Larry G. Rushing

Confirmation of malachite green, gentian violet and their leuco analogs in catfish and trout tissue by high-performance liquid chromatography utilizing electrochemistry with ultraviolet-visible diode array detection and fluorescence detection

A sensitive analytical procedure for the confirmation of residues of malachite green (MG), gentian violet (GV) and their leuco analogs (LMG and LGV) in catfish and trout tissue at 10 ng/g is described. Frozen (-20 degrees C) fish fillets were cut into small pieces and homogenized in Waring blendors. The compounds of interest were extracted from 20-g amounts of homogenized fish tissue with acetonitrile-buffer, partitioned against methylene chloride, and isolated with tandem neutral alumina and propylsulfonic acid cation-exchange solid-phase extraction cartridges. Samples of 100 microl (0.8 g equiv.) were chromatographed isocratically in 10 min using an acetonitrile-buffer mobile phase on a short-chain deactivated (SCD) reversed-phase column (150x4.6 mm I.D.) in-line with a post-column oxidation coulometric electrochemical cell (EC), a UV-Vis diode array detector and a fluorescence detector.

Simultaneous determination of malachite green, gentian violet and their leuco metabolites in catfish or trout tissue by high-performance liquid chromatography with visible detection

A sensitive analytical procedure for the determination of residues of leucomalachite green (LMG)-malachite green (MG) and leucogentian violet (LGV)-gentian violet (GV) in catfish or trout tissue is presented. Frozen (-20 degrees C) fish fillets were cut into small pieces and blended in a Waring blender. A 20-g amount of homogenized fish tissue was extracted with acetonitrile-buffer, partitioned against methylene chloride, and cleaned up on tandem neutral alumina and propylsulfonic acid cation-exchange solid-phase extraction cartridges. Samples of 100 microliters (0.8 g equiv.) were chromatographed isocratically in 10 min using an acetonitrile-buffer mobile phase on a short-chain deactivated (SCD) reversed-phase column (250 x 4.6 mm I.D.) in-line with a post-column PbO2 oxidation reactor. The PbO2 post-column reactor efficiently oxidized LMG to the chromatic MG, and LGV to the chromatic GV permitting visible detection at 588 nm for all four compounds. Linearity was demonstrated with standards over the range of 0.5-50 ng per injection. Recoveries of LMG, MG, LGV and GV from catfish tissues fortified at 10 ng/g were 75.4 +/- 3.0, 61.3 +/- 4.1, 72.6 +/- 3.7 and 87.9 +/- 2.5, respectively, while trout tissues fortified at 10 ng/g yielded recoveries of 82.6 +/- 2.3, 48.6 +/- 1.8, 72.1 +/- 2.1 and 83.8 +/- 4.6 (mean +/- S.D., n = 4), respectively.

Persistence of gentian violet and leucogentian violet in channel catfish (ictalurus punctatus) muscle after water-borne exposure

Gentian violet is a triphenylmethane dye that is an antifungal/antiparastic agent. GV is similar to malachite green that has been used in the aquaculture industry for treatment or prevention of external fungal and parasitic infections in fish and fish eggs although it (MG) is not approved for this use. For these reasons, GVs potential for misuse by the aquaculture industry is high. The uptake and depletion of gentian violet (GV) were determined in channel catfish (Ictalurus punctatus) after water-borne exposure (100 ng ml(-1), 1 h) under simulated aquaculture farming conditions. Leucogentian violet (LGV) was rapidly formed, concentrated in the muscle tissue, and very slowly eliminated from muscle tissue. An isocratic (60% acetonitrile-40% water; 0.05 M ammonium acetate buffer, pH 4.5) HPLC system consisting of a 5 microm LC-CN 250x4.6 mm I.D. column, a 20x2.0 mm I.D. PbO2 oxidative post-column, and a UV-VIS detector set at 588 nm were used to determine uptake and depletion of tissue residues of GV and LGV with time. GV was rapidly depleted and converted to its major metabolite, LGV, which was detected out to 79 days. Therefore, LGV is the appropriate target analyte for monitoring exposure of channel catfish to GV.

Determination of D-fenfluramine, D-norfenfluramine and fluoxetine in plasma, brain tissue and brain microdialysate using high-performance liquid chromatography after precolumn derivatization with dansyl chloride

A HPLC method is described for the simultaneous determination of D-fenfluramine (FEN), D-norfenfluramine (NF) and fluoxetine (FLX) using fluorometric detection after precolumn derivatization with dansyl-chloride. The method has limits of quantitation of 200 fmol for FEN and NF, 500 fmol for FLX in brain microdialysate, and 1 pmol for NF and FEN, and 2 pmol for FLX in plasma. Brain tissue standards were linear between 5 and 200 pmol/mg for all three compounds. The inter-assay variability (relative standard deviation) was 6.6%, 6.9% and 9.3% for FEN, 4.6%, 3.7% and 7.9% for NF and 10.4%, 4.9% and 12.2% for FLX, for brain microdialysate (2 pmol/microl), plasma (2 pmol/ microl) and brain tissue (50 pmol/mg), respectively. Intra-assay variability was always lower, typically several times lower than inter-assay variability. Extraction recovery was 108% and 48% for FEN, 105% and 78% for NF and 94% and 45% for FLX, in plasma (2 pmol/microl) and brain tissue (5 pmol/mg), respectively. Due to the stability of the dansyl-chloride derivatives this method is well suited for an autoinjector after manual derivatization with dansyl chloride at room temperature for 4 h.

Determination of lincomycin residues in salmon tissues by gas chromatography with nitrogen-phosphorus detection

A sensitive method for the determination of lincomycin residues in fish tissues is described. Lincomycin was extracted from fish tissues with phosphate buffer (pH 4.5). The extract was concentrated with a C18 solid-phase extraction cartridge and further cleaned up by solvent extraction. Lincomycin was derivatized with N,O-bis(trimethylsilyl)trifluoroacetamide to form a trimethylsilyl derivative before being analyzed by gas chromatography with nitrogen-phosphorus detection. Coumaphos was used as the internal standard. Assays showed good linearity in the range 25-250 ppb (ng/g) (r = 0.9994). Recoveries of fortified lincomycin at 50, 100 and 200 ppb were > 80% with relative standard deviations < 6%. The limit of detection of the method was 1.7 ppb and the limit of quantitation was 3.8 ppb.

Confirmation of Gentian Violet and its Metabolite Leucogentian Violet in Catfish Muscle Using Liquid Chromatography Combined with Atmospheric Pressure Ionization Mass Spectrometry

Gentian violet (GV) is a triphenylmethane dye antiseptic with potential for illegal use in livestock production, especially aquaculture where the related malachite green has been widely used. This potential misuse has regulatory importance because of the observed rodent carcinogenicity of GV. This report describes the use of online LC-APCI/MS for confirmation of incurred GV residues, and those of its principal metabolite, LGV, in catfish muscle following treatment of live catfish with GV under putative use conditions. LC with APCI/MS detection provided sensitive analysis of GV and LGV with estimated detection limits of < 1 pg observed for both compounds. Fragmentation of GV and LGV via in-source CID was effected by varying the sampling cone-skimmer voltage. Ion intensity data were collected using a rapid cone voltage switching procedure that permits selected ion acquisition under optimal conditions for the parent molecule and several selected fragment ions. For GV, four ions including the ionized molecule were used and for LGV, six ions including the protonated molecule were used. The levels of GV and LGV in muscle from fish dosed with 10 micrograms/l in aquarium water were determined by LC/VIS to be 0.5 and 44 ppb, respectively. Analysis of these samples yielded ion intensity ratios that agreed precisely between injections (< 5%) and accurately with those generated by a comparable amount of authentic GV and LGV (< 10% deviation). These results show the utility of on-line LC-APCI/MS to do both sensitive confirmatory analyses of incurred drug residues for use in monitoring the food supply.

Determination of leucogentian violet and gentian violet in catfish tissue by high-performance liquid chromatography with visible detection

A sensitive analytical procedure for the determination of residues of leucogentian violet (LGV) and gentian violet (GV) in catfish tissue is presented. Frozen (-20 degrees C) catfish fillets were cut into chunks and then blended in a Waring blender. A 10-g amount of catfish muscle tissue was homogenized and extracted with acetonitrile-buffer, partitioned against methylene chloride, and cleaned up on tandem neutral alumina and propylsulfonic acid cation-exchange solid-phase extraction cartridges. Samples of 100 microliters (0.5 g equiv.) were chromatographed isocratically in 15 min using an acetonitrile-buffer mobile phase on a cyano phase column in-line with a post-column PbO2 oxidation reactor. The PbO2 post-column reactor efficiently oxidized the LGV to the chromatic GV permitting visible detection at 588 nm for both LGV and GV. Linearity was demonstrated with standards over the range 0.5-50 ng per injection. Recoveries of LGV and GV from catfish tissues fortified at 20, 10, and 1 ng/g were 83.1 +/- 1.2, 78.4 +/- 4.0, 84 +/- 8 and 92.7 +/- 1.8, 95.0 +/- 2.2, 93 +/- 2 (mean +/- S.D., n = 4), respectively.

Rapid phenotypic characterization of Vibrio isolates by pyrolysis metastable atom bombardment mass spectrometry.

Pyrolysis mass spectrometry was investigated for rapid characterization of food-borne bacterial pathogens. Nine isolates of Vibrio parahaemolyticus and one isolate each of Vibrio fluvialis, Vibrio hollisae, and Vibrio vulnificus were analyzed. Pyrolysis mass spectra, generated via an alternative ionization method, metastable atom bombardment, were subject to principal component-discriminant analysis. The spectral patterns were used to distinguish Vibrio isolates differing in species, serotype and expression of the thermostable direct hemolysin gene. The patterns of similarity and dissimilarity amongst spectra in the Vibrio test set generally reflected those associated with species, serotype or hemolysin-producing genes, though the combined influence of these and other variables in the multi-dimensional data did not produce a simple clustering with respect to any one of these characteristics. These results suggested that with enough examples to model the most common combinations, the method should be able to characterize Vibrio isolates according to their phenotypic characteristics. Pyrolysis-mass spectrometry with metastable atom bombardment and pattern recognition appeared suitable for rapid infraspecific comparison of Vibrio isolates. This integrated analytical, pattern-recognition system should be examined further for potential utility in clinical and public health diagnostic contexts.

Trace analysis of 3,3'-dichlorobenzidine in animal chow, wastewater and human urine by three gas chromatographic procedures.

Gas chromatographic methods are described for the trace analysis of 3,3′-dichlorobenzidine and its dihydrochloride salt in animal chow, wastewater, and human urine. Salient elements of the method for these known carcinogens in chow are: Extraction of the residues as the free amine and a cleanupvia acid-base liquid-liquid partitioning with benzene followed by a silica gel column. With wastewater and human urine, residues are adsorbed by percolating the sample through a column of XAD-2, eluted with acetone, and cleaned up with acid-base partitioning and a silica gel column. Residues are assayed by gas chromatography (GC) either as the free amine or after conversion to the pentafluoropropionyl (PFP) derivative by using an electron capture (EC) or a rubidium-sensitized thermionic-type (N/P) detector. Minimum detectable residues in chow, wastewater, and human urine are about 3 ppb, 18 ppt and 60 ppt, respectively, as determined by EC-GC of the PFP derivative.

Formation of artifactual metabolites of doxylamine following acid hydrolysis

This study describes the use of gas chromatographic-mass spectrometric, high-performance liquid chromatographic and capillary column gas chromatographic separation techniques in demonstrating the production of several artifactual compounds reported in the literature as metabolites of doxylamine. Rhesus monkey urinary extracts which contained doxylamine and doxylamine metabolites were examined with and without acid hydrolysis. The production of 1-phenyl-1-(2-pyridinyl)ethanol and 1-phenyl-1-(2-pyridinyl)ethylene under acid hydrolysis conditions was demonstrated. These artifactual products were shown to originate from the acid hydrolysis of 2-[1-phenyl-1-(2-pyridinyl)ethoxy] acetic acid and not from doxylamine.