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生物相关应用中的发光镧系元素:从分子到纳米颗粒,从诊断探针到治疗手段。

Luminescent Lanthanides in Biorelated Applications: From Molecules to Nanoparticles and Diagnostic Probes to Therapeutics.

作者信息

Alexander Carlson, Guo Zhilin, Glover Peter B, Faulkner Stephen, Pikramenou Zoe

机构信息

Chemistry Research Laboratory, Department of Chemistry, University of Oxford, 12 Mansfield Road, Oxford OX1 3TA, United Kingdom.

Department of Chemistry, Hong Kong Baptist University, Kowloon Tong, Hong Kong SAR, China.

出版信息

Chem Rev. 2025 Feb 26;125(4):2269-2370. doi: 10.1021/acs.chemrev.4c00615. Epub 2025 Feb 17.

DOI:10.1021/acs.chemrev.4c00615
PMID:39960048
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11869165/
Abstract

Lanthanides are particularly effective in their clinical applications in magnetic resonance imaging and diagnostic assays. They have open-shell 4 electrons that give rise to characteristic narrow, line-like emission which is unique from other fluorescent probes in biological systems. Lanthanide luminescence signal offers selection of detection pathways based on the choice of the ion from the visible to the near-infrared with long luminescence lifetimes that lend themselves to time-resolved measurements for optical multiplexing detection schemes and novel bioimaging applications. The delivery of lanthanide agents in cells allows localized bioresponsive activity for novel therapies. Detection in the near-infrared region of the spectrum coupled with technological advances in microscopies opens new avenues for deep-tissue imaging and surgical interventions. This review focuses on the different ways in which lanthanide luminescence can be exploited in nucleic acid and enzyme detection, anion recognition, cellular imaging, tissue imaging, and photoinduced therapeutic applications. We have focused on the hierarchy of designs that include luminescent lanthanides as probes in biology considering coordination complexes, multimetallic lanthanide systems to metal-organic frameworks and nanoparticles highlighting the different strategies in downshifting, and upconversion revealing some of the opportunities and challenges that offer potential for further development in the field.

摘要

镧系元素在磁共振成像和诊断检测的临床应用中特别有效。它们具有外层有4个电子的结构,能产生特征性的窄线状发射,这在生物系统中与其他荧光探针不同。镧系元素发光信号基于从可见光到近红外的离子选择提供了检测途径的选择,其长发光寿命适用于光学复用检测方案的时间分辨测量和新型生物成像应用。细胞中镧系元素试剂的递送允许进行新型疗法的局部生物响应活性。光谱近红外区域的检测与显微镜技术的进步相结合,为深层组织成像和手术干预开辟了新途径。本综述重点关注镧系元素发光可用于核酸和酶检测、阴离子识别、细胞成像、组织成像以及光诱导治疗应用的不同方式。我们专注于设计层次结构,其中包括将发光镧系元素作为生物学中的探针,考虑配位络合物、多金属镧系元素系统到金属有机框架和纳米颗粒,突出了在能量下移和上转换中的不同策略,揭示了该领域进一步发展的一些机遇和挑战。

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3
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J Am Chem Soc. 2024 May 15;146(19):12913-12918. doi: 10.1021/jacs.4c03406. Epub 2024 May 3.
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Nat Commun. 2024 Mar 15;15(1):2341. doi: 10.1038/s41467-024-46727-5.
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Small. 2024 Jul;20(29):e2311729. doi: 10.1002/smll.202311729. Epub 2024 Feb 28.
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