PLGA公司
乙二醇
药物输送
PEG比率
紫杉醇
材料科学
聚合物
纳米技术
丙交酯
纳米颗粒
癌症
药品
癌细胞
乳酸
组合化学
药理学
化学
有机化学
医学
共聚物
内科学
财务
生物
细菌
复合材料
遗传学
经济
作者
Zhanguo Yue,Zuo‐Xiang You,Yang Qin-zheng,Piping Lv,Hua Yue,Bin Wang,Dezhi Ni,Zhiguo Su,Wei Wei,Guanghui Ma
摘要
Various carriers are being advanced for anti-cancer therapy, which can protect drugs and ferry them to the target site. However, little understanding exists regarding the effect of molecular structure on anti-cancer drug delivery efficiency. To fill this knowledge gap, we take poly(lactic acid) (PLA), poly(lactide-co-glycolide) (PLGA), and poly-ethylene glycol-co-poly-lactide (PEG-b-PLA) polymers as prototype materials and comparatively explore the inherent relationship between the molecular structure and the delivery ability. Compared with PLA and PLGA NPs, PEG-b-PLA ones possess the advantages of longer blood circulation time, more tumor accumulation, and better intratumoral delivery ability. Subsequent mechanism investigations reveal that the molecular structure will regulate the polymer arrangement and render NPs different hydrophilicity/deformability, which dictate the distinct delivery performances. Finally, the superior PEG-b-PLA NPs are further loaded with the anti-cancer drug paclitaxel (PTX) and functionalized with magnetic (M) Fe3O4 nanocrystals. As-designed PTX/M PEG-b-PLA NPs show much better tumor inhibition efficacy and fewer side effects than the commercialized Taxol® formulation, strongly supporting their use as high-performance carriers for anti-cancer therapy.
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