This work is aimed at the development of a reduction-sensitive drug carrier for the delivery of the anti-cancer drug paclitaxel (PTX). N,N'-bis(acryloyl)cystamine (CBA) was reacted with ethanolamine (AEOL) via Michael addition to synthesize cationic poly(CBA-AEOL) (PCA) containing disulfide bonds. Subsequently, polycaprolactone (PCL) was grafted from PCA to form a novel reduction-sensitive copolymer (PCA-g-PCL). The PCA-g-PCL copolymer self-assembled as spherical micelles with a mean size of ca. 108nm. The disulfide bonds in the PCA-g-PCL copolymer contributed to the reduction-sensitivity of the micelles, observed as stepwise aggregation under simulated reduction conditions. To improve the stability of PCA-g-PCL micelles in aqueous media, carboxyl-terminated poly(ethylene glycol) methyl ether (mPEG-COOH) was conjugated with the PCA-g-PCL copolymer via electrostatic interaction to produce polyion complex micelles with a hydrophilic PEG surface. The in vitro release of PTX from the mPEG@PCA-g-PCL micelle showed a reduction sensitive profile, namely the rate of drug release strongly depended upon the concentration of the reducing agent. Leakage of PTX was limited to below 30% under normal conditions while almost all the drug was released in 9h under reduction conditions with 40mM DTT. In conclusion, the assembled mPEG@PCA-g-PCL micelle with reduction-sensitive controlled release shows great potential for improving the therapeutic effect of paclitaxel.
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