普鲁兰
环糊精
纳米纤维
色谱法
化学
化学工程
材料科学
有机化学
纳米技术
多糖
工程类
作者
Congyi Nie,Qian Liang,Qunyu Gao
标识
DOI:10.1016/j.ijbiomac.2024.132388
摘要
Cyclodextrin-based electrospun nanofibers are promising for encapsulating and preserving unstable compounds, but quick dissolution of certain nanofibers hinders their delivery application. In this study, hydroxypropyl-β-cyclodextrin (HPβCD) was used as an effective carrier of resveratrol (RSV) to obtain the RSV/HPβCD inclusion complex (HPIC), which was then incorporated into pullulan nanofibers. For enhancement of RSV release toward colon target, multilayer structure with a pullulan/HPIC film sandwiched between two layers of hydrophobic Eudragit S100 (ES100) nanofibers was employed. The relationship between the superiority of the ES100-pullulan/HPIC-ES100 film and its multilayer structure was verified. The intimate interactions of hydrogen bonds between two adjacent layers enhanced thermal stability , and the hydrophobic outer layers improved water contact resistance. According to release results, multilayer films also showed excellent colon-targeted delivery property and approximately 78.58 % of RSV was observed to release in colon stage. In terms of release mechanism, complex mechanism best described RSV colonic release. Additionally, ES100-pullulan/HPIC-ES100 multilayer films performed higher encapsulation efficiency when compared to the structures without HPIC, which further increased the antioxidant activity and total release amount of RSV. These results suggest a promising strategy for designing safe colonic delivery systems based on multilayer and HPIC structures with superior preservation for RSV. • The Eudragit S100-pullulan multilayer film was prepared by sequential electrospinning. • Multilayer and HPβCD structures increased colonic release of resveratrol. • HPβCD improved encapsulation efficiency of resveratrol and antioxidant activity . • Colonic resveratrol release for multilayer films was governed by complex mechanism. • Resveratrol encapsulated in multilayer nanofibers had higher thermal stability.
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