Facile Synthesis of Zn2+-Based Hybrid Nanoparticles as a New Paradigm for the Treatment of Internal Bacterial Infections

Transition metal ions such as Ag+, Cu2+, and Zn2+ are utilized as sterile agents thousands of years ago. Unfortunately, these metal ions in the form of traditional metal or metal oxide nanoparticles cannot be directly medicated into human body due to the potential toxicity. Herein, novel Zn2+-epsilon-poly(l-lysine) (EPL)-protocatechuic aldehyde (PCA)-based hybrid nanoparticles (ZEP NPs) with on-demand release capability are synthesized for the first time by one-step coordination self-assembly of Zn2+, EPL, and PCA to address this issue. The ZEP NPs can effectively adhere on bacterial cells and release Zn2+ in situ due to the decomposition of ZEP NPs in acidic infection microenvironment. More importantly, ZEP NPs exhibit excellent bactericidal ability in a protein-rich environment, in which free Zn2+ completely loses its bactericidal ability. The excellent bactericidal effect of ZEP NPs is confirmed in a skin infection model and a lung infection model, demonstrating the great potential to deal with internal infections. Meanwhile, ZEP NPs exhibit negligible toxicity since the dose of Zn2+ can be significantly reduced compared to the commercial zinc oxide nanoparticles (ZnO NPs). The outstanding bactericidal ability as well as negligible toxicity of ZEP NPs makes it ideal candidate of next generation antibacterial agents in treating internal infections.

Automated summary

Transition metal ions have been used as sterilizing agents for thousands of years, but traditional metal or metal oxide nanoparticles cannot be directly medicated into the human body due to potential toxicity. Novel Zn2+-epsilon-poly(l-lysine)-protocatechuic aldehyde-based hybrid nanoparticles with on-demand release capability were synthesized for the first time in this study. These nanoparticles effectively adhere to bacterial cells, release Zn2+ in situ, exhibit excellent bactericidal ability, and show negligible toxicity, making them ideal candidates for treating internal infections.