烟台大学药学院;烟台大学新型制剂与生物技术药物研究山东省高校协同创新中心;烟台大学分子药理和药物评价教育部重点实验室;
目前,由于抗生素滥用,食品和环境中的抗生素残留污染已经成为一个世界性问题。开发准确、实时、高通量、简便、经济的检测方法以评估食品和生物样品中的抗生素残留显得尤为迫切。随着纳米技术的不断发展,纳米材料在医疗和检测等方面得到广泛应用。基于纳米材料建立的抗生素检测方法可以克服传统检测方法灵敏度低、检测速度慢等缺点,将碳基纳米材料引入生物传感器,可以显著放大各类生物传感器的信号,增强分析物与受体之间的相互作用,提高灵敏度和选择性。此外,在纳米材料中引入氟可以增强碳基纳米材料中碳的电负性,使其与周围溶剂发生相互作用,增加电荷载流子密度和偶极子相互作用,降低表面能,从而改善材料的稳定性以及电化学性能。结合近年来国内外相关文献,总结了纳米材料的类型及特点,对含氟纳米材料检测抗生素的方法进行了综述,主要包括荧光碳点、比色法和表面增强拉曼散射(SERS)等。同时也阐述了含氟材料的预处理方法以及其在色谱固定相中的应用和发展前景。
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基本信息:
DOI:10.13822/j.cnki.hxsj.2025.0008
中图分类号:O657;TB383.1;X830.2
引用信息:
[1]王蕊,隋磊,刘轩语等.含氟材料在抗生素检测中的应用[J].化学试剂,2025,47(05):84-91.DOI:10.13822/j.cnki.hxsj.2025.0008.
基金信息:
国家自然科学基金项目(22404143); 山东省自然科学基金资助项目(ZR2024QB032)