机构地区:[1]Department of Chemistry, Al Shujaa Bin Al Aslam School, Farwaniya, Kuwait
出 处:《Advances in Nanoparticles》2022年第1期13-22,共10页纳米粒子(英文)
摘 要:This work shows that novel virus-like mesopore silica-zinc oxide/Ag nanoparticles (SZnOAg) synthesized and professionally collected on NIR laser irradiation with quercetin to improve the elimination the mutated virus as a biomedical application. A unique type of silica nanoparticles with a self-in- flating tubular surface has been successfully synthesized using a novel single-micelle epitaxial growth process. The properties of the nanoparticles can be tuned with respect to their core diameter, tubular length, and outer diameter. Due to their biomimetic appearance, they can rapidly transform living cells into virus-like particles, this SZnOAg nanomaterial has specific elimination effect on bacteriophage and Covid-19. Using epitaxial growth, we can construct virus-like structures that can be used for biomedicine applications. These nanomaterials and NIR laser could open the way to a new range of antiviral materials, due to the low-efficiency cellular uptake of current nanoparticles, their applications in the biomedical field are limited. Herein, it clearly shows that novel mesoporous silica nanoparticles can be easily exhibited superior cellular uptake property.This work shows that novel virus-like mesopore silica-zinc oxide/Ag nanoparticles (SZnOAg) synthesized and professionally collected on NIR laser irradiation with quercetin to improve the elimination the mutated virus as a biomedical application. A unique type of silica nanoparticles with a self-in- flating tubular surface has been successfully synthesized using a novel single-micelle epitaxial growth process. The properties of the nanoparticles can be tuned with respect to their core diameter, tubular length, and outer diameter. Due to their biomimetic appearance, they can rapidly transform living cells into virus-like particles, this SZnOAg nanomaterial has specific elimination effect on bacteriophage and Covid-19. Using epitaxial growth, we can construct virus-like structures that can be used for biomedicine applications. These nanomaterials and NIR laser could open the way to a new range of antiviral materials, due to the low-efficiency cellular uptake of current nanoparticles, their applications in the biomedical field are limited. Herein, it clearly shows that novel mesoporous silica nanoparticles can be easily exhibited superior cellular uptake property.
关 键 词:Bacteriophage Biomedical Applications Covid-19 Omicron Epitaxial Growth Zinc/Silica/Silver Nanoparticles Infectious Diseases NIR Laser SEM/TEM Photothermal QUERCETIN Virus-Like Mesopore
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