Photophysical properties of rhodamine isomers: A two-photon excited fluorescent sensor for trivalent chromium cation (Cr)

We introduce a new rhodamine-based fluorescent chemosensor, FD8 which exhibits a distinct two-photon excited fluorescence (TPEF) on/off characteristic upon binding Cr³⁺ ions. By coordination with metal cation, conformation of FD8 changes from spirocyclic to open-ring, resulting in remarkable enhancement of absorption and fluorescence both in one- and two-photon excitations. As a result, a 29-fold enhancement of two-photon excited fluorescent intensity was observed when 10 eq. Cr³⁺ was added to the FD8 solution. The detection limit of Cr³⁺ cation concentration down to 1 μM (0.01 eq. of FD8) was achieved under our experimental condition. Besides the excitation within ultraviolet regime by fluorescence resonance energy transfer (FRET) mechanism, the TPEF on/off behavior further extends the excitation to near infrared regime (the biological optimal window of 700-1200 nm), and shows more effective sensitivity. The broad excitation wavelength, on/off fluorescence and high selectivity to Cr³⁺ enable FD8 to be a powerful Cr³⁺ cation sensor with potential application, especially in biological detection. To the best of our knowledge, this is the first report about two-photon fluorescent sensor for Cr³⁺ ions.     

A FRET approach for luminescence sensing Cr in aqueous solution and living cells through functionalizing glutathione and glucose moieties

A simple FRET-based approach to ratiometric fluorescence sensing of Cr³⁺ in aqueous solution using glutathione and glucose as building blocks was achieved, inspired to the binding motifs of Cr³⁺ in glucose tolerance factors (GTF). Selectivity and competition experiments showed that this system featured high sensitivity (detection limit ≤0.1 ppm) and excellent selectivity over other metal ions in buffer solution. Confocal fluorescence microscopy experiments had established the utility of the approach in monitoring Cr³⁺ within living cells.     

Ratiometric and selective two-photon fluorescent probe based on PET-ICT for imaging Zn2+in living cells and tissues简

A two-photon fluorescent probe TPZn was developed for specific ratiometric imaging Zn2＋ in living cells and tissues. Significant ratiometric fluorescence change was based on photoinduced electron transfer and intramolecular charge transfer. The synthetic method of TPZn was simple. It was successfully used to selectively image Zn2＋ based on the higher binding affinity for Zn2＋ than for Cd2＋. TPZn was easily loaded into the living cell and tissues with high membrane permeability in a complex biological environment. TPZn could clearly visualize endogenous Zn2＋ by TP ratiometric imaging in hippocampal slices at a depth of 120 μm. Thus, TPZn is a useful tool to image of Zn2＋ in living cells and tissues without interference from Cd2＋.     

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

A new two-photon fluorescent probe, ADNO, for nitric oxide （NO） based on intramolecular photoinduced electron transfer （PET） mechanism d/splays 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-~hoton microscopy （TPM）,     

Thiazole-based chemosensor: synthesis and ratiometric fluorescence sensing of zinc

A new ratiometric and selective fluorescent chemosensor (1), based on thiazole for quantification of zinc ions in aqueous ethanol, was synthesized and investigated. The mechanism of fluorescence was based on the cation-induced inhibition of excited-state intramolecular proton transfer (ESIPT).     

Design,photophysical properties,and applications of fluorene-based fluorophores in two-photon fluorescence bioimaging: A review

Two-photon fluorescence microscopy (2PFM) emerged as a powerful alternative to conventional one-photon microscopy. 2PFM typically uses two near-infrared (NIR) photons to excite fluorescent dyes, which minimizes light scattering in biological samples. Multiphoton absorption also suppresses background signal and autofluorescence from tissues and allows to achieve higher 3D resolution images with low photodamage and photobleaching. Fluorene dyes possess distinct properties that meet the strict criteria of probes used for 2PFM such as enhanced solubility, photostability, and two-photon absorption cross-section. The fluorene molecule also includes many active positions that allow versatile synthesis, selective functionalization, bioconjugation, and tuning solubility. These properties have led to reporting several fluorene probes including monomers, polymers, and dendrimers with important uses in understanding molecular dynamics and bioimaging. The current review presents a compact summary of fluorene-based fluorophores for 2PFM bioimaging applications, shedding light on structure-photophysical property relationships in fluorenes and polyaromatic probe designs.     

Ratiometric and turn-on monitoring for heavy and transition metal ions in aqueous solution with a fluorescent peptide sensor

A novel fluorescent peptide sensor containing tryptophan (donor) and dansyl fluorophore (acceptor) was synthesized for monitoring heavy and transition metal (HTM) ions on the basis of metal ion binding motif (Cys-X-X-X-Cys). The peptide probe successfully exhibited a turn on and ratiometric response for several heavy metal ions such as Hg²⁺, Cd²⁺, Pb²⁺, Zn²⁺, and Ag⁺ in aqueous solution. The enhancements of emission intensity were achieved in the presence of the HTM ions by fluorescent resonance energy transfer (FRET) and chelation enhanced fluorescence (CHEF) effects. The detection limits of the sensor for Cd²⁺, Pb²⁺, Zn²⁺, and Ag⁺ were lower than the EPA's drinking water maximum contaminant levels (MCL). We described the fluorescent enhancement, binding affinity, and detection limit of the peptide probe for HTM ions.     

Design of a novel mitochondria targetable turn-on fluorescence probe for hydrogen peroxide and its two-photon bioimaging applications

Considering that hydrogen peroxide (H₂O₂) plays significant roles in oxidative stress, the cellular signal transduction and essential biological process regulation, the detection and imaging of H₂O₂ in living systems undertakes critical responsibility. Herein, we have developed a novel two-photon fluorescence turn on probe, named as Pyp-B for mitochondria H₂O₂ detection in living systems. Selectivity studies show that probe Pyp-B exhibit highly sensitive response toward H₂O₂ than other reactive oxygen species (ROS) and reactive nitrogen species (RNS) as well as biologically relevant species. The fluorescence colocalization studies demonstrate that the probe can localize in the mitochondria solely. Furthermore, as a bio-compatibility molecule, the highly selective and sensitive of fluorescence probe Pyp-B have been confirmed by its cell imaging application of H₂O₂ in living A549 cells and zebrafishes under the physiological conditions.     

An ‘off-on’ fluorescent chemosensor of selectivity to Cr and its application to MCF-7 cells

A ‘switching-on’ fluorescent chemosensor for the selective and sensitive signaling of intraceullar Cr³⁺ has been designed and synthesized exploiting the guest-induced prohibition of the photoinduced electron transfer process between naphthyridine moiety and 7,10-diphenylfluoranthene moiety, the system shows a Cr³⁺-selective chelation-enhanced fluorescence response not only in ethanol but in cell.     

Recent advances in AIEgens for three-photon fluorescence bioimaging

Bioimaging is increasingly becoming an indispensable tool in disease diagnosis, clinical trials and medical practice. Fluorescence bioimaging is minimally invasive, affordable and portable, with the potential to become a widespread medical imaging technique. Currently, a serious challenge obstructing the large-scale clinical applications of fluorescence technique is the shallow penetration depth. Three-photon fluorescence offers several advantages over near-infrared and two-photon fluorescence, such as deeper penetration, more confined excitation areas and higher resolution. On the other hand, fluorophores displaying solid-state fluorescence are intriguing because they can emit bright fluorescence in the condensed phase, which is beneficial to imaging applications demanding intense emission signals. This review highlights the recent advances in small organic AIEgens for three-photon fluorescence bioimaging in vivo. The progress suggests that three-photon fluorescence imaging offers deep penetration, good photostablity and high signal-to-background contrast, which is valuable in fluorescence imaging in vivo.     

A FRET-based fluorescent probe for imaging H2S in living cells

A FRET-based fluorescence probe was developed for selective detection of H₂S in aqueous buffer and inside living cells. For this probe, the FRET probe could be cleaved by H₂S, and the fluorescence of FRET donor is released. The probe is highly selective to H₂S over other biologically relevant species to give color change for naked eye observation. Confocal imaging indicated that the probe could monitor intracellular H₂S level changes.     

Development of a Two-photon Ratiometric Fluorescent Probe for Glutathione and Its Applications in Living Cells

Glutathione(GSH), as the most abundant intracellular biothiol, plays an important role in the redox homeostasis of the organism. Abnormal concentrations of GSH in cells may lead to many malignant diseases, such as cancer, liver damage and neurodegenerative diseases. It is urgent to develop effective methods to detect GSH in living organisms. In this work, a new two-photon ratiometric fluorescent probe Co-GSH based on the coumarin-chalcone dye platform was judiciously developed. Based on the Michael-addition reaction, Co-GSH was able to identify GSH with high selectivity and sensitivity. Furthermore, assisted by laser-scanning confocal microscopy, Co-GSH could specifically response GSH over the other biothiols, including Cys and Hcy, in living HeLa cells by using one-and two-photon modes.     

A bright two-photon fluorescent probe for real-time monitoring autophagy in living cells

A novel donor-acceptor(D-A) type of two-photon(TP) fluorescent probe,i.e.Lyso-OSC,based on the lysosome-targeting morpholine group was developed.The polarity sensing coumarin group was functionalized as the acceptor and the 1-vinyl-4-methoxybenzene group was engineered as the donor.The fluorescence intensity and emission maximum wavelength of Lyso-OSC are highly sensitive to the polarity changes of solvent.The two-photon absorption cross-section and tissue penetration depth are up to 254 GM and 150 μm,respectively.The strong fluorescence,high sensitivity to polarity,low cytotoxicity,and accurate lysosome-targeting ability entail Lyso-OSC the excellent performance in detecting the polarity changes ofcellular environment.To this end,a bright,real-time imaging autophagy of living cells has been achieved.     

A highly selective and ratiometric fluorescence probe for the detection of Hg and pH change based on coumarin in aqueous solution

A simple but highly selective coumarin-based fluorescence probe 1, 8-(1,3-dithiane)-7-hydroxycoumarin was designed and synthesized for both the ratiometric detection of Hg²⁺ and the on–off response to pH change in aqueous solution. The sensor detected Hg²⁺ selectively via Hg²⁺-promoted thioacetal deprotection reaction within five minutes and reflected pH in the range from 7.8 to 11.9 as a result of the equilibrium between weak-fluorescent acid form and strong-fluorescent base form. In addition, the probe has an excellent selectivity towards Hg²⁺ over other competitive metal ions for biomedical and environmental applications. The sensing behavior of our probe was studied by UV–visible absorption spectra and fluorescence spectra.     

Characterization of rhodamine B hydroxylamide as a highly selective and sensitive fluorescence probe for copper(II)

Rhodamine B hydroxylamide (1) is characterized as a highly selective and sensitive fluorescence probe for Cu²⁺. Under the optimized conditions, the probe exhibits specific absorbance-on and fluorescence-on responses to Cu²⁺ only. This remarkable property may allow Cu²⁺ to be detected directly in the presence of the other transition metal ions, and such an application has been demonstrated to human serum. The reaction mechanism is also investigated and proposed as that the hydroxylamide group of 1 binds Cu²⁺, and the subsequent complexation of Cu²⁺ displays a high catalytic activity for the hydrolytic cleavage of the amide bond, causing the release of fluorophore (rhodamine B) and thereby the retrievement of absorbance and fluorescence. The recovered fluorescence intensity is proportional to the concentration of Cu²⁺ in the range 1-20 μM. The detection limit for Cu²⁺ is 33 nM (k = 3). The reaction mechanism described here may be useful for developing excellent spectroscopic probes with cleavable active bonds for other analytes.     

Ratiometric fluorescent and colorimetric sensors for Cu based on 4,5-disubstituted-1,8-naphthalimide and sensing cyanide via Cu displacement approach

Two 4,5-disubstituted-1,8-naphthalimide derivatives 1 and 2 were synthesized as ratiometric fluorescent and colorimetric sensors for Cu²⁺, respectively. In 100% aqueous solutions of 1, the presence of Cu²⁺ induces a strong and increasing fluorescent emission centered at 478 nm at the expense of the fluorescent emission of 1 centered at 534 nm. Compound 2 senses Cu²⁺ by means of a colorimetric (primrose yellow to pink) method with a thorough quench in emission attributed to the deprotonation of the secondary amine conjugated to the naphthalimide fluorophore. 1-Cu²⁺ and 2-Cu²⁺ sense cyanide in ratiometric way via colorimetric and fluorescent changes.     

Design of a novel mitochondria targetable turn-on fluorescence probe for hydrogen peroxide and its two-photon bioimaging applications

Considering that hydrogen peroxide (H₂O₂) plays significant roles in oxidative stress, the cellular signal transduction and essential biological process regulation, the detection and imaging of H₂O₂ in living systems undertakes critical responsibility. Herein, we have developed a novel two-photon fluorescence turn on probe, named as Pyp-B for mitochondria H₂O₂ detection in living systems. Selectivity studies show that probe Pyp-B exhibit highly sensitive response toward H₂O₂ than other reactive oxygen species (ROS) and reactive nitrogen species (RNS) as well as biologically relevant species. The fluorescence colocalization studies demonstrate that the probe can localize in the mitochondria solely. Furthermore, as a bio-compatibility molecule, the highly selective and sensitive of fluorescence probe Pyp-B have been confirmed by its cell imaging application of H₂O₂ in living A549 cells and zebrafishes under the physiological conditions.     

Ratiometric fluorescent determination of Zn(II): a new class of tripodal receptor using mixed imine and amide linkages

We synthesized a novel receptor with a unique combination of sp² nitrogen (-CHN-) and carbonyl groups from amide linkages. These two moieties are judiciously incorporated into the receptor design such that these sites simultaneous binding a metal ion may generate a stable five-member ring. The receptor has been used to selectively detect Zn²⁺ through changes in the fluorescence spectra. Upon Zn²⁺ binding with the receptor, the fluorescence band shifted to enhance fluorescence intensity, allowing ratiometric determination of Zn²⁺ concentration.     

Development of an oxidative dehydrogenation-based fluorescent probe for Cu and its biological imaging in living cells

Based on a boron dipyrromethene (BODIPY) derivative containing an N, O and S tridentate ligand, a Cu²⁺ fluorescent probe BTCu was developed. The detection mechanism was verified as Cu²⁺-promoted oxidative dehydrogenation of an amine moiety, leading to a formation of a fluorescent Cu⁺-Schiff base complex. Free BTCu exhibited a maximum absorption wavelength at 496 nm, and a very weak maximum emission at 511 nm. Upon addition of various metals ions, it showed large fluorescence enhancement toward Cu²⁺ (417-fold in MeCN and 103-fold in MeCN/HEPES solution, respectively) with high selectivity. The detection limits are as low as 1.74 × 10⁻⁸ M and 4.96 × 10⁻⁸ M in the two different solutions, respectively. And BTCu could work in a wide pH range with an extraordinary low pK_a of 1.21 ± 0.06. Using fluorescence microscopy, the probe was shown to be capable of penetrating into living cells and imaging intracellular Cu²⁺ changes.     

Synthesis of a new ratiometric emission Ca2+ indicator for in vivo bioimaging

A novel fluorescent calcium indicator with a 490/582 nm ratiometric emission has been designed and synthesized.The indicator exhibits a highly selective ratiometric emission response to Ca²⁺ over other metal cations and a large Stokes shift of 202 nm.Moreover,its practical cell imaging capability for intracellular Ca²⁺ in the resting- and dynamic-state has been demonstrated in human umbilical vein endothelial cells using a confocal laser scanning microscope.