pH敏感型热休克笼形蛋白纳米载体的构建及其理化性质评价

王喻; 饶跃峰; 杨惠卿; 骆红飞; 赵子明<sup>*</sup>

引用本文:	王喻,饶跃峰,杨惠卿,骆红飞,赵子明.pH敏感型热休克笼形蛋白纳米载体的构建及其理化性质评价[J].中国现代应用药学,2019,36(17):2113-2118.
	WANG Yu,RAO Yuefeng,YANG Huiqing,LUO Hongfei,ZHAO Ziming.Preparation and Evaluation of Physicochemical Properties of pH Sensitive Nanocarriers Based on Cage-like Heat Shock Proteins[J].Chin J Mod Appl Pharm(中国现代应用药学),2019,36(17):2113-2118.

【打印本页】【HTML】【下载PDF全文】【查看/发表评论】【EndNote】【RefMan】【BibTex】

←前一篇|后一篇→

过刊浏览高级检索

本文已被：浏览 1837次下载 914次	码上扫一扫！
分享到：微信更多字体:加大+\|默认\|缩小-
pH敏感型热休克笼形蛋白纳米载体的构建及其理化性质评价
王喻^1,2, 饶跃峰², 杨惠卿¹, 骆红飞¹, 赵子明³
1.浙江中医药大学附属第二医院, 杭州 310005;2.浙江大学医学院附属第一医院, 杭州 310003;3.徐州医科大学药学院, 江苏徐州 221004

摘要:

目的设计并制备具有靶向肿瘤且pH敏感的热休克蛋白（heat shock proteins，HSP）笼形蛋白纳米递药系统，并对其理化性质进行表征。方法采用基因全合成与蛋白质重组表达技术纯化HSP为母版，通过表面官能团功能化制备得到修饰穿膜肽Tat、聚乙二醇包衣的热休克笼形蛋白纳米载体（PT-HSP）。通过透射电镜、纳米粒度与Zeta电位测定仪对其形态、粒径及Zeta电位进行表征，并建立HPLC测定其载药量与包封率。考察载紫杉醇（paclitaxel，PTX）的PT-HSP在生理pH条件（pH 7.4）与肿瘤pH条件（pH 6.5）下的体外释药行为。结果形态学结果表明，PT-HSP是呈现典型双层结构的均一球体，平均粒径为（154.4±23.6） nm，Zeta电位为（-2.6±0.7） mV。HPLC测得载PTX的PT-HSP的包封率为（75.3±3.6）%，载药量为（7.0±0.2）%。体外释药试验结果表明PT-HSP在pH 7.4条件下的释放速率显著慢于pH 6.5条件下的释放速率（P<0.01）。结论本研究制备得到的pH敏感的HSP笼形蛋白智能纳米递药系统具有载药量高、稳定性强及智能靶向等优点，有望成为一种安全、有效、智能的抗肿瘤药物载体。

关键词: 热休克蛋白聚乙二醇 Tat肽 pH敏感纳米载体

DOI：10.13748/j.cnki.issn1007-7693.2019.17.001

分类号:R943

基金项目:国家自然科学基金项目（81773643，81872213）；江苏省高校自然科学基金项目（17KJB350014）；浙江省医药卫生科研基金项目（2017KY516）

Preparation and Evaluation of Physicochemical Properties of pH Sensitive Nanocarriers Based on Cage-like Heat Shock Proteins

WANG Yu^1,2, RAO Yuefeng², YANG Huiqing¹, LUO Hongfei¹, ZHAO Ziming³

1.The Second Affiliated Hospital of Zhejiang Chinese Medical University, Hangzhou 310005, China;2.The First Affiliated Hospital, School of Medicine, Zhejiang University, Hangzhou 310003, China;3.Department of Pharmacy, Xuzhou Medical University, Xuzhou 221004, China

Abstract:

OBJECTIVE To design and prepare a tumor-targeted pH-sensitive delivery system based on heat shock proteins(HSP) nanocages, and to evaluate its physicochemical properties. METHODS Using HSP as the matrix, which were prepared by total gene synthesis and protein recombination expression technology, HSP nanocages modified with cell-penetrating peptides Tat and PEG(PT-HSP) were produced via the functionalization of surface groups. Morphology was examined by TEM, particle size and Zeta potential were determined by nanometer particle size and zeta potential measuring instrument. Encapsulation efficiency and loading capacity were determined by HPLC. The in vitro release behavior of paclitaxel-loaded PT-HSP under pH 7.4 and pH 6.5 was investigated. RESULTS Morphological results showed that PT-HSP presented uniform spherical with a typical two-layer structure, the average size of PT-HSP was (154.4±23.6)nm, Zeta potential was (−2.6±0.7)mV. Encapsulation efficiency and loading capacity of PT-HSP detected by HPLC were (75.3±3.6)% and (7.0±0.2)%. The results of in vitro release test showed that the release rate of PT-HSP at pH 6.5 was faster than pH 7.4(P<0.01). CONCLUSION The pH-sensitive intelligent HSP nanocages drug delivery system constructed in this study, is expected to become a safe, effective and intelligent antitumor drug delivery carriers by its high loading capacity, good stability and intelligent tumor-targeting.

Key words: heat shock proteins(HSP) PEG Tat pH-sensitive nanocarriers