for effective drug delivery. Both GNLC and Doxorubicin (0.78–50 µg/ml) were used for the activity. The anticancer potential at 12.50, 25 and 50 µg/ml pf GNLC was found to be statistically significant and was comparable with that of standard group Doxorubicin. The observed structural transformations in Glycyrrhizin into a lipid matrix indicate potential enhancements in its drug release.

Conclusions

GNLC shows promising anti-cancer potential in lung cancer, further pre-clinical and clinical studies, is crucial to validate its efficacy, safety, and integration into standard therapeutic regimens.

Graphical abstract

对甘草酸苷负载纳米结构脂质载体的计算和实验见解:对接、动力学、设计优化以及在肺癌细胞中的抗癌功效
背景肺癌(LC)仍然是全球主要的健康问题,特别是随着吸烟率的上升。本研究对表皮生长因子受体(2ITY 和 W2O)上的植物成分进行了计算筛选、分子动力学、DFT 和模拟分析,然后从 45 种植物成分中选出对接得分最高的进行进一步分析。通过中央复合设计对配方进行了优化。纳米结构脂质载体的制备方法是:在含有甘草苷的水相中,以 1:1 的比例混合液态脂质(蓖麻油)和融化的固态脂质(单硬脂酸甘油酯)以及 4% 的表面活性剂(吐温 80),然后进行高速均质。得到的混合物在 8000 转/分的转速下高速均质 40 分钟,然后超声 15 分钟,最终研制出 GNLC 配方。通过使用 A549 细胞系进行 MTT 试验,实验分析证明了 GNLC 的抗癌潜力。该研究揭示了甘草酸苷与表皮生长因子受体(EGFR)的相互作用在癌症进展和治疗中的关键作用。分子动力学模拟强调了蛋白质配体复合物内的结构和动态相互作用,显示出稳定性和灵活性特征。甘草苷的 DFT 分析显示了其分子特性,表明其具有稳定性和潜在的反应性。通过对粒度、药物释放 zeta 电位、扫描电镜分析和溶解度分析等各种参数进行分析,开发出了负载甘草酸苷的纳米结构脂质载体(GNLC),为优化其有效给药提供了重要启示。GNLC 和多柔比星(0.78-50 µg/ml)都被用来进行活性测试。研究发现,GNLC 在 12.50、25 和 50 µg/ml 浓度下的抗癌潜力具有统计学意义,与标准组多柔比星的抗癌潜力相当。结论甘草酸苷在肺癌中显示出良好的抗癌潜力,进一步的临床前和临床研究对验证其疗效、安全性以及将其纳入标准治疗方案至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
自引率
0.00%
发文量
44
审稿时长
23 weeks
期刊介绍: Future Journal of Pharmaceutical Sciences (FJPS) is the official journal of the Future University in Egypt. It is a peer-reviewed, open access journal which publishes original research articles, review articles and case studies on all aspects of pharmaceutical sciences and technologies, pharmacy practice and related clinical aspects, and pharmacy education. The journal publishes articles covering developments in drug absorption and metabolism, pharmacokinetics and dynamics, drug delivery systems, drug targeting and nano-technology. It also covers development of new systems, methods and techniques in pharmacy education and practice. The scope of the journal also extends to cover advancements in toxicology, cell and molecular biology, biomedical research, clinical and pharmaceutical microbiology, pharmaceutical biotechnology, medicinal chemistry, phytochemistry and nutraceuticals.
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