以对 ROS 敏感的苯硼酰化壳聚糖为载体的不同纳米粒子的功能特性和分子对接。

IF 4.3 3区 医学 Q1 PHARMACOLOGY & PHARMACY European Journal of Pharmaceutical Sciences Pub Date : 2024-07-25 DOI:10.1016/j.ejps.2024.106865
Ziming Liu, Sihui Li, Pengfei Xu, Huiqin Gan, Pengfei Yue, Shuying Xie, Zixia Zhang, Weifeng Zhu, Zhiyu Guan
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引用次数: 0

摘要

目的制备壳聚糖纳米颗粒(NPs),提高葛根素(Pur)的口服生物利用度,并使其对活性氧(ROS)产生反应:该研究在智能给药理论方面取得了实质性进展,为葛根素与其他天然药物活性成分的结合提供了新的参考:方法:利用壳聚糖和对 ROS 敏感的 3-羧基苯硼酸(PBA)的酰化反应合成了对 ROS 敏感的苯硼酰化壳聚糖(PBACS)。随后,分别加入 PBA 和三聚磷酸钠(TPP),通过离子凝胶法制备了 PBACS-PBA-Pur-NPs 和 PBACS-TPP-Pur-NPs。比较了两种 NPs 的理化性质和功能特性,并通过分子对接初步研究了它们的差异:结果:成功合成了对活性氧敏感的 PBACS。在制备的两种 NPs 中,PBACS-TPP-Pur-NPs 的尺寸为 127.2 ± 0.80 nm,多分散指数(PDI)为 0.129 ± 0.0008,封装率为 95.75 ± 0.387%;而 PBACS-PBA-Pur-NPs 的尺寸为 149.8 ± 0.1414 nm,PDI 为 0.389 ± 0.0012,封装率为 91.77 ± 0.279%。PBACS-TPP-Pur-NPs 的微观形态表现出更好的物理性质。然而,PBACS-PBA-Pur-NPs 的体外释放速度更快,体外抗炎效果更显著。药代动力学方面,PBACS-PBA-Pur-NPs 的 AUC0-24、Tmax 和 Cmax 分别是 Pur 的 3.485、2.117 和 3.339 倍。PBACS-TPP-Pur-NPs 的 AUC0-24、Tmax 和 Cmax 分别是 Pur 的 2.41 倍、1.33 倍和 2.03 倍。分子模拟显示,PBACS-PBA-Pur -NPs的结合能约为-4.34 kcal/mol,而PBACS-TPP-Pur-NPs的结合能更低,约为-5.93 kcal/mol,这表明用TPP制备的NPs比用PBA设计的NPs更致密,导致药物释放更慢、更少:本研究构建的 NPs 能有效减少疾病部位的炎症因子,为纳米药物在炎症疾病模型中的应用提供了理论和实验依据。此外,对两种 NPs 的分子对接研究还有助于深入了解后续纳米药物的释放与结构之间的关系。
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Functional properties and molecular docking of different nanoparticles with ROS-sensitive phenylboronylated chitosan as the carrier

Objective

To prepare chitosan-loaded nanoparticles (NPs) that enhance the oral bioavailability of puerarin (Pur) and render it responsive to reactive oxygen species (ROS).

Significance

This research makes substantial progress towards the theory of intelligent drug delivery, offering a new reference for combining Pur with other natural medicinal active ingredients.

Methods

The acylation reaction between chitosan and ROS-sensitive 3-carboxyphenylboronic acid (PBA) was used to synthesise ROS-sensitive phenylboronylated chitosan (PBACS). Subsequently, PBACS-PBA-Pur-NPs and PBACS-TPP-Pur-NPs were prepared via ion gelation after the addition of PBA and sodium tripolyphosphate(TPP), respectively. The physicochemical and functional properties of both NPs were compared, and their differences were preliminarily studied through molecular docking.

Results

Reactive oxygen species-sensitive PBACS was successfully synthesised. Of the two NPs prepared, PBACS-TPP-Pur-NPs had a size of 127.2 ± 0.80 nm, polydispersity index (PDI) of 0.129 ± 0.0008, and an encapsulation rate of 95.75 ± 0.387 %, whereas PBACS-PBA-Pur-NPs had a size of 149.8 ± 0.1414 nm, PDI of 0.389 ± 0.0012, and an encapsulation rate of 91.77 ± 0.279 %. The micromorphology of the PBACS-TPP-Pur-NPs exhibited better physical properties. However, PBACS-PBA-Pur-NPs demonstrated a faster in vitro release and more significant in vitro anti-inflammatory effects. Pharmacokinetically, the AUC0–24, Tmax, and Cmax of PBACS-PBA-Pur-NPs were 3.485, 2.117, and 3.339 times higher, respectively, than those of Pur. The AUC0–24, Tmax, and Cmax of PBACS-TPP-Pur-NPs were 2.41, 1.33, and 2.03 times higher, respectively, than those of Pur. Molecular simulation revealed that the binding energy of PBACS-PBA-Pur -NPs was approximately −4.34 kcal/mol and that of PBACS-TPP-Pur-NPs was even lower, approximately −5.93 kcal/mol, suggesting that the NPs prepared with TPP are more densely packed than those designed with PBA, resulting in slower and reduced drug release.

Conclusion

The NPs constructed in this study effectively reduced inflammatory factors at the disease site, providing a theoretical and experimental basis for the application of nano drugs in inflammatory disease models. In addition, the molecular docking study of the two NPs offered insights into the relationship between the release and structure of subsequent nano drugs.

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CiteScore
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期刊介绍: The journal publishes research articles, review articles and scientific commentaries on all aspects of the pharmaceutical sciences with emphasis on conceptual novelty and scientific quality. The Editors welcome articles in this multidisciplinary field, with a focus on topics relevant for drug discovery and development. More specifically, the Journal publishes reports on medicinal chemistry, pharmacology, drug absorption and metabolism, pharmacokinetics and pharmacodynamics, pharmaceutical and biomedical analysis, drug delivery (including gene delivery), drug targeting, pharmaceutical technology, pharmaceutical biotechnology and clinical drug evaluation. The journal will typically not give priority to manuscripts focusing primarily on organic synthesis, natural products, adaptation of analytical approaches, or discussions pertaining to drug policy making. Scientific commentaries and review articles are generally by invitation only or by consent of the Editors. Proceedings of scientific meetings may be published as special issues or supplements to the Journal.
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