Facile fabrication of positively-charged helical poly(phenyl isocyanide) modified multi-stimuli-responsive nanoassembly capable of high efficiency cell-penetrating, ratiometric fluorescence imaging, and rapid intracellular drug release

Sub-lethal drug concentrations in cancer therapy have always occurred because of the systematic barriers existing in the drug-resistant tumor microenvironment. To circumvent this issue, accurate and rapid drug release in cancer cells is crucial for providing optimum drug concentrations, preventing P...

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Bibliographic Details
Published in:Polymer chemistry 2018-01, Vol.9 (31), p.4233-4242
Main Authors: Zhang, Wen-Ming, Zhang, Jian, Qiao, Zhu, Liu, Huan-Ying, Wu, Zong-Quan, Yin, Jun
Format: Article
Language:English
Subjects:
Biocompatibility
Blood circulation
Blood vessels
Cancer
Cell membranes
Chemotherapy
Drug delivery systems
Efficiency
Efflux
Fluorescence
Glycoproteins
Micelles
Oxidation
Peptides
Polymer chemistry
Side effects
Stimuli
Toxicity
Ultraviolet radiation
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Summary:Sub-lethal drug concentrations in cancer therapy have always occurred because of the systematic barriers existing in the drug-resistant tumor microenvironment. To circumvent this issue, accurate and rapid drug release in cancer cells is crucial for providing optimum drug concentrations, preventing P-glycoprotein pumping out, increasing the efficiency of chemotherapy, and destroying cancer cells without respite. In this contribution, we report helical chain functionalized polymeric micelles for the co-delivery of dyes and drugs for cell imaging and therapy by taking advantage of pH, oxidation, and UV light multiple synergistic triggers. The positively charged guanidine group modified hydrophilic helical chains have a similar structure to cell penetrating peptides, which play an important role in their interaction with lipid bilayers in cell membranes and enhance subsequent cell internalization. The resultant complex nanoassembly has a preferable size of ∼185 nm and strong stability in aqueous solution, which is beneficial to long-term blood circulation and efficient extravasation from tumoral vessels. In conditions mimicking the extracellular environment, the complex nanoassembly showed a slow cargo release rate, while an accelerated release was observed after incubation of the micelles with an acidic medium or reductive environment. Moreover, an enhanced rapid drug release was realized if all three stimuli were performed on the micelles simultaneously, which exactly avoided insufficient drug concentration in cancer cells brought about by poor drug release or drug efflux pumps. The drug-loaded nanoassembly showed a devastating cytotoxicity against cancer cells, whereas blank samples were found to be non-toxic. This proof-of-concept is operated through multiple stimuli responsive drug release, showing promise for minimizing side effects, improving drug utilization efficiency, and having bright prospects in biomedical practice. High efficiency cell-penetrating helical chain functionalized polymeric micelles capable of co-delivery of cargoes and rapid release were reported.
ISSN:1759-9954
1759-9962
DOI:10.1039/c8py00865e