A dual-function fluorescent probe for the detection of pH values and formaldehyde

A dual-function fluorescent probe (Probe 1) was developed in this work for the separate detection of pH value and formaldehyde (HCHO). Probe 1 could recognize HCHO and the pH value from the amino group. The colour of the probe solution was changed from grey blue to light blue with the increase in the pH value, and luminous intensity became larger with the increase in formaldehyde concentration. The curve function relationship between fluorescence intensity and the pH value was also determined. A smartphone containing a colour detector for imaging was used to record the values of the three primary colours (R value, G value, and B value) for the probe solution in formaldehyde. Importantly, there was a linear functional relationship between the B*R/G value with HCHO concentration. Therefore, the probe could be used as a rapid tool for the detection of formaldehyde. More importantly, Probe 1 was successfully used to detect formaldehyde in an actual distilled liquor sample.     

Application of a luminous intensity variation fluorescent probe for the detection of ferric ions

A luminous intensity variation fluorescent probe (Probe 1) for the detection of ferric ion was developed. The quantitative range of Fe³⁺ content detected was 0–600 μM with the limit of detection at 0.76 μM. Furthermore, after 20 min of Fe³⁺ addition, the intensity of the luminescence of Probe 1 solution gradually decreased with increase in Fe³⁺ concentration. In addition, the B and G values of these images showed a linear relationship with Fe³⁺ concentration (0–500 μM). Probe 1 was successfully used for the rapid determination of Fe³⁺ concentration in real samples. This study demonstrates that Probe 1 is an excellent tool for the rapid determination of Fe³⁺ content in real samples using a smart phone without professional equipment.     

Determination of organophosphate and carbamate pesticides in spiked samples of tap water and fruit juices by a biosensor with photothermal detection.

The determination of organophosphate (paraoxon, chlorpyrifos, diazinon) and carbamate (carbaryl, carbofuran) pesticides in spiked drinking water and fruit juices was carried out using a photothermal biosensor. The biosensor consists of a cartridge containing immobilised enzyme acetylcholinesterase (AChE) placed in a flow-injection analysis (FIA) manifold and a photothermal detector based on thermal lens spectrometry. With this approach, 0.2 ng/ml of paraoxon can be detected in less than 15 min. Limits of detection for other organophosphate (chlorpyrifos, diazinon) and carbamate (carbaryl, carbofuran) pesticides varied, depending on their antiacetylcholinesterase (AntiAChE) toxicity, from 1 ng/ml to 4 microg/ml. The biosensor was used for the direct detection of pesticides in spiked tap water and fruit juices without any pretreatment steps. In these cases, the LOD3sigma of 1.5, 2.8 and 4 ng/ml paraoxon in tap water, orange juice and apple juice were obtained, respectively.     

Discriminative detection of mercury (II) and hydrazine using a dual‐function fluorescent probe

A dual‐function fluorescent probe (Probe 1 ) was developed for discriminative detection of Hg²⁺ and N₂H₄. Probe 1 could discriminatively detect Hg²⁺ and N₂H₄ through two different reaction sites, with the mechanism for Probe 1 for Hg²⁺ depending on a desulfurization reaction and for N₂H₄ depending on the Schiff‐base reaction. N₂H₄ had minimal effect on Hg²⁺ detection in dimethyl sulfoxide (DMSO)/H₂O solution, but Hg²⁺ could interfere with N₂H₄ detection in DMSO/buffer solution. Different concentrations of Hg²⁺ and N₂H₄ resulted in different blue shades of Probe 1 test strips, and the shade of blue was different with the same concentration of Hg²⁺ or N₂H₄, as observed under ultraviolet light at 365 nm wavelength.     

Methylene blue-based 7-nitro-1,2,3-benzoxadiazole NIR fluorescent probe triggered by H2S

A new Methylene blue–based 7-nitro-1,2,3-benzoxadiazole NIR fluorescent probe 3, 7-bis-dimethylamino-10-(7-nitrobenzo[c][1,2,5]oxadiazol-4-yl)-10H-phenothiazine (leuco-MB-NBD) was designed and synthesized. Leuco-MB-NBD showed high sensitivity and selectivity for H₂S as a fluorescent probe in C₂H₅OH-PBS (9:1, v/v, pH = 7.4) solution, this fluorescent assay showed a linear range of 0–50.0 μM and a LOD (limit of detection) of 0.43 μM. Moreover, the probe leuco-MB-NBD has lower toxicity at low concentrations to HCT-116 cells and can be used for cell imaging. Additionally, Leuco-MB-NBD is triggered by hydrogen sulfide to generate methylene blue, methylene blue which has potential rescuing effects on the mitochondrial activity can act as an antidote against sulfide intoxication.     

Selective sensing Ca2+ with a spiropyran‐based fluorometric probe

Spiropyran (SP) and its derivatives operate between their ring opening and closing forms as a versatile molecular platform for the fluorescence detection of cations and anions, using a colour change for signalling. A functionalized SP fluorescence probe, L , was prepared and characterized. Probe L can detect Ca²⁺ with a fluorescence ‘turn‐on’ response in ethanol solution. It selectively binds Ca²⁺ to form a 1:1 ligand/metal complex, which produced a new emission band centred at 604 nm. The sensing result was clearly observed by the solution colour change from colourless to pink under visible light, and from blue to red under ultraviolet light. The detection limit was calculated to be 4.53 × 10^?8 M for Ca²⁺. The probe provides another possibility that SP‐based derivatives could be used for the development and detection of metal ions in environmental and physiological systems.     

A deep-red xanthene-based highly sensitive fluorescent probe for detection of hypochlorite

As an oxidant, deodorant and bleaching agent, the hypochlorous acid (HClO) and hypochlorite (ClO⁻) are widely used in corrosion inhibitors, textile dyes, pharmaceutical intermediates and in our daily lives. However, excess usage or aberrant accumulation of ClO⁻ leads to tissue damage or some diseases and even cancer. Therefore, it is necessary to develop a fluorescent probe that specifically identifies ClO⁻. In this article, we synthesized a deep-red xanthene-based fluorescent probe (XA-CN). The strong electron deficient group dicyano endows the probe XA-CN deep-red fluorescent emission with high solubility, selectivity and sensitivity for ClO⁻ detection. Studies showed that the probe demonstrated turn-off fluorescence (643 nm) at the presence of ClO⁻ in dimethylsulfoxide/phosphate-buffered saline 1:1 (pH 9) solution with a limit of detection of 1.64 μM. Detection mechanism investigation revealed that the electron deficient group -CN and the hydroxyl group was oxidized into aldehyde or carbonyl groups at the presence of ClO⁻, resulting ultraviolet-visible absorption of the probe blue shifted and turned-off fluorescence. Furthermore, XA-CN was successfully used for the detection of ClO⁻ in tap water samples.     

Fluorescent sensors based on quinoline‐containing styrylcyanine: determination of ferric ions,hydrogen peroxide,and glucose,pH‐sensitive properties and bioimaging

A novel styrylcyanine‐based fluorescent probe 1 was designed and synthesized via facile methods. Ferric ions quenched the fluorescence of probe 1, whereas the addition of ferrous ions led to only small changes in the fluorescence signal. When hydrogen peroxide was introduced into the solution containing probe 1 and Fe²⁺, Fe²⁺ was oxidized to Fe³⁺, resulting in the quenching of the fluorescence. The probe 1/Fe²⁺ solution fluorescence could also be quenched by H₂O₂ released from glucose oxidation by glucose oxidase (GOD), which means that probe 1/Fe²⁺ platform could be used to detect glucose. Probe 1 is fluorescent in basic and neutral media but almost non‐fluorescent in strong acidic environments. Such behaviour enables it to work as a fluorescent pH sensor in both the solution and solid states and as a chemosensor for detecting volatile organic compounds with high acidity and basicity. Subsequently, the fluorescence microscopic images of probe 1 in live cells and in zebrafish were achieved successfully, suggesting that the probe has good cell membrane permeability and a potential application for imaging in living cells and living organisms. Copyright © 2014 John Wiley & Sons, Ltd.     

A ratiometric fluorescent probe for bisulphite anion,employing intramolecular charge transfer

4‐(1H‐benzimidazol‐2‐yl)benzaldehyde (1) has been developed as a new ratiometric fluorescent probe for bisulphite, based on the modulation of intramolecular charge transfer (ICT). Upon mixing with bisulphite in aqueous ethanol, an aldehyde–bisulphite adduct was formed and the ICT of the probe was switched off, which resulted in a ratiometric fluorescence response with an enhancement of the ratios of emission intensities at 368 and 498 nm. The detection range of the probe for bisulphite is in the 2.0–200 µmol/L concentration range and the detection limit is 0.4 µmol/L. Probe 1 produces a ratiometric fluorescent response to bisulphite with a marked emission wavelength shift (130 nm) and displays high selectivity for bisulphite over other anions. Copyright © 2012 John Wiley & Sons, Ltd.     

Synthesis of copper nanoclusters from Bacopa monnieri leaves for fluorescence sensing of dichlorvos

In this work, a facile one-step green synthesis was developed for the fabrication of blue fluorescent copper nanocluster (Brahmi-CuNCs) from the extract of Bacopa monnieri (common name is Brahmi) via a microwave method. The as-prepared Brahmi-CuNCs emitted blue fluorescence at 452 nm when excited at 352 nm and showed a quantum yield of 31.32%. Brahmi-derived blue fluorescent CuNCs acted as a probe for fluorescence sensing of dichlorvos. Upon the addition of dichlorvos, the blue emission for Brahmi-CuNCs was gradually turned off, favouring establishment of a calibration graph in the range 0.5–100 μM with a detection limit of 0.23 μM. The as-synthesized Brahmi-CuNCs exhibited marked sensitivity and selectivity towards dichlorvos, favourable for assaying dichlorvos in various samples (cabbage, apple juice, and rice).     

The design of a novel near-infrared fluorescent HDAC inhibitor and image of tumor cells

Histone deacetylases (HDACs) have been found to be biomarkers of cancers and the corresponding inhibitors have attracted much attention these years. Herein we reported a near-infrared fluorescent HDAC inhibitor based on vorinostat (SAHA) and a NIR fluorophore. This newly designed inhibitor showed similar inhibitory activity to SAHA against three HDAC isoforms (HDAC1, 3, 6). The western blot assay showed significant difference in compared with the negative group. When used as probe for further kinematic imaging, Probe 1 showed enhanced retention in tumor cells and the potential of HDAC inhibitors in drug delivery was firstly brought out. The cytotoxicity assay showed Probe 1 had some anti-proliferation activities with corresponding IC₅₀ values of 9.20 ± 0.96 μM on Hela cells and 5.91 ± 0.57 μM on MDA-MB-231 cells. These results indicated that Probe 1 could be used as a potential NIR fluorescent in the study of HDAC inhibitors and lead compound for the development of visible drugs.     

Application of central composite design for DNA hybridization onto magnetic microparticles

Central composite face-centered (CCF) design and response surface methodologies were used to investigate the effect of probe and target concentration and particle number in immobilization and hybridization on a microparticle-based DNA/DNA hybridization assay. The factors under study were combined according to the CCF design matrix, and the intensity of the hybridization signal was quantified by flow cytometry. A second-order polynomial was fitted to data and validated by analysis of variance. The results showed a complex relationship between variables and response given that all factors as well as some interactions were significant, yet it could explain 95% of the data. Probe and target concentration had the strongest impact on hybridization signal intensity. Increments in initial probe concentration in solution positively affected the hybridization signal until a negative influence of a compact probe layer emerged. This trend was attributed to probe-probe interactions. By manipulating particle number on both immobilization and hybridization, enhancements on the assay sensitivity could be obtained. Under optimized conditions, the limit of detection (LOD) at the 95% confidence level was determined to be 2.3 nM of target solution concentration.     

Fiber optic monitoring of carbamate pesticides using porous glass with covalently bound chlorophenol red

An optical fiber biosensor for the determination of the pesticides propoxur (Baygon®) and carbaryl, two of the most commonly used carbamate insecticides in vegetable crops, is described. A pH indicator, chlorophenol red, is used as optical transducer of the inhibition of the enzyme acetylcholinesterase by the analytes. The biorecognition element is covalently immobilized onto controlled pore glass beads (CPG) and packed in a thermostatized bioreactor connected to a flow-through cell that contains CPG-immobilized chlorophenol red placed at the common end of a bifurcated fiber optic bundle. In the presence of a constant acetylcholine concentration, the colour of the pH sensitive layer changes and the measured reflectance signal can be related to the carbamate concentration in the sample solution. The performance of the biosensor has been optimized using a flow injection system. The linear dynamic range for the determination of carbaryl and propoxur spans from 0.8 to 3.0 mg l⁻¹ and from 0.03 to 0.50 mg l⁻¹, respectively. The detection limit (3 s) of the biosensor for propoxur (0.4 ng) is lower than that measured for carbaryl (25 ng). Reproducibility, stability and interference studies of the optical device are reported. The biosensor has been applied to the determination of propoxur in spiked vegetables (onion and lettuce) using ultrasound extraction, achieving recovery values between 93 and 95% for onion samples at the different concentration levels assayed.     

A highly sensitive and selective fluorescent probe for fluoride anions based on intramolecular charge transfer

Currently, there is a great need to develop methods for the selective detection of fluoride anions (F^–) owing to their toxicity in the environment and biological function in living systems. In this study, we developed a new fluorescent probe (probe 1) employing a Si–O bond as a highly selective recognition receptor for detecting F^– via intramolecular charge transfer. Probe 1 could detect F^– quantitatively using the turn‐on fluorescence spectroscopy method with excellent sensitivity in the range of 4–38 μM and a detection limit of 0.26 μM; the detection time was < 17 min. We anticipate that probe 1 would be used widely to monitor F^– in the environment. Copyright © 2015 John Wiley & Sons, Ltd.     

Insertion of amphiphilic molecules into membranes is catalyzed by a high molecular weight non-ionic surfactant

We have employed an amphiphilic fluorescent probe to elucidate the mechanism by which a class of oxyethylene-oxypropylene copolymers catalyzes the insertion of hydrophobic or amphiphilic molecules into membranes. The rate of binding can be accelerated by over two orders of magnitude in the presence of the catalyst which does not itself disrupt the lipid bilayer. The rate of probe binding to lipid vesicles does not depend on the lipid concentration in the presence or absence of catalyst but is linearly related to the concentration of the catalyst. Probe binding to the polyol surfactant appears to be a component of the catalytic mechanism and equilibrium binding parameters can be determined; these are used to indirectly establish quantitative binding parameters for the probe to the vesicle membrane. The polyol surfactant is also shown to catalyze insertion of the probe into the outer leaflet of a hemispherical lipid bilayer and the plasma membrane of HeLa cells. The latter were also stained by catalyzed transfer of a fluorescent lipid from lipid vesicles. The permeability of the cell membrane is not significantly altered under any of the catalytic conditions. These data, taken together, suggest that the polyol surfactant extracts a monomeric substrate molecule from its aggregate or microcrystal and passes it to the membrane via a loose and transient contact.     

A colorimetric fluorescent probe for rapid and specific detection of nitrite

The method of fluorescent probes has been an important technique for detection of nitrite (NO₂^?). As an important inorganic salt, excessive nitrite would threaten humans and the environment. In this paper, a colorimetric fluorescent probe P‐N (1,2‐diaminoanthraquinone) with rapid response and high selectivity, which could detect NO₂^? by visual colour changes and fluorescence spectroscopy is presented. The probe P‐N solution (pH 1) changed from pink to colourless with the addition of NO₂^? and fluorescence intensity at 639 nm clearly decreased. Good linear exists between fluorescence intensities and NO₂^? concentrations for the range 0–16 μM, and the detection limit was 54 nM (based on a 3σ/slope). Moreover, probe P‐N could also detect NO₂^? in real water samples, and results were all satisfactory. Probe P‐N shows great practical application value for detecting NO₂^? in the environment.     

Rhodol‐based far‐red fluorescent probe for the detection of cysteine and homocysteine over glutathione

The simultaneous discrimination of cysteine (Cys), homocysteine (Hcy) and glutathione (GSH) is of great importance due to their roles in biology and close link to many diseases, especially via the development of a far‐red fluorescent probe that could be used for rapid, selective, and sensitive detection of all three. Herein, we report the characterization of a far‐red fluorescent probe with turn‐on fluorescence properties and visible color changes that could be used for the detection of cysteine and homocysteine over glutathione. In this study we found that the sensor could discriminate cysteine and homocysteine over glutathione within 20 min. Function of this probe was based on the conjugate addition–cyclization reaction and showed a low detection limit to cysteine and homocysteine. Upon the addition of cysteine and homocysteine, the absorption band at 592 nm rose gradually and fluorescence was detected at 645 nm. The color changed from colorless to blue and fluorescence changed from absent to strong red fluorescence, which could be differentiated by the naked eye. All these unique features make this probe particularly potentially favorable for use in cysteine/homocysteine sensing and bioimaging applications. Copyright © 2016 John Wiley & Sons, Ltd.     

Expression of the housefly acetylcholinesterase in a bioreactor and its potential application in the detection of pesticide residues

Acetylcholinesterase is a key enzyme of the animal nerve system. The enzyme is the primary target of organophosphorous (OP) and carbamate (CB) insecticides. The insect AChE is being extensively used in development of new insecticides or in vitro selection of the new designed insecticides, and in pharmacological and toxicological field. Rapid assays using AChE-based methods have been proposed as an efficient and rapid method for the detection of pesticides, especially in many Asian markets. In this study, the acetylcholinesterase gene was cloned from housefly (Musca domestica) susceptible to organophosphate (OP) and carbamate (CB) insecticides, and expressed in baculovirus-insect cells system using a bioreactor with oxygen supplementation. The recombinant housefly AChE was purified using ammonium sulfate precipitation and procainamide affinity chromatography, and approximately 0.42 mg of the purified AChE with high biological activity (118.9 U/mg) was obtained from 100 ml of culture solution. The purified AChE was highly sensitive to OP and CBs insecticides. In conclusion, an efficient expression and purification system has been developed for large-scale production of recombinant housefly AChE. The recombinant enzyme is potential to be used for the detection of pesticide residues.     

Bioconjugation of CdTe quantum dot for the detection of 2,4-dichlorophenoxyacetic acid by competitive fluoroimmunoassay based biosensor

Quantum dots (QD) are semiconductor fluorescent nanoparticles, which can be made use of for environmental monitoring with high sensitivity. In view of the alarming levels of pesticides and herbicides being used in agriculture practices, there is a need for their rapid, sensitive and specific detection in food and environmental samples, as pesticides and herbicides are harmful to living beings even at trace levels. Present study was carried out to develop a reliable and rapid method for analysis and detection of 2,4-D (herbicide) using cadmium telluride quantum dot nanoparticle (CdTe QD). Fluoroimmunoassay based on the fluorescent property of quantum dot was used along with immunoassay to detect 2,4-D. CdTe capped with mercaptopropionic acid, was conjugated using N-(3-dimethylaminopropyl)-N-ethylcarbodiimide hydrochloride (EDC) and a coupling reagent like N-hydroxysuccinimide (NHS) to alkaline phosphatase (ALP) which was in turn conjugated to 2,4-D molecule. Anti 2,4-D-IgG antibodies were immobilized in an immunoreactor column using Sepharose CL-4B as an inert matrix. The detection of 2,4-D was carried out by fluoroimmunoassay-based biosensor using competitive binding between conjugated 2,4-D-ALP-CdTe and free 2,4-D with immobilized anti 2,4-D antibodies in an immunoreactor column. It was possible to detect 2,4-D upto 250pgmL(-1). Present study also emphasizes on the resonance energy transfer between ALP and CdTe QD as a result of bioconjugation, which can be used for future biosensor development based on quantum dot-biomolecular interactions.     

The carbamate reaction of glycylglycine, plasma, and tissue extracts evaluated by a pH stopped flow apparatus.

We have used a stopped flow rapid reaction pH apparatus to investigate the carbamate equilibrium in glycylglycine solutions and in three biological tissues, human plasma, sheep muscle, and sheep brain, as well as to investigate the kinetics of carbamate formation in glyclyglycine solution and in human plasma. The rapid reaction apparatus was equipped with a pH sensitive glass electrode in order to follow the time course of pH from 0.005 to 100 s after rapid mixing of a solution of amine or protein and CO2. Two phases of the pH curve were observed: a fast phase representing carbamate formation, and a slow phase due to the hydration of CO2 which was uncatalyzed since a carbonic anhydrase inhibitor was added to the biological solutions. From the time course of pH change during the fast phase K2, the R-NH2 ionization constant, and Kc, the carbamate equilibrium constant as well as the velocity constant for the formation of carbamate, ka could be calculated from data at different pH and pCO2. The carbamate formed in glycylglycine solutions over a wide range of pH and pCO2 was found consistent with the theory of carbamate formation and with published data. At ionic strength 0.16 and 37 degrees pK is 7.67. pKc 4.58. The heat of the carbamate reaction (deltaH) was calculated to be -3.2 kcal/mol between 20 degrees and 37 degrees. Kt of glycylglycine depends quantitatively on ionic strength as predicted by the Debye-Huckel theory. With ionic strength 0.16 ku was found to be 2,500 M1 S1 at 37 degrees. The activation energy of carbamate formation is 6.7 kcal/mol. Carbamate measurements in human plasma at pCO2 from 38 to 359 Torr. pH from 6.9 to 8.3, temperature 37 degrees, and ionic strength 0.15 provided evidence that two kinds of amino groups participate in carbamate formation. From the equilibrium constants computed for the two species they could be identified as alpha- and epsilon-amino groups. On the basis of a protein molecular weight of 69.000. 0.6 alpha-amino groups/molecule with pKz=7.0 and pKc=4.2, and 5.9 epsilon-amino groups/molecule with pKz=9.0 and pKc=4.3 contribute to carbamate formation. The velocity constant ka was estimated to be 4,950 M1 S1 for the alpha-amino groups and 13,800 M1 S1 for the epsilon-amino groups. Under physiological conditions (pCO2=40 Torr. pH=7.4). The concentration of carbamate in plasma is 0.6 mM and the half-time of carbamate formation is 0.05 s. In extracts prepared from sheep brain at 37 degrees pH=7 and pCO2=35 Torr. the carbamate formation was estimated to be 0.8 mM. With pCO2=70 Torr and the same pH and temperature the carbamate concentration in muscle approximates 0.3 mM and increases to 7 mM as pH rises to 8. It is concluded that, as in plasma, a considerable number of epsilon-amino groups appear to be available for carbamate formation in these tissues.