Abstract

Mercury (Hg) is considered an extremely toxic heavy metal which is extremely harmful to both the human body and environment. In addition, Hg²⁺-induced oxidative stress also exerts a crucial role to play in pathophysiological mechanisms of mercury toxicity. Thus, efficient and specific fluorescent probes for imaging Hg²⁺-induced oxidative stress are necessary. In the present study, we rationally design a novel Hg²⁺-activated and ICT-based NIR emission fluorescent probe <b>NIR-HO</b> for sequentially monitoring the ONOO^- level with a "dual-key-and-lock" strategy. The probe <b>NIR-HO</b> showed rapid response and excellent specificity and sensitivity for the detection of Hg²⁺ and ONOO^- in vitro. Cell imaging demonstrated that Hg²⁺-induced oxidative stress was involved in ONOO^- upregulation. Also, GSH, NAC, and EDTA were employed as excellent detoxifying drugs against Hg²⁺-induced toxicity. Moreover, the probe <b>NIR-HO</b> was successfully used for imaging Hg²⁺ and ONOO^- in vivo. In brief, <b>NIR-HO</b> provides a simple and powerful approach which can be used to image Hg²⁺-induced oxidative stress in the pathological environment.