Fluorescence Imaging Of Nitric Oxide Research Articles

A Highly Stable Two-Photon Ratiometric Fluorescence Probe for Real-Time Biosensing and Imaging of Nitric Oxide in Brain Tissues and Larval Zebrafish

A Highly Stable Two-Photon Ratiometric Fluorescence Probe for Real-Time Biosensing and Imaging of Nitric Oxide in Brain Tissues and Larval Zebrafish

Fluorescence imaging of nitric oxide in living cells using o-phenylenediamine-rhodamine based polymeric nanosensors.

Direct real-time measurement of nitric oxide (NO) in living cells has proven quite challenging, owing in part to the lack of tools that are selective and sensitive to measure intracellular concentrations of NO. Herein we report the synthesis and characterization of polyvinyl alcohol (PVA) based nanosensors for fluorescence imaging of cytosolic NO using an o-phenylenediamine-rhodamine (OPD-RhB) platform. More specifically, thiol-functionalized PVA incorporating RhB conjugated OPD was disulfide crosslinked to yield NO-responsive nanosensors. The polymeric nanosensors were anionic, averaged 170nm in hydrodynamic size, and exhibited linear increases in fluorescence intensity (FLI) to micro- and nanomolar concentrations of NO in a sodium nitroprusside (SNP) concentration-dependent manner. In the presence of SNP, the engineered nanosensors demonstrated physical stability at extracellular glutathione (GSH) conditions, while favoring NO detection at cytoplasmic GSH conditions. In addition, the PVA-based nanosensors were non-cytotoxic, cell membrane-permeable and demonstrated hydrogen peroxide-dependent FL increases upon incubation with activated synoviocytes in vitro. Most notably, NO-induced cell FLIs correlated strongly with total nitrite/nitrate content of conventional Griess assays with Pearson correlation coefficients of 0.96. Comprehensively, our results show that OPD-RhB-conjugated PVA nanosensors offer real-time imaging of NO with high sensitivity in living cells that can be employed for direct quantification of NO.

An N-nitrosation reactivity-based two-photon fluorescent probe for the specific in situ detection of nitric oxide.

In situ fluorescence imaging of nitric oxide (NO) is a powerful tool for studying the critical roles of NO in biological events. However, the selective imaging of NO is still a challenge because most currently available fluorescent probes rely on the o-phenylenediamine (OPD) recognition site, which reacts with both NO and some abundant reactive carbonyl species (RCS) (such as dehydroascorbic acid and methylglyoxal) and some reactive oxygen/nitrogen species (ROS/RNS). To address this problem, a new fluorescent probe, NCNO, based on the N-nitrosation of aromatic secondary amine was designed to bypass the RCS, ROS, and RNS interference. As was expected, the probe NCNO could recognize NO with pronounced selectivity and sensitivity among ROS, RNS, and RCS. The probe was validated by detecting NO in live cells and deep tissues owing to its two-photon excitation and red-light emission. It was, hence, applied to monitor NO in ischemia reperfusion injury (IRI) in mice kidneys by two-photon microscopy for the first time, and the results vividly revealed the profile of NO generation in situ during the renal IRI process.

Highly selective two-photon fluorescent probe for imaging of nitric oxide in living cells

Abstract A new two-photon fluorescent probe, ADNO, for nitric oxide (NO) based on intramolecular photoinduced electron transfer (PET) mechanism displays a rapid response to NO with a remarkable fluorescent enhancement in PBS buffer. The excellent chemoselectivity of ADNO for NO over other ROS/RNS (reactive oxygen species or nitrogen species) and common metal ions was observed. Moreover, ADNO has been successfully applied in fluorescence imaging of NO of living cells using both one-photon microscopy (OPM) and two-photon microscopy (TPM).

Novel B,O-chelated fluorescent probe for nitric oxide imaging in Raw 264.7 macrophages and onion tissues

A novel fluorescent probe based on B,O-chelated dipyrromethene chromophore in far-visible and near-infrared spectral region (600–900nm), boron chelated 8-(3,4-diaminophenyl)-3,5-bis(2-hydroxyphenyl)-4-bora-3a,4a-diaza-s-indancene (BOPB), has been first developed for nitric oxide (NO) imaging. BOPB, a turn-on fluorescent probe, can react with NO rapidly under physiological condition. The reaction product of BOPB with NO, BOPB-T, emits bright red fluorescence at 643nm when excited at 622nm. Meanwhile, BOPB-T displays high fluorescent quantum yield of 0.21 and good photostability. The selectivity for NO over other reactive oxygen/nitrogen species and ascorbic acid has been investigated and BOPB has good specificity for the detection of NO. MTT assay shows that the toxicity of BOPB (below 10μM) to living cells can be neglected. Based on these investigations, BOPB has been used for NO imaging in Raw 264.7 cells and onion tissues. Meanwhile, mechanical injury to onion tissues results in a brighter fluorescence around the wound, which indicates that more NO has been produced in plant tissues in response to external stimuli. Our studies illustrate that BOPB has advantages of high sensitivity, low background interference and little photo damage on fluorescence imaging of NO.

“Off–on” red-emitting fluorescent probes with large Stokes shifts for nitric oxide imaging in living cells

Fluorescent probes with larger Stokes shifts in the far-visible and near-infrared spectral region (600-900nm) are more superior for cellular imaging and biological analysis due to avoiding light scattering interference, reducing autofluorescence from biological sample and encouraging deeper tissue penetration in vivo imaging. In this work, two bis-methoxyphenyl-BODIPY fluorescent probes for the detection of nitric oxide (NO) have been firstly synthesized. Under physiological conditions, these probes can react with NO to form the corresponding triazoles with 250- and 70-fold turn-on fluorescence emitting at 590 and 620nm, respectively. Moreover, the triazole forms of these probes have large Stokes shifts of 38nm, in contrast to 10nm of existing BODIPY probes for NO. Excellent selectivity has been observed against other reactive oxygen/nitrogen species, ascorbic acid and biological matrix. After the evaluation of MTT assay, new fluorescent probes have been successfully applied to fluorescence imaging of NO released from RAW 264.7 macrophages by co-stimulation of lipopolysaccharide and interferon-γ. The experimental results indicate that our fluorescent probes can be powerful candidates for fluorescence imaging of NO due to the low background interference and high detection sensitivity.

Fluorescence of 1,2‐Diaminoanthraquinone and its Nitric Oxide Reaction Product within Macrophage Cells

Nitric oxide (NO) is involved in many biological processes. Aromatic ortho-diamine derivatives are commonly used in the fluorescence imaging of NO in living cells. ortho-diamino (o-diamino) compounds are believed to react with NO in an oxygenated medium leading to the formation of a triazole derivative. One such o-diamino compound, 1,2-diaminoanthraquinone (DAA), is a nontoxic probe for the detection of NO in living tissues and cells. The formation of the DAA triazole derivative (DAA-TZ) upon reaction of DAA with NO/O(2) within cells has not been demonstrated previously. The aim of this study was to confirm that DAA-TZ is the species formed intracellularly when DAA reacts with NO in the presence of oxygen. The chemical synthesis and characterisation of DAA-TZ was performed together with intracellular studies of DAA and DAA-TZ. Raw 264.7 macrophages were loaded with the DAA or DAA-TZ under conditions of no-stimulation or stimulation with interferon-γ and lipopolysaccharide to produce NO. Confocal microscopy was used to image the DAA-loaded macrophage cells. Analysis of the emission spectra allowed precise discrimination of the fluorescence of each species in the macrophage cells, and confirmed the identity of DAA-TZ as the intracellular reaction product between DAA and NO in the presence of oxygen.

Cell-trappable fluorescent probes for nitric oxide visualization in living cells.

Two new cell-trappable fluorescent probes for nitric oxide (NO) are reported based on either incorporation of hydrolyzable esters or conjugation to aminodextran polymers. Both probes are highly selective for NO over other reactive oxygen and nitrogen species (RONS). The efficacy of these probes for the fluorescence imaging of nitric oxide produced endogenously in Raw 264.7 cells is demonstrated.

A novel fluorescent probe for the detection of nitric oxide in vitro and in vivo

Fluorescence imaging of nitric oxide (NO) in vitro and in vivo is essential to developing our understanding of the role of nitric oxide in biology and medicine. Current probes such as diaminofluorescein depend on reactions with oxidized NO products, but not with nitric oxide directly, and this limits their applicability. Here we report the formation of an imaging probe for nitric oxide by coordinating the highly fluorescent chemical 4-methoxy-2-(1 H-naphtho[2,3- d]imidazol-2-yl)phenol (MNIP) with Cu(II). The coordination compound MNIP–Cu reacts rapidly and specifically with nitric oxide to generate a product with blue fluorescence that can be used in vitro and in vivo. In the present study MNIP–Cu was used to reveal nitric oxide produced by inducible nitric oxide synthase in lipopolysaccharide (LPS)-activated macrophages (Raw 264.7 cells) and by endothelial nitric oxide synthase in endothelial cells (HUVEC). MNIP–Cu was also used to evaluate the distribution of nitric oxide synthesis in a model of acute liver injury induced by LPS and d-galactosamine in mice. The results demonstrate that MNIP–Cu can act as a novel fluorescent probe for nitric oxide and has many potential applications in biomedical research.

Detailed modeling and laser-induced fluorescence imaging of nitric oxide in a NH 3-seeded non-premixed methane/air flame

In this paper, we study the formation of NO in laminar, nitrogen-diluted methane diffusion flames that are seeded with ammonia in the fuel stream. We have performed numerical simulations with detailed chemistry as well as laser-induced fluorescence (LIF) imaging measurements for a range of ammonia injection rates. For comparison with the experimental data, synthetic LIF images are calculated based on the numerical data accounting for temperature and fluorescence quenching effects. We demonstrate good agreement between measurements and computations. The LIF corrections inferred from the simulation are then used to calculate absolute NO mole fractions from the measured signal. The NO formation in both doped and undoped flames occurs in the flame sheet. In the undoped flame, four different mechanisms contribute to NO formation. The present calculations show that the most important pathway is prompt NO, followed by the NNH mechanism, thermal NO, and the N2O mechanism. As the NH3 seeding level increases, fuel-NO becomes the dominant mechanism and N2 shifts from being a net reactant to being a net product. Nitric oxide in the undoped flame as well as in the core region of the doped flames is underpredicted by the model; we attribute this mainly to inaccuracies in the NO recycling chemistry on the fuel-rich side of the flame sheet.