Comparison of virus-capsid mimicking biologic-shell based versus polymeric-shell nanoparticles for enhanced oral insulin delivery

IF 10.7 1区 医学 Q1 PHARMACOLOGY & PHARMACY
Zhixiang Cui , Shuman Cui , Lu Qin , Yalin An , Xin Zhang , Jian Guan , Tin Wui Wong , Shirui Mao
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Abstract

Virus-capsid mimicking mucus-permeable nanoparticles are promising oral insulin carriers which surmount intestinal mucus barrier. However, the impact of different virus-capsid mimicking structure remains unexplored. In this study, utilizing biotin grafted chitosan as the main skeleton, virus-mimicking nanoparticles endowed with biologic-shell (streptavidin coverage) and polymeric-shell (hyaluronic acid/alginate coating) were designed with insulin as a model drug by self-assembly processes. It was demonstrated that biologic-shell mimicking nanoparticles exhibited a higher intestinal trans-mucus (>80%, 10 min) and transmucosal penetration efficiency (1.6–2.2-fold improvement) than polymeric-shell counterparts. Uptake mechanism studies revealed caveolae-mediated endocytosis was responsible for the absorption of biologic-shell mimicking nanoparticles whereas polymeric-shell mimicking nanoparticles were characterized by clathrin-mediated pathway with anticipated lysosomal insulin digestion. Further, in vivo hypoglycemic study indicated that the improved effect of regulating blood sugar levels was virus-capsid structure dependent out of which biologic-shell mimicking nanoparticles presented the best performance (5.1%). Although the findings of this study are encouraging, much more work is required to meet the standards of clinical translation. Taken together, we highlight the external structural dependence of virus-capsid mimicking nanoparticles on the muco-penetrating and uptake mechanism of enterocytes that in turn affecting their in vivo absorption, which should be pondered when engineering virus-mimicking nanoparticles for oral insulin delivery.

Abstract Image

模拟病毒衣壳的生物壳纳米颗粒与聚合物壳纳米颗粒增强口服胰岛素递送的比较
病毒衣壳模拟粘液可渗透纳米颗粒是很有前途的口服胰岛素载体,可以克服肠道粘液屏障。然而,不同病毒衣壳模拟结构的影响仍未被探索。本研究以生物素接枝壳聚糖为主要骨架,以胰岛素为模型药物,通过自组装工艺设计了具有生物外壳(链亲和素覆盖)和聚合物外壳(透明质酸/藻酸盐涂层)的仿病毒纳米颗粒。研究表明,与聚合物外壳相比,模拟生物外壳的纳米颗粒表现出更高的肠道反式粘液(>;80%,10分钟)和跨粘膜渗透效率(提高1.6–2.2倍)。摄取机制研究表明,小窝介导的内吞作用是生物仿壳纳米颗粒吸收的原因,而聚合物仿壳纳米粒子的特征是网格蛋白介导的途径与预期的溶酶体胰岛素消化。此外,体内降血糖研究表明,调节血糖水平的改善效果取决于病毒衣壳结构,其中模仿生物外壳的纳米颗粒表现出最好的性能(5.1%)。尽管这项研究的结果令人鼓舞,但要达到临床翻译的标准,还需要做更多的工作。总之,我们强调了模仿病毒衣壳的纳米颗粒对肠上皮细胞的粘膜穿透和摄取机制的外部结构依赖性,这反过来又影响了它们的体内吸收,在设计模仿病毒的纳米颗粒用于口服胰岛素递送时应考虑这一点。
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
Asian Journal of Pharmaceutical Sciences
Asian Journal of Pharmaceutical Sciences Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science
CiteScore
18.30
自引率
2.90%
发文量
11
审稿时长
14 days
期刊介绍: The Asian Journal of Pharmaceutical Sciences (AJPS) serves as the official journal of the Asian Federation for Pharmaceutical Sciences (AFPS). Recognized by the Science Citation Index Expanded (SCIE), AJPS offers a platform for the reporting of advancements, production methodologies, technologies, initiatives, and the practical application of scientific knowledge in the field of pharmaceutics. The journal covers a wide range of topics including but not limited to controlled drug release systems, drug targeting, physical pharmacy, pharmacodynamics, pharmacokinetics, pharmacogenomics, biopharmaceutics, drug and prodrug design, pharmaceutical analysis, drug stability, quality control, pharmaceutical engineering, and material sciences.
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上海源叶 Polyglutamic acid
¥19.00~¥15490.00
Sigma Type II porcine stomach mucin
¥30.00~¥10822.08
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