Mitochondria-Targeted Reaction-Based Fluorescent Probe for Hydrogen Sulfide

A new H2S-specific near-infrared fluorescence-enhanced probe that can visualize the H2S level in colorectal cancer cells in mice

Near-infrared (NIR) fluorescence-based sensors capable of selective detection of H2S in vivo would be useful tools to understand the mechanisms of diseases. A new NIR fluorescence probe 1 was developed for the detection of endogenous H2S in colorectal cancer cells in mice. 1 displayed an 87-fold fluorescence enhancement at 796 nm (with excitation at 730 nm) when reacted with H2S in a buffer (pH 7.4). 1 was water-soluble, cell-membrane-permeable, had low cytotoxicity and high selectivity and sensitivity for H2S. The properties of 1 enable its use in monitoring endogenous H2S in living cells, tissues, and mice. The bioimaging results indicated that (1) d-Cys could induce endogenous H2S production in living cells and stimulate angiogenesis; (2) tail intravenous injection of 1 into mice generated strong fluorescence in the liver while intraperitoneal injection of d-Cys could further enhance fluorescence in the liver in vivo; (3) importantly, endogenous H2S in colorectal cancer cells (HCT116, HT29) in vitro and in murine tumor models could be quickly and selectively detected by intratumoral injection of 1. These results indicated that our new probe could serve as an efficient tool for the detection of cellular H2S in living animals and even for cancer diagnosis.

A new fluorescent probe for colorimetric and ratiometric detection of sulfur dioxide derivatives in liver cancer cells

A new ratiometric fluorescent probe was constructed with hemicyanine and 7-nitrobenzofurazan for detection of sulfur dioxide derivatives (HSO₃⁻/SO₃²⁻). The ratiometric response mode could be attributed to the efficient FRET (Förster resonance energy transfer) platform. The probe exbihited some desirable properties including fast response (within 2 minutes), good selectivity and high sensitivity. Moreover, the probe could detect endogenous HSO₃⁻ in liver cancer cells rather than normal liver cells, implying the diagnosal potential of the probe.

UV and fluorescent spectra study the reaction between 1, 8-Naphthalimide derivative and hypochlorite their applications

Two simple, efficient turn-on fluorescent probes for hypochlorite have been rationally designed and developed by utilizing the oxidation of hypochlorite. Notably, probe 1 and 2 displayed rapid and remarkable turn-on responses to ClO^- in PBS buffer solution (pH7.4). Further, the optical properties of two probes and their ClO^--addition products were confirmed by density functional theory calculations. And detection limits of two probes for ClO^- based on the definition by IUPAC were calculated for 2.882nM and 0.354μM. More importantly, cell imaging experiments demonstrated that probe 1 was more suitable for detecting the ClO^- in living A549 cells. And both two probes had the possibility of potentially applied in practical applications such as detecting the hypochlorite concentration of tap water and river water.

Real-Time Monitoring ATP in Mitochondrion of Living Cells: A Specific Fluorescent Probe for ATP by Dual Recognition Sites

Adenosine triphosphate (ATP) is mainly produced in the mitochondrion and used as a universal energy source for various cellular events. Various fluorescent probes for ATP have been established successfully, but most of them are not appropriate for monitoring the fluctuation of the mitochondrial ATP level. Herein, a fluorescent probe named Mito-Rh is first synthesized and used to recognize ATP in mitochondrion. In the probe, rhodamine, diethylenetriamine, and triphenylphosphonium are selected as fluorophore, reaction site, and mitochondrion-targeting group, respectively. Probe Mito-Rh shows high sensitivity to ATP with 81-fold fluorescence enhancement, and the detection range (0.1-10 mM) can match the concentration level of ATP in the mitochondrion. Moreover, Mito-Rh provides excellent selectivity toward ATP over other biological anions (ADP, AMP, GTP, CTP, UTP) owing to a concurrent effect of dual recognition sites (hydrogen bond and π-π stacking). In particular, the probe can localize in mitochondrion specifically and demonstrates utility in the real-time detection of mitochondrial ATP concentration changes.

A two-photon fluorescent probe for specific detection of hydrogen sulfide based on a familiar ESIPT fluorophore bearing AIE characteristics

A two-photon fluorescent probe based on an ESIPT fluorophore bearing AIE characteristics was utilized to detect H₂S.

A novel two-photon fluorescent probe for hydrogen sulfide in living cells using an acedan–NBD amine dyad based on FRET process with high selectivity and sensitivity

The first NBD amine based two-photon fluorescence probe L using a FRET strategy was developed for the H₂S detecting in vitro and in vivo. The probe L not only afforded high selectivity and sensitivity for H₂S detecting, but also dispalyed a linear response to H₂S with a low detection limit 24 nM.

A novel isophorone-based red-emitting fluorescent probe for selective detection of sulfide anions in water for in vivo imaging

A new red-emitting fluorescent probe for detection of sulfide anions in living cells (MCF-7 cells) and zebrafish was developed.

Thiolysis of NBD-based dyes for colorimetric and fluorescence detection of H2S and biothiols: design and biological applications

H₂S-specific fluorescent/colorimetric probes based on the thiolysis of NBD dyes are summarized.

Targetable N-annulated perylene-based colorimetric and ratiometric near-infrared fluorescent probes for the selective detection of hydrogen sulfide in mitochondria, lysosomes, and serum

The N-annulated perylene-based ratiometric NIR fluorescent probes were firstly developed to detect H₂S in mitochondria, lysosomes, and serum.

Investigation of thiolysis of NBD amines for the development of H2S probes and evaluating the stability of NBD dyes

Colorimetric and fluorescent turn-on probes based on thiolysis of NBD ether were explored for selective detection of H₂S.