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Dual-Locked Probe with Activatable Sonoafterglow Luminescence for Precise Imaging of MET-Induced Liver Injury

Zhicun Yao, Fei Xu, Rongrong Wu, Xian Wang, Mao Guo, Shuhan Wang, Kaiqiong Yang, Wei Du, Jibin Song

2024Analytical Chemistry14 citationsDOI

Abstract

Metformin (MET) is currently the first-line treatment for type 2 diabetes mellitus (T2DM). However, overdose and long-term use of MET may induce a serious liver injury. What’s worse, diagnosis of MET-induced liver injury remains challenging in clinic. Although several probes have been reported for imaging MET-induced liver injury utilizing upregulated hepatic H 2 S as a biomarker, they are still at risk of nonspecific activation in complex physiological environments and rely on light excitation with limited imaging depth. Herein, we rationally designed and developed a dual-locked probe, DPA-H 2 S, for precise imaging of MET-induced liver injury by H 2 S-activated sonoafterglow luminescence. DPA-H 2 S is a small molecule consisting of a sonosensitizer protoporphyrin IX (PpIX) and an afterglow substrate that is dual-locked with a H 2 S-responsive 2,4-dinitrobenzene group and a 1 O 2 -responsive electron-rich double bond. When employing DPA-H 2 S for imaging of MET-induced liver injury in vivo, since the PpIX moiety can produce 1 O 2 in situ at the liver site under focused ultrasound (US) irradiation, the two locks of DPA-H 2 S can be specifically activated by the highly upregulated H 2 S at the liver injury sites and the in situ generated 1 O 2, respectively. Thus, the sonoafterglow signal of DPA-H 2 S is significantly turned on, enabling precise imaging of the MET-induced liver injury. In vitro results showed that, through H 2 S-activated sonoafterglow luminescence, DPA-H 2 S was capable of imaging H 2 S with good sensitivity and high selectivity and realized deep tissue imaging (∼20 mm, signal-to-background ratio (SBR) = 3.4). Furthermore, we successfully applied DPA-H 2 S for precise in vivo imaging of MET-induced liver injury. We anticipate that our dual-locked probe, DPA-H 2 S, may serve as a promising tool in assisting the diagnosis of MET-induced liver injury in clinics and informing the clinical utilization of MET in the near future.

Topics & Concepts

ChemistryLuminescenceDual (grammatical number)Luminescent MeasurementsNanotechnologyOpticsLiteratureMaterials scienceArtPhysicsNanoplatforms for cancer theranosticsRadiation Detection and Scintillator TechnologiesLuminescence and Fluorescent Materials