Amphiphilic polycations with a "stealth" cationic nature have been designed and synthesized by the PEGylation of polycationic amphiphile via a novel pH responsible benzoic imine linker. The linkage is stable in aqueous solution at physiological pH but cleaves in slight acidic conditions such as the extracellular environment of solid tumor and endosomes. The polymeric micelle formed from the amphiphilic "stealth" polycation contains a pH-switchable cationic surface driven by the reversible detachment/reattachment of the shielding PEG chains due to the cleavage/formation process of the imine linkage. At physiological pH, the micellar surface was shielded by the PEG corona, leading to lower cytotoxicity and less hemolysis, whereas in a mild acidic condition like in endosomes or solid tumors, the deshielding of the PEG chains exposed the positive charge on the micellar surface and retained the membrane disrupting ability. The amphiphilic "stealth" polycation is potentially useful as a drug targeting system toward tumors via endocytosis and trafficked through the endosomal pathway.
We demonstrate that multifuctional drug carriers, e.g., polymeric micelles, for tumor-specific uptake and intracellular delivery can be generated from the pH-dependent progressive hydrolysis of a novel benzoic-imine linker in the micelle-forming amphiphilic polymer. The linker, hence the micelle, is stable at physiological pH, partially hydrolyzes at the extracellular pH of the solid tumor, and completely hydrolyzes at the endosomal pH. Meanwhile, the surface property of the micelle converts from neutral to positively charged due to the generation of amino groups from the cleavage of the imine bond at tumor pH. The ionization on the surface facilitates the cellular uptake of the micelles through the electrostatic interaction between the micelle and the cell membrane. Subsequently, at the endosomal pH, with more complete cleavage of the polymer the micellar structure dissociates, and the system becomes very membrane-disruptive, inferring an enhanced intracellular delivery capability via the endosomal pathway.
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