Rundong Yang , Siyan Liu , Feifei Wang , Shuyi Li , Na Zhang , Zhenzhou Zhu
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引用次数: 0
Abstract
Laminaria polysaccharides (LP) have been shown to effectively stabilize selenium nanoparticles (SeNPs), forming LP–SeNP complexes with enhanced bioactivity. However, the correlation between their bioactivity and physicochemical properties remains inadequately explored. This study used chemical reduction with LP as stabilizer to investigate how LP-to-selenium mass ratio (LPSMR), reaction time, and temperature influence particle size, selenium content, and 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavenging activity of LP–SeNPs. The results showed that enhanced DPPH scavenging correlated with higher selenium content and smaller particle size, primarily modulated by LPSMR and temperature. Under optimal conditions (LPSMR of 1; temperature of 25°C), the resulting LP–SeNPs exhibited uniform morphology with a particle size of 81.41 nm and selenium content of 653.91 mg/g. This stability was achieved through non-covalent interactions between LP and SeNPs, providing superior light and acid resistance compared to unmodified SeNPs. Notably, LP–SeNPs showed synergistic antioxidant effects, with lower half-maximal inhibitory concentration (IC50) values for scavenging DPPH, hydroxyl, and superoxide anion radicals than LP or SeNPs alone, and enhanced hypoglycemic activity. Cytotoxicity assays confirmed LP–SeNPs had reduced toxicity compared to Na2SeO3 and selenopeptide. These findings provide insights into the structure-activity relationships of LP–SeNPs and support their potential application as antioxidant and hypoglycemic agents.
期刊介绍:
Process Biochemistry is an application-orientated research journal devoted to reporting advances with originality and novelty, in the science and technology of the processes involving bioactive molecules and living organisms. These processes concern the production of useful metabolites or materials, or the removal of toxic compounds using tools and methods of current biology and engineering. Its main areas of interest include novel bioprocesses and enabling technologies (such as nanobiotechnology, tissue engineering, directed evolution, metabolic engineering, systems biology, and synthetic biology) applicable in food (nutraceutical), healthcare (medical, pharmaceutical, cosmetic), energy (biofuels), environmental, and biorefinery industries and their underlying biological and engineering principles.