Aleem Abdur Raheem, Liu Jin, Wang Jing, Wang Jing, Zhao Yue, Wang Yao, Wang Yanxin, Wang Wei, Rehman Faisal Ul, Kipper Matt J, Tang Jianguo
Institute of Hybrid Materials, National Center of International Joint Research for Hybrid Materials Technology, National Base of International Sci. & Technology Cooperation on Hybrid Materials, Qingdao University, 308 Ningxia Road, Qingdao, 266071, People's Republic of China.
Department of Medical Oncology, The Affiliated Hospital of Qingdao University, Qingdao University, Qingdao, 266003, People's Republic of China.
J Hazard Mater. 2020 Nov 15;399:122991. doi: 10.1016/j.jhazmat.2020.122991. Epub 2020 May 25.
Fluorescent lanthanide complexes have favorable features for fluorescence-based sensors compared to organic fluorophores and quantum dots. They exhibit very long fluorescence lifetimes, sharp emission bands, and stability with respect to photo-bleaching, without blinking. However, these complexes are usually hydrophobic, and many are excited by UV light, making them hazardous and incompatible with aqueous environments and biological samples. In this work, the strong fluorescent Eu-induced aggregates of polysaccharides (EIAP) was used to improve their aqueous solubility, and to tune the appropriate excitation wavelength in the visible range for avoiding toxicity of UV light in biological applications. The complexes exhibit bright fluorescence with an excitation maximum in the visible range, near 405 nm. EIAP 3 also exhibit rapid quenching response in the presence of transition metal ions. This enables the detection of Cu and Fe below 1 ppm. The reverse of quenching response of copper by the addition of a chelating agent makes it possible to recover the fluorescence property. Successfully, the EIAP exhibit cytocompatibility with mammalian cells. Thus, these new polysaccharide-based complexes have the potential for rapid, sensitive and selective metal ion sensors for the environmental systems.
与有机荧光团和量子点相比,荧光镧系元素配合物在基于荧光的传感器方面具有有利特性。它们具有非常长的荧光寿命、尖锐的发射带,并且对光漂白具有稳定性,不会闪烁。然而,这些配合物通常是疏水的,并且许多是由紫外光激发的,这使得它们具有危险性且与水性环境和生物样品不相容。在这项工作中,强荧光铕诱导的多糖聚集体(EIAP)被用于提高其在水中的溶解度,并在可见光范围内调节合适的激发波长,以避免紫外光在生物应用中的毒性。这些配合物在可见光范围内、接近405nm处具有最大激发波长,表现出明亮的荧光。EIAP 3在过渡金属离子存在下也表现出快速猝灭响应。这使得能够检测到低于1ppm的铜和铁。通过添加螯合剂使铜的猝灭响应逆转,从而有可能恢复荧光特性。EIAP成功地表现出与哺乳动物细胞的细胞相容性。因此,这些新型的基于多糖的配合物有潜力成为用于环境系统的快速、灵敏和选择性金属离子传感器。
