Hydrogen sulfide (H2S)
is an important endogenous gas
signal molecule in living system, which participates in a variety
of physiological processes. Very recent evidence has accumulated to
show that endogenous H2S is closely associated with various
cancers and can be regarded as a biomarker of cancer. Herein, we have
constructed a new near-infrared fluorescent probe (DCP-H2S) based on isophorone-xanthene dye for sensing hydrogen sulfide
(H2S). The probe shows remarkable NIR turn-on signal at
770 nm with a large Stokes shift of 200 nm, together with high sensitivity
(15-fold) and rapid detection ability for H2S (4 min).
The probe also possesses excellent selectivity for H2S
over various other analytes including biothiols containing sulfhydryl
(−SH). Moreover, DCP-H2S has been successfully applied
to visualize endogenous and exogenous H2S in living cells
(293T, Caco-2 and CT-26 cells). In particular, the excellent ability
of DCP-H2S to distinguish normal mice and tumor mice is
shown, and it is expected to be a powerful tool for detection of H2S in cancer diagnosis.
Cysteine (Cys) is a crucial biological thiol that has a vital function in preserving redox homeostasis in organisms. Studies have shown that Cys is closely related to the development of cancer. Thus, it is necessary to design an efficient method to detect Cys for an effective cancer diagnosis. In this work, a novel tumor-targeting probe (Bio-Cy-S) for dualmodal (NIR fluorescence and photoacoustic) Cys detection is designed. The probe exhibits high selectivity and sensitivity toward Cys. After reaction with Cys, both NIR fluorescence and photoacoustic signals are activated. Bio-Cy-S has been applied for the dual-modal detection of Cys levels in living cells, and it can be used to distinguish normal cells from cancer cells by different Cys levels. In addition, the probe is capable of facilitating dual-modal imaging for monitoring changes in Cys levels in tumor-bearing mice. More importantly, the excellent tumor-targeting ability of the probe greatly improves the signal-to-noise ratio of imaging. To the best of our knowledge, this is the first Cys probe to combine targeting and dual-modal imaging performance for cancer diagnosis.
Adenosine 5′-triphosphate (ATP) is the energy currency in cells. It is involved in numerous cellular life activities and exhibits a close association with the development of certain diseases. Thus, the precise detection of ATP within cells holds immense significance in understanding cell biological events and related disease development. Fluorescent probes have obvious advantages in imaging ATP in cells and in vivo due to their high sensitivity, good selectivity, real-time imaging, and good biocompatibility. Thus far, an extensive array of fluorescent probes targeting ATP has been formulated to enable the visualization of ATP within cells and in vivo. This review summarizes the recent advances in ATP fluorescent probes according to different design strategies, mainly including those based on organic small molecules, metal complexes, and water-soluble conjugated polymers. In addition, the practical applications of ATP fluorescent probes in the imaging of target organelles, cell biological events, and disease markers are highlighted. Finally, the challenges and future trends of ATP detection based on fluorescent probes are discussed.
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