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光可切换螯合物:金属离子的光学控制与传感

Optically switchable chelates: optical control and sensing of metal ions.

作者信息

Sakata Tomoyo, Jackson David K, Mao Shu, Marriott Gerard

机构信息

Department of Physiology, University of Wisconsin, 1300 University Avenue, Madison, Wisconsin 53706, USA.

出版信息

J Org Chem. 2008 Jan 4;73(1):227-33. doi: 10.1021/jo7019898. Epub 2007 Dec 12.

DOI:10.1021/jo7019898
PMID:18072788
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2518625/
Abstract

This study introduces new concepts in the design, synthesis, and in vitro and in vivo characterization, manipulation, and imaging of organic chelates whose association with metal ions is rapidly and reversibly controlled by using light. Di- and tricarboxylic group bearing photochromes, nitrobenzospiropyran (nitroBIPS), undergo rapid and reversible, optically driven transitions between their spiro (SP) and fluorescent merocyanine (MC) states. The MC state of nitroBIPS-8-DA binds tightly to various metal ions resulting in specific shifts in absorption and fluorescence, and the dissociation constant for its Gadolinium complex in water is measured at approximately 5 microM. The metal-bound MC state is converted to the weaker-binding SP state with use of 543 nm light, while the SP to MC transition is complete with use of 365 or 720 nm (2-photon) light within several microseconds. Fluorescence imaging of the MC state of nitroBIPS-8-TriA was used to quantify the rate and efficiency of optical switching and to provide a real-time readout of the state of the optically switchable chelate within living cells.

摘要

本研究介绍了有机螯合物在设计、合成、体外和体内表征、操控及成像方面的新概念,这类有机螯合物与金属离子的结合可通过光实现快速且可逆的控制。带有二羧酸和三羧酸基团的光致变色化合物,即硝基苯并螺吡喃(nitroBIPS),能在其螺环(SP)态和荧光部花青(MC)态之间进行快速且可逆的光驱动转变。硝基BIPS - 8 - DA的MC态能与多种金属离子紧密结合,导致吸收和荧光发生特定变化,其钆配合物在水中的解离常数经测定约为5微摩尔。利用543纳米的光可将金属结合的MC态转变为结合力较弱的SP态,而在几微秒内使用365或720纳米(双光子)光可使SP态完全转变为MC态。硝基BIPS - 8 - TriA的MC态的荧光成像被用于量化光开关的速率和效率,并实时读取活细胞内光开关螯合物的状态。

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