Hydrogen
sulfide (H2S) is a significant component of
various physiological processes, and it can also cause a negative
effect on foodstuffs. In this work, we designed and synthesized an
NIR fluorescent turn-on responding probe (DDM-H
2
S) with a large Stokes shift (190 nm)
for the detection of H2S. DDM-H
2
S exhibited high selectivity and sensitivity,
obvious color changes, and a fast response time for tracing H2S. When DDM-H
2
S reacted with H2S, the PET process was eliminated, and
the recovered ICT process and NIR fluorescence were observed. Moreover, DDM-H
2
S could image endogenous
and exogenous H2S in living HeLa cells and zebrafish. What
is more, the probe DDM-H
2
S could be deposited easily to test paper strips, which were
able to detect the H2S gas produced during food spoilage
(such as eggs, raw meat, and fishes) by the color of test paper strips
changing from pink to purple. Therefore, this work provides a promising
approach for monitoring H2S in complicated biological systems
and practical food samples.
Hepatic lipid droplets (LDs) and peroxynitrite (ONOO–) levels are closely related to nonalcoholic fatty
liver disease
(NAFLD). Additionally, some drug-induced liver injury (DILI) is often
associated with ONOO–. Here, we constructed and
screened the quasi-LDs-targeted and ONOO–-responsive
fluorescent probe MBDP-Py+
to investigate
the interaction of NAFLD with DILI. By monitoring the upregulation
of the ONOO– levels and the accumulation of LDs, MBDP-Py+
was more sensitive and efficient than
tissue staining and serum markers detection in evaluating the early
toxicity of NAFLD and diagnosing the anticancer-DILI. More importantly,
the sensitive enhancement of fluorescence signals demonstrated that
in different stages of NAFLD, the dominant element of liver injury
was different in the NAFLD combined with DILI mice models. As the
degree of NAFLD deepens, the synergistic effect of the two will lead
to more serious liver damage.
Herein, by optimizing phenyl selenide-based BODIPYs, BDP-Se-MOS was obtained, which possessing resistance to ROS, and could selectively detect Cys. BDP-Se-MOS could not only discriminate between normal and cancer cells, but...
Inflammation is a vital protective response in living systems and closely related to various diseases. As a member of the reactive oxygen species (ROS) family, peroxynitrite (ONOO−) is involved in the organism’s inflammatory process and considered as an important biomarker of inflammation. Therefore, the construction of a simple, rapid, and sensitive tool for detecting ONOO− is of great importance for the diagnosis of inflammation. In this study, we constructed the new near-infrared fluorescence probe BDP-ENE-S-Py+ based on BODIPY dye, which has the advantages of fast response speed (2 min), good selectivity, and a high signal-to-noise ratio. Moreover, the probe had a good linear relationship (LOD = 120 nM) when the ONOO− concentration was 10–35 µM. In addition, BDP-ENE-S-Py+ could detect exogenous ONOO− in liver cancer cells without interference from other reactive oxygen species and visualize the fluctuations in ONOO− concentrations in cells. More importantly, BDP-ENE-S-Py+ was able to track the upregulation of ONOO− content in a mouse model of peritonitis induced by LPS. This work demonstrated that the near-infrared fluorescent probe for visualizing ONOO− level fluctuations could provide a promising tool for inflammation-related studies.
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