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Fluorescent fluorescein fluorescence

I. Fluorescein test. Fuse together carefully in a dry test-tube for about 1 minute a few crystals of resorcinol and an equal quantity of succinic acid or a succinate, moistened with 2 drops of cone. H2SO4. Cool, dissolve in water and add NaOH solution in excess. A red solution is produced which exhibits an intense green fluorescence.-f-... [Pg.351]

Fluorescein reaction. Repeat Test i, using however resorcinol instead of phenol. A reddish solution having an intense green fluorescence is produced. [Pg.353]

Fluorescein reaction. Fuse together in a dry test-tube o-i g. of succinimide, O l g. of resorcinol and 2 drops of cone. HjSOi, Cool, add water and then NaOH solution in excess. A green fluorescent solution is obtained. [Pg.363]

EIA was originally developed as a histological technique to localize specific ceUular sites using the specificity of an immunological reaction (23). The resulting fluorescent antibodies can be detected in animal tissues at levels as low as 1 /tg/mL of body fluid. Eluorophore-labeled antibodies have also been used widely for flow cytometry appHcations using fluorescein antibodies to cell surface markers to detect and quantify specific cells (24). [Pg.26]

C is the concentration of limiting reactant in mol/L, c is the chemiluminescence quantum yield in ein/mol, and P is a photopic factor that is determined by the sensitivity of the human eye to the spectral distribution of the light. Because the human eye is most responsive to yellow light, where the photopic factor for a yellow fluorescer such as fluorescein can be as high as 0.85, blue or red formulations have inherently lower light capacities. [Pg.273]

Utilization of resonance effects can facilitate unenhanced Raman measurement of surfaces and make the technique more versatile. For instance, a fluorescein derivative and another dye were used as resonantly Raman scattering labels for hydroxyl and carbonyl groups on glassy carbon surfaces. The labels were covalently bonded to the surface, their fluorescence was quenched by the carbon surface, and their resonance Raman spectra could be observed at surface coverages of approximately 1%. These labels enabled assess to changes in surface coverage by C-OH and C=0 with acidic or alkaline pretreatment [4.293]. [Pg.260]

Note The full fluorescence intensity usually only develops about 30 min after the dipping process it then remains stable for several days if the chromatograms are stored in the dark (1, 5]. Fluorescein sodium can be employed in the reagent in place of 2, 7 -dichlorofluorescein [5]. The detection limits lie in the lower nanogram to picogram range [1, 5]. [Pg.326]

Discussion. This method is based upon the formation of a fluorescent chelate between calcium ions and calcein [fluorescein bis(methyliminodiacetic acid)] in alkaline solution.29 The procedure described below30 has been employed for the determination of calcium in biological materials.31 ... [Pg.738]

Fluorescent materials are very important in medical research. Dyes such as fluorescein (21) can be attached to protein molecules, and the protein can be traced in a biological system by exciting the fluorescein and looking for its emissions. The use of a fluorescent material allows the detection of much smaller concentrations than would otherwise be possible. Because fluorescent materials can be activated by radioactivity, they are also used in scintillation counters to measure radiation (see Box 17.2). [Pg.768]

Jablonski (48-49) developed a theory in 1935 in which he presented the now standard Jablonski diagram" of singlet and triplet state energy levels that is used to explain excitation and emission processes in luminescence. He also related the fluorescence lifetimes of the perpendicular and parallel polarization components of emission to the fluorophore emission lifetime and rate of rotation. In the same year, Szymanowski (50) measured apparent lifetimes for the perpendicular and parallel polarization components of fluorescein in viscous solutions with a phase fluorometer. It was shown later by Spencer and Weber (51) that phase shift methods do not give correct values for polarized lifetimes because the theory does not include the dependence on modulation frequency. [Pg.9]

Table I describes several of the fluorescent assays that have been used in our lab to study neutrophil activation. Fluorescein-labeled W-formylhexapeptide (FLPEP) has been used to characterize the ki- netics of ligand binding, dissociation, and internalization at 37°C (7,8). FLPEP is added to a suspension of cells, then receptor-bound and free FLPEP in solution are distinguished by adding antibody to fluorescein. This is a high-affinity antibody which binds free FLPEP within 1 s hut does not bind cell-bound FLPEP. When it binds the FLPEP, it quenches the fluorescein fluorescence. Hence the residual fluorescence after antibody addition represents FLPEP that is bound to the cell. Nonspecific binding is determined in cell suspensions that contain an excess of nonfluorescent peptide. Table I describes several of the fluorescent assays that have been used in our lab to study neutrophil activation. Fluorescein-labeled W-formylhexapeptide (FLPEP) has been used to characterize the ki- netics of ligand binding, dissociation, and internalization at 37°C (7,8). FLPEP is added to a suspension of cells, then receptor-bound and free FLPEP in solution are distinguished by adding antibody to fluorescein. This is a high-affinity antibody which binds free FLPEP within 1 s hut does not bind cell-bound FLPEP. When it binds the FLPEP, it quenches the fluorescein fluorescence. Hence the residual fluorescence after antibody addition represents FLPEP that is bound to the cell. Nonspecific binding is determined in cell suspensions that contain an excess of nonfluorescent peptide.
Complexity of LR Dynamics in Intact Neutrophils at 37°. At present, our most versatile assay to analyze receptor binding uses fluorescent ligand and a high-affinity antibody to fluorescein which discriminates free from receptor-bound hexapeptide ligand (FLPEP, N-formyl-Nle-Leu-Phe-Nle-Tyr-Lys-Fl). The assay has a time resolution of 1... [Pg.56]

Figure 2. The binding and dissociation of FLPEP and receptor on intact neutrophils at 37 C The data are plotted as the specific binding of FLPEP (pmoles/10 cells) on a log plot versus time. Experimental details 10 cells/mL were exposed at time 0 to 1 nAf FLPEP. At 15, 30, 60, or 120 s, antibody to fluorescein is added to each sample. Fluorescence is monitored continuously during the additions. The data ate derived from a point-by-point comparison of the fluorescence measured under conditions of receptor binding and receptor blockade. Data are representative of observations in more than 10 separate experiments. (Reproduced with permission from reference 22. Copyright 19S7 Journal of Biological Chemistry.)... Figure 2. The binding and dissociation of FLPEP and receptor on intact neutrophils at 37 C The data are plotted as the specific binding of FLPEP (pmoles/10 cells) on a log plot versus time. Experimental details 10 cells/mL were exposed at time 0 to 1 nAf FLPEP. At 15, 30, 60, or 120 s, antibody to fluorescein is added to each sample. Fluorescence is monitored continuously during the additions. The data ate derived from a point-by-point comparison of the fluorescence measured under conditions of receptor binding and receptor blockade. Data are representative of observations in more than 10 separate experiments. (Reproduced with permission from reference 22. Copyright 19S7 Journal of Biological Chemistry.)...
Calibration. Many approaches have been used to calibrate flow cytometric measurements. Including the comparison of flow and nonflow techniques (radiolabels, spectrofluorometry). In recent years, commercial standards have been introduced which are calibrated in fluorescein equivalents/particle (e.g., 3,000 or 500,000). With labeled ligands, calibration requires determining the relative quantum yield of the ligand compared to pure fluorescein and using the standards to analyze the amount bound on cells. Our ligands (fluorescein isothiocyanate derivatives) are typically 50% as fluorescent as fluorescein. [Pg.67]

Alcohols (diols, polyols, sugan) Lead(IV) acetate -dichloro fluorescein Diol cleavage of vicinal diols, e. g. sugars, sugar alcohols. The lead tetraacetate consumed is no longer available to decompose the fluorescent dichlorofluorescein. [3, 8]... [Pg.31]


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