Selective determination of cysteines through precolumn double-labeling and liquid chromatography followed by detection of intramolecular FRET.

In this paper we introduce a novel approach for highly selective and sensitive analysis of cysteines (glutathione, cysteine, and homocysteine). This method is based on the detection of intramolecular fluorescence resonance energy transfer (FRET) in a liquid chromatography (LC) system after double-labeling of the amino and sulfhydryl groups of the cysteines. In this detection process, we monitored the FRET between the amine-derivatized and thiol-derivatized fluorophores. We screened 16 combinations of fluorescent reagents. As a result, FRET occurred most effectively when the sulfhydryl and amino groups of the cysteines were derivatized with 7-diethylamino-3-[{4'-(iodoacetyl)amino}phenyl]-4-methylcoumarin (DCIA, Ex/Em 390/480 nm) and 4-fluoro-7-nitrobenz-2-oxo-1,3-diazole (NBD-F, Ex/Em 480/540 nm), respectively, in this order. The double-labeled cysteines emitted NBD-F fluorescence (540 nm) through an intramolecular FRET process when they were excited at the wavelength of maximum excitation of DCIA (390 nm). The generation of FRET was confirmed by comparison with analysis of n-amylamine or tryptophan (amines without a sulfhydryl group) and 6-mercaptohexanol (thiol without an amino group) performed using LC and a three-dimensional fluorescence detection system. We were able to separate the double-labeled cysteines (DCIA and NBD-F) when performing LC on an ODS column with isocratic elution. The limits of quantification (signal-to-noise ratio = 10) and detection (signal-to-noise ratio = 3) for the cysteines, for a 20-µL injection volume, were in the range 150-670 fmol and 46-200 fmol, respectively. The sensitivity of the intramolecular FRET-forming derivatization method is higher than that of a system which takes advantage of conventional detection of the derivatives. Furthermore, this method provides sufficient selectivity and sensitivity to determine the total cysteines present in the plasma of healthy humans.

Liquid chromatography method for detecting native fluorescent bioamines in urine using post-column derivatization and intramolecular FRET detection.

Liquid chromatography (LC) with fluorescence detection is described for simultaneous determination of native fluorescent bioamines (indoleamines and catecholamines). This is based on intramolecular fluorescence resonance energy transfer (FRET) in an LC system following post-column derivatization of native fluorescent bioamines' amino groups with o-phthalaldehyde (OPA). OPA fluorescence was achieved through an intramolecular FRET process when the molecules were excited at maximum excitation wavelength of the native fluorescent bioamines. Bioamines separated by reversed-phase LC on ODS column were derivatized with OPA and 2-mercaptoethanol. This method provides sufficient selectivity and sensitivity for the determination of normetanephrine, dopamine, tyrosine, 5-hydroxytryptamine, tryptamine, and tryptophan in healthy human urine without prior sample purification.

Selective determination of tryptophan-containing peptides through precolumn derivatization and liquid chromatography using intramolecular fluorescence resonance energy transfer detection.

A selective and sensitive fluorometric determination method for native fluorescent peptides has been developed. This method is based on intramolecular fluorescence resonance energy transfer (FRET) detection in a liquid chromatography (LC) system following precolumn derivatization of the amino groups of tryptophan (Trp)-containing peptides. In this detection process, we monitored the FRET from the native fluorescent Trp moieties (donor) to the derivatized fluorophore (acceptor). From a screening study involving 10 fluorescent reagents, we found that o-phthalaldehyde (OPA) generated FRET most effectively. The OPA derivatives of the native fluorescent peptides emitted OPA fluorescence (445 nm) through an intramolecular FRET process when they were excited at the excitation maximum wavelength of the Trp-containing peptides (280 nm). The generation of FRET was confirmed through comparison with the analysis of a non-fluorescent peptide (C-reactive protein fragment (77 - 82)) performed using LC and a three-dimensional fluorescence detection system. We were able to separate the OPA derivatives of the Trp-containing peptides when performing LC on a reversed-phase column. The detection limits (signal-to-noise ratio = 3) for the Trp-containing peptides, at a 20-microL injection volume, were 41 - 180 fmol. The sensitivity of the intramolecular FRET-forming derivatization method is higher than that of the system that takes advantage of the conventional detection of OPA derivatives. Moreover, native non-fluorescent amines and peptides in the sample monitored at FRET detection are weaker than those of conventional fluorescence detection.

Determination of catecholamines and indoleamines in human urine based on intramolecular excimer-forming derivatization and fluorescence detection.

A liquid chromatographic (LC) determination of catecholamines and indoleamines is described. This is based on intramolecular excimer-forming fluorescence derivatization with 4-(1-pyrene)butanoyl chloride, followed by reversed-phase LC. The analytes, containing an amino moiety and phenolic hydroxyl moieties in a molecule, were converted to the corresponding polypyrene-labeled derivatives by one-step derivatization. They afforded intramolecular excimer fluorescence, which can clearly be discriminated from the normal fluorescence emitted from reagent blanks. The detection limits (S/N = 3) for catecholamines and indoleamines were femto-mole levels per 20-microL injection. Furthermore, this method was applied to a urine assay.

A simple liquid chromatographic method based on intramolecular excimer-forming derivatization and fluorescence detection for the determination of tyrosine and tyramine in urine.

A liquid chromatographic (LC) method for sensitive and selective fluorometric determination of p-hydroxyphenylethylamino group containing compounds is described. This method is based on an intramolecular excimer-forming fluorescence derivatization with a pyrene reagent, 4-(1-pyrene)butanoyl chloride, followed by reversed-phase LC. The analytes, containing an amino moiety and a phenolic hydroxyl moiety in a molecule, were converted to the corresponding dipyrene-labeled derivatives by one-step derivatization. The dipyrene-labeled derivatives afforded intramolecular excimer fluorescence (440-540 nm), which can clearly be discriminated from the normal fluorescence (360-420 nm) emitted from reagent blanks. The derivatives of tyrosine and tyramine could be separated by reversed-phase LC on ODS column under conditions of isocratic elution. The detection limits (signal-to-noise ratio = 3) for tyrosine and tyramine were 4.5 and 2.6 fmol per 20 microL injection, which corresponded to analyte concentrations of 0.9 and 0.5 nM, respectively.

Fluorous derivatization and fluorous-phase separation for fluorometric determination of naproxen and felbinac in human plasma.

Fluorous derivatization followed by fluorous-phase liquid chromatographic (LC) separation exploits the affinity between perfluoroalkyl compounds for highly selective and quantitative isolation of various analytes. However, the applicability of this technique as a simple pretreatment for fluorometric determination in clinical settings has not been fully explored. Here we show the applicability of this technique to the clinical determination of non-steroidal anti-inflammatory drugs (NSAIDs) in human plasma. Naproxen and felbinac, widely used native-fluorescent NSAIDs with a carboxyl group, can have toxic effects at acute doses, and were therefore chosen as representative NSAIDs. Samples were precolumn derivatized with a non-fluorescent fluorous amine, which allowed highly selective retention of only derivatized substances in the fluorous LC column. Thus, subsequently, only the retained fluorous-labeled and fluorescent analytes were detected fluorometrically at appropriate retention times. The detection limits for these two drugs were less than 11fmol on column. Correlation curves were liner over the range of 0.04-10 and 5-250nmol/mL plasma for both two drugs (r>0.999) with good repeatability. Thus, this method offers a simple, sensitive, and selective solution for determination of NSAIDs in clinical settings.

Selective determination of native fluorescent bioamines through precolumn derivatization and liquid chromatography using intramolecular fluorescence resonance energy transfer detection.

In this paper, we introduce a novel approach for the highly selective and sensitive analysis of native fluorescent bioamines (indoleamines and catecholamines). This method is based on intramolecular fluorescence resonance energy transfer (FRET) detection in a liquid chromatography (LC) system following precolumn derivatization of the bioamines' amino groups. In this detection process, we monitored the FRET from the native fluorescent moieties (donor) to the derivatized fluorophore (acceptor). From a screening study involving 15 fluorescent reagents, we found that o-phthalaldehyde (OPA) generated the FRET most effectively. The OPA derivatives of the native fluorescent bioamines emitted OPA fluorescence (445 nm) through an intermolecular FRET process when they were excited at the excitation maximum wavelengths of the native fluorescent bioamines (280 nm). The generation of FRET was confirmed through comparison with the analysis of a nonfluorescent amine (isoleucine) performed using LC and a three-dimensional fluorescence detection system. We were able to separate the OPA derivatives of the indoleamines and catecholamines when performing LC on an ODS column. The detection limits (signal-to-noise ratio, 3) for the indoleamines and catecholamines, at a 20-muL injection volume, were 17-120 and 28-200 fmol, respectively. The sensitivity of the intramolecular FRET-forming derivatization method is higher than those of systems that take advantage of both native fluorescence detection (i.e., without derivatization) and the conventional detection of OPA derivatives. Furthermore, this method provides enough selectivity and sensitivity for the determination of the indoleamines present in the urine of healthy humans.