A multi-functional anti-pathogen coating with release-killing, contact-killing and anti-adhesion properties was prepared from biocompatible polymer encapsulated chlorine dioxide (ClO2) which protected the active ingredient from the outside environment. A slow sustained-release of ClO2 from micelles over fifteen days was detected for long-term release-killing. Micelles only release ClO2 on demand in minimum inhibitory concentrations. We prepared nanoparticles which were covalently clustered on micelle surfaces to improve contact-killing as well as to improve the stability of the micelle. Copper nanoparticles were generated using the biosynthesis method including l-vitamin C, which avoids the toxicity and allows for the preparation of copper nanoparticles in a green environment. Synergistic anti-pathogen activity could be generated by a combination of micelle released ClO2 and ascorbic acid. In addition to release-killing and contact-killing, a pluronic polymer coated surface also provides an additional anti-adhesion property through its protein-repelling ability. In this research, the designed coating demonstrated a broad-spectrum of activity to kill drug-resistant bacteria, viruses and spores in short period of time. Based on scanning electron microscopy (SEM), transmission electron microscopy (TEM) and anti-oxidase assays, we found that the designed coatings killed the pathogens via bio-oxidation. We also carried out acute respiratory toxicity tests in this research. Analysis of blood samples, lung function and histopathological slices indicated that the synthesized micelles allowed a controlled and sustained release of ClO2 to kill pathogens while maintaining an overall ClO2 concentration in the air within a safe range.

• 出版日期2018
• 单位武汉轻工大学; 武汉科技大学; 上海交通大学; 华中师范大学