Interface-sensitized prodrug nanoaggregate as an effective in situ antitumor vaccine

In situ antitumor vaccines have been widely explored as an effective strategy to inhibit tumor growth by stimulating antitumor immune responses. Herein, we reported a simple and effective in situ antitumor vaccine, which was prepared by co-assembling cationic lipids (DOTAP) with the disulfide bond-linked lipid-drug conjugates of camptothecin and resiquimod. The resulting vaccine had a rod-sharped morphology with nanoscale sizes (average hydrodynamic diameter of ∼163.7 nm) and positively-charged interfaces (zeta potential ∼ +36.2 mV). The interfacial cationization of nanoaggregate resulted in 1000 folds faster redox-responsive drug release than that of unmodified ones, which induced a much more potent in vivo antitumor immune by accelerating the glutathione-responsive drug release at the tumor site. Such cationic lipid-drug nanoaggregates displayed many benefits, such as high co-loading capacity, simple preparation process, and wide applicability, which would serve as a promising new approach to design effective in situ antitumor vaccines.

Drug Release from Disulfide-Linked Prodrugs: Role of Thiol Agents

The disulfide bond (SS) has been widely used in prodrugs for the redox-responsive drug release, but its drug release mechanism and rate were seldom compared in different thiol agents. Herein, self-assembling nanoaggregates (NAs) formed by camptothecin (CPT)-oleic acid (OA) prodrugs linked by two frequently used SS linkers (ETCSS and ACSS) were used for such comparative investigation. It is found that the cleavage of ETCSS was directly coupled with CPT release, whereas the breakage of ACSS resulted in the generation of CPT intermediates, the chemical stability of which determined CPT release. In both cases, the redox-responsive drug release was highly dependent on the reactivity between SS and thiol agents, with an order of dithiothreitol > cysteine ≈ glutathione. Moreover, the presence of SS significantly accelerated the extracellular CPT release, which was around 3-4 fold higher than intracellular CPT release. Therefore, the in vitro cytotoxicity of SS-linked CPT-OA NAs could not be ascribed to the glutathione-trigged intracellular drug release but rather to the SS-accelerated extracellular CPT release. The above results would effectively guide the rational design and evaluation of SS-linked prodrug NAs for efficient drug delivery.