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Near-infrared Fluorescent Probe For Imaging Nitroxyl In Living Cells And Zebrafish Model

Tianlin Wang, Chai Yun, S. Chen, Guichun Yang, C. Lu, J. Nie, C. Ma, Z. Chen, Q. Sun, Y. Zhang, J. Ren, Feiyi Wang, Weihong Zhu
Published 2019 · Chemistry

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Abstract Nitroxyl (HNO) is one of the important derivatives of nitric oxide (NO). It was intertwined with various biological and pharmacological events as a well-defined active molecule. Developing fluorescent probes for high specific and in situ trapping of HNO in living samples is still challenging. In this project, we constructed a near-infrared (NIR) metal-free fluorescent probe (DCM-P) for monitoring HNO in vitro and in vivo. The novel probe, DCM-P, contains a dicyanomethylene-4H-pyran (DCM) fluorophore as the reporter and a triarylphosphine as the recognition moiety. Upon exposure to HNO, the probe emits fluorescence at the wavelength of 688 nm, which belongs to near-infrared region and endows great beneficial for imaging in vivo. Moreover, DCM-P shows high chemoselective detection and fast response to HNO in the presence of various biological relevant reductants, and is successfully employed to trap nitroxyl in different living cells and zebrafish models. These results suggest that DCM-P is a suitable near-infrared metal-free fluorescent probe for motoring nitroxyl in living samples.
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