RESUMEN
Objective:To establish an aggregation-induced emission vesicle material based on supramolecular host-guest chemical assembly (AIE-HG-Vesicle) for siRNA delivery and fluorescence imaging, and to explore its uptake effect by tumor cells and siRNA-based cell killing effect.Methods:By synthesizing β-cyclodextrin modified with polyethyleneimine dendrimer (H-β-CD-dendrimer) as a host compound and a Bola type adamantane containing tetrastyrene AIE group (G-Ada-AIE) as a guest compound, the nanovesicle material was prepared by a supramolecular host-guest self-assembly process for loading siRNA. The morphology and size of the materials were tested by transmission electron microscopy and the dynamic light scattering method. The aggregation-induced luminescence properties of the materials were investigated by fluorescence spectrophotometry. The loading effect of the material on siRNA was investigated by gel retardation experiments. The delivery effect of siRNA-loaded AIE-HG-Vesicle vesicles in tumor cells was observed by a confocal laser scanning microscope. The killing effect of siRNA-loaded AIE-HG-Vesicle vesicles on tumor cells was tested by an MTT assay.Results:The prepared host-guest compounds can be assembled into vesicles with a size of about 100 nm and wall thickness of 9 nm in solution, and the positively charged vesicles on the surface can efficiently load siRNA. The siRNA-loaded AIE-HG-Vesicle vesicles can deliver siRNA into HeLa tumor cells and can be observed through aggregation-induced luminescence. The siRNA-loaded vesicles have an obvious killing effect on HeLa tumor cells.Conclusions:A vesicle material with aggregation-induced luminescence properties was prepared by a method based on supramolecular host-guest chemical assembly, which can be used to deliver siRNA. The material has fluorescence imaging and siRNA-based tumor cytotoxic effects and is expected to be applied to tumor treatment in vivo.
RESUMEN
Objective:To establish a method for preparing ferritin-Prussian blue nanocomposites (ferritin-PB NPs) and evaluate their photothermal conversion performance and photothermally responsive tumor cell killing effect.Methods:Prussian blue nanomaterials were prepared by the precipitation method and then loaded into the ferritin cavity to construct ferritin-PB NPs. The composition of ferritin-PB NPs was tested by infrared spectroscopy and UV-vis absorption spectroscopy. The size and morphology of ferritin-PB NPs were measured by dynamic light scattering and transmission electron microscopy. The photothermal heating effect and photothermal stability effect of the ferritin-PB NPs material were tested by a thermal imager. The uptake effect of ferritin-PB NPs in HeLa and HepG2 tumor cells was observed by laser confocal microscopy. The photothermal killing effect of ferritin-PB NPs on HeLa tumor cells was tested by the MTT assay.Results:The morphology of the ferritin-PB NPs is a composite structure of ferritin coated with PB NPs, which can rapidly convert light energy into heat energy in response to 730 nm laser irradiation, resulting in a significant increase in the temperature of the test solution. The ferritin-PB NPs were rapidly taken up by HeLa and HepG2 tumor cells and significantly inhibited the proliferation of HeLa cells under 730 nm light irradiation.Conclusions:The ferritin-PB NPs were obtained by a simple preparation method, which has good biocompatibility and photothermal cytotoxicity and is expected to be used for in vivo tumor therapy in the extended research.