Surface Metallization of Porous Polymer Materials for Multifunctional Applications.

Porous materials have attracted great interest in recent years, and a variety of surface modification methods have been developed to endow porous materials with multifunctional applications. Herein, multifunctional porous materials are fabricated based on surface metallization. Metallized sponges with Ag and Cu are highly hydrophobic and are still hydrophobic under oil. The metallized sponges selectively adsorb oils from oil/water mixtures and can completely remove oils from water. We further demonstrate continuous oil-water separation by the metallized sponges with the aid of a peristaltic pump. The Ag-metallized materials show high catalytic performance for both chemical reduction and dye degradation. The catalytic reduction efficiency of 4-nitrophenol reaches 97.7% within 60 min and remains as high as 96% after 15 cycles. Moreover, the metallized materials show 99.99% bactericidal efficiency for both Staphylococcus aureus and Escherichia coli. Particularly, the Cu-metallized materials exhibit stable conductivity under deformation; and metal patterns are realized via the metallization method combined with a patterned mask, which may provide a feasible approach for flexible electronics. This work provides a versatile method to introduce metal coatings to porous materials, broadening the applications of porous materials.

Versatile RBC-derived vesicles as nanoparticle vector of photosensitizers for photodynamic therapy.

Various nanocarriers for photosensitizers have been developed to solve the problems of limiting the clinical utility of photodynamic therapy (PDT); however, to date, no carriers capable of supplying oxygen have been reported. We reported the development of a novel system composed of red blood cell (RBC)-derived vesicles (RDVs) generated by osmotic stress and demonstrated the capacity of RDVs for encapsulating and delivering external cargo into targeted cells due to the cellular uptake of RDVs. In this study, protoporphyrin IX (PpIX)-encapsulated RDVs (PpIX@RDVs) were prepared by the hypotonic incorporation of PpIX into RDVs in an aqueous environment, characterized, and utilized for PDT of cancer. PpIX@RDVs were rapidly uptaken by tumor cells via endocytosis in vitro, and the highly phototoxic effect of PpIX@RDVs was demonstrated upon irradiation. Superoxide anion (O(2)˙) and singlet oxygen ((1)O(2)) were involved in PpIX@RDV-induced cell apoptosis and necrosis. Finally, we demonstrated that RDVs with an oxygen supply capacity have potential as versatile delivery vehicles for efficient PDT.

The selective growth inhibition of oral cancer by iron core-gold shell nanoparticles through mitochondria-mediated autophagy.

Nanoparticles with an iron core and gold shell (denoted "Fe@AuÓ") have been reported to limit cancer-cell proliferation and therefore have been proposed as a potential anti-cancer agent. However, the underlying mechanisms are still unknown. In this study, we used flow cytometry, confocal fluorescence microscopy, and transmission electron microscopy to analyse the morphological and functional alterations of mitochondria in cancerous cells and healthy cells when treated with Fe@Au. It was found that Fe@Au caused an irreversible membrane-potential loss in the mitochondria of cancer cells, but only a transitory decrease in membrane potential in healthy control cells. Production of reactive oxygen species (ROS) was observed; however, additions of common ROS scavengers were unable to protect cancerous cells from the Fe@Au-induced cytotoxicity. Furthermore, iron elements, before oxidation, triggered mitochondria-mediated autophagy was shown to be the key factor responsible for the differential cytotoxicity observed between cancerous and healthy cells.