Bioorthogonal cleavage chemistry (BCC) has been extensively applied to fluorescence-based imaging in cancer diagnostics. Its potential in chemiluminescence imaging is to be explored. In this study, a smart ruthenium (Ru)-catalyzed bioorthogonal activation chemiluminescence (BAC) probe is developed by integrating BCC with a phenoxy-adamantyl-1,2-dioxetane (PAD) for real-time, in vivo imaging of thiol-containing metabolites, particularly hydrogen sulfide (H 2S), associated with thiol dysregulation in the tumor microenvironment. The BAC probe overcomes many limitations existed in other chemiluminescence probes via a highly selective “Ru-locked” mechanism to achieve light-independent, thiol-triggered activation in complex tumor microenvironment. This mechanism enables rapid activation (1 min), high sensitivity (LOD = 0.243 μM), and stable luminescence with a half-life of 18.5 h, as determined in vitro, across a broad emission range (400-800 nm). The probe also demonstrates enhanced selectivity for thiol-containing metabolites, particularly H 2S, and exhibits low toxicity both in vitro and in vivo. In a breast cancer mouse model, the probe successfully visualizes endogenous H 2S with high spatial precision, supporting its utility in tumor localization and image-guided surgery. In addition, the PAD scaffolds are developed via an efficient synthetic route, significantly lowering production costs (300- to 400-fold) and increasing yields from 40% to 95%. Furthermore, our BAC probe holds a broad potential for non-invasive diagnosis and real-time monitoring of thiol dysregulation and pathophysiological processes.

Breast cancer remains a leading cause of mortality among women, driving the need for more accurate diagnostic tools. To address this, a smart ruthenium (Ru)-catalyzed bioorthogonal activation chemiluminescent (BAC) probe has been developed for long-lasting non-invasive in vivo imaging. Although chemiluminescence imaging offers ultrahigh sensitivity without background autofluorescence, its application in breast cancer is limited by poor selectivity in complex tumor environments, slow activation kinetics and insufficient resolution. The BAC probe overcomes these challenges via a smart “Ru-locked” mechanism, achieving light-independent, thiol-triggered activation in complex tumor microenvironment. This mechanism enables rapid activation (1 min), prolonged half-life ( t 1/2 = 18.5 h), and high sensitivity (LOD = 87 nM) across a broad emission range (400-800 nm), while enhancing selectivity for thiol-containing metabolites, particularly H 2S. The probe exhibits low toxicity in vitro and efficiently activates chemiluminescence within the tumor microenvironment in vivo, enabling precise imaging for tumor localization and image-guided surgery. Additionally, the phenoxy-adamantyl-1,2-dioxetane luminophores are developed via an efficient synthetic route, which reduces the synthesis from seven steps to two, lowering production costs (300- to 400-fold) and increasing yields from 40% to 95%. This study introduces a smart Ru-locked BAC probe for real-time, non-invasive monitoring of thiol-related homeostasis in breast cancer, with promising application in clinical diagnostic and therapeutic potential.