Determination of sulfadimethoxine in the liver and kidneys of swine and cattle by gas chromatogarphy--chemical ionization mass spectrometry and stable isotope dilution

Liquid Secondary Ion Mass Spectrometry and Collision-induced Dissociation Mass Spectrometry of Sulfonamide Derivatives of meso-Tetraphenylporphyrin

Liquid secondary ion mass spectrometry (LSIMS) and collision-induced dissociation (CID) were used for the characterization of sulfonamide derivatives of meso-tetraphenylporphyrin (TPP). The spectra obtained using LSIMS show abundant molecular ions and fragment ions from losses of the sulfonamide moieties. The main fragmentation observed in the LSI mass spectra and in the CID spectra of the protonated or cationized molecules involves the loss of one sulfonamide group. In addition, in the CID spectra of these compounds the fragment ions formed by the elimination of two, three and/or four sulfonamide groups are also observed. The CID spectra of the protonated or cationized molecules of these derivatives do not display the ions formed by the cleavage of the S - N bond which have been reported for other sulfonamide compounds. The LSI mass spectra and CID spectra of sulfonamide derivatives of meso-tetraphenylporphyrin provide an easy and reliable means of identification of the number and nature of sulfonamide groups in the porphyrinic ring.

Simultaneous determination of ochratoxin A and cyclopiazonic, mycophenolic, and tenuazonic acids in cornflakes by solid-phase microextraction coupled to high-performance liquid chromatography

A solid-phase microextraction (SPME) method, coupled to liquid chromatography with diode array UV detection (LC-UV/DAD), for the simultaneous determination of cyclopiazonic acid, mycophenolic acid, tenuazonic acid, and ochratoxin A is described. Chromatographic separation was achieved on a propylamino-bonded silica gel stationary phase using acetonitrile/methanol/ammonium acetate buffer mixture (78:2:20, v/v/v) as mobile phase. SPME adsorption and desorption conditions were optimized using a silica fiber coated with a 60 microm thick polydimethylsiloxane/divinylbenzene film. Estimated limits of detection and limits of quantitation ranged from 3 to 12 ng/mL and from 7 to 29 ng/mL, respectively. The method has been applied to cornflake samples. Samples were subjected to a preliminary short sonication in MeOH/2% KHCO(3) (70:30, v/v); the mixture was evaporated to near dryness and reconstituted in 1.5 mL of 5 mM phosphate buffer (pH 3) for SPME followed by LC-UV/DAD. The overall procedure had recoveries (evaluated on samples spiked at 200 ng/g level) ranging from 74 +/- 4 to 103 +/- 9%. Samples naturally contaminated with cyclopiazonic and tenuazonic acids were found; estimated concentrations were 72 +/- 9 and 25 +/- 6 ng/g, respectively.

Fragmentation pathways of sulphonamides under electrospray tandem mass spectrometric conditions

Sulphonamides are antibacterial compounds used extensively in farming and veterinary practice. Residues are commonly found in meat and milk. The growing concern about antibiotic resistance of bacteria led to a lowering of the legal concentration limits of sulphonamides in food. A range of analytical methods, employing tandem mass spectrometry (MS/MS) and selected reaction monitoring (SRM), have been developed to allow screening at the limit of detection (LOD) levels. Interest was drawn to the fragment ions produced by the sulphonamides, some involving complex rearrangements that have not previously been looked at. Here we report an investigation into the fragmentation pattern of sulphonamides under electrospray (ES) MS/MS conditions using ion trap and Fourier transform ion cyclotron resonance (FTICR) mass spectrometers. Structures are proposed for the main fragment ions observed for a range of sulphonamides, the effects of the functional groups in the dissociation pathway of the compounds are investigated, and the mechanisms leading to the main fragment ions are explored.

Approaches towards the automated interpretation and prediction of electrospray tandem mass spectra of non-peptidic combinatorial compounds

Combinatorial chemistry is widely used within the pharmaceutical industry as a means of rapid identification of potential drugs. With the growth of combinatorial libraries, mass spectrometry (MS) became the key analytical technique because of its speed of analysis, sensitivity, accuracy and ability to be coupled with other analytical techniques. In the majority of cases, electrospray mass spectrometry (ES-MS) has become the default ionisation technique. However, due to the absence of fragment ions in the resulting spectra, tandem mass spectrometry (MS/MS) is required to provide structural information for the identification of an unknown analyte. This work discusses the first steps of an investigation into the fragmentation pathways taking place in electrospray tandem mass spectrometry. The ultimate goal for this project is to set general fragmentation rules for non-peptidic, pharmaceutical, combinatorial compounds. As an aid, an artificial intelligence (AI) software package is used to facilitate interpretation of the spectra. This initial study has focused on determining the fragmentation rules for some classes of compound types that fit the remit as outlined above. Based on studies carried out on several combinatorial libraries of these compounds, it was established that different classes of drug molecules follow unique fragmentation pathways. In addition to these general observations, the specific ionisation processes and the fragmentation pathways involved in the electrospray mass spectra of these systems were explored. The ultimate goal will be to incorporate our findings into the computer program and allow identification of an unknown, non-peptidic compound following insertion of its ES-MS/MS spectrum into the AI package. The work herein demonstrates the potential benefit of such an approach in addressing the issue of high-throughput, automated MS/MS data interpretation.

HPLC/atmospheric pressure chemical ionization-mass spectroscopy of eight regulated sulfonamides

Reversed phase high performance liquid chromatography coupled with on-line atmospheric pressure chemical ionization mass spectrometry, HPLC,APCI-MS, has been applied to a mixture of eight sulfonamides. In full scan mode, extracted ion chromatograms produced minimum detectable quantities (MDQ) of 0.8 ng on column, for six of the eight regulated sulfonamides investigated. Selected ion monitoring yielded a 50 pg MDQ for sulfamerazine, sulfadiazine and sulfamethazine, while, the other compounds presented higher values. Analysis of supercritical fluid extracts of chicken liver containing sulfadimethoxine were found to be easily detected by HPLC/APCI-MS. In extracts of chicken liver spiked with 25 microg/kg(-1) (25 ppb) of sulfadimethoxine this compound could be detected in selected ion mode, while 100 pg/microl(-1) was detectable in either full scan or single ion modes. The analysis method for extracted sulfadimethoxine also demonstrated good linearity and reproducibility in both single ion and scan mode.

Determination of sulfonamide antibiotics by gas chromatography coupled with atomic emission detection

The paper describes the analysis of nine sulfonamides, chosen as the most widely used representatives of an important class of antibacterial drugs. Atomic emission detection has been found to allow simultaneous quantification and identification of the N1-methylated derivatives, which are resolved efficiently by conventional capillary gas chromatography. Results are given concerning the linearity of the response and the characterization of the individual compounds by the elemental ratio of their carbon, nitrogen and sulfur content. The method looks promising for the quantitative analysis and confirmation of sulfonamide residues in complex mixtures.

Methods for the determination of sulphonamides in meat

Sulphonamides, due to their important antibacterial effects, are widely used in veterinary practice and animal husbandry. Residues arising from administration without observing withdrawal time sufficiently are normally the parent compounds and the N4-acetyl derivatives, the latter being hydrolyzed to the parent compounds only during extraction under acidic conditions. It is therefore quite conceivable that many authors concentrate on determining these metabolites. In the past decade, we have witnessed a considerable increase in new analytical techniques dealing with the determination of sulphonamides. Among these procedures, especially the so-called multimethods using high-performance liquid chromatography--though sometimes including toilsome clean-up steps--can be mentioned. However, current approaches also utilize gas chromatography, gas chromatography-mass spectrometry, liquid chromatography-mass spectrometry, supercritical fluid chromatography-mass spectrometry, thin-layer chromatography and immunological methods. For most of these techniques, a strong trend towards lowering the level of detectability (down to the sub-ppb range) and improving accuracy and reproducibility can be established.

Determination of small drug molecules by capillary electrophoresis-atmospheric pressure ionization mass spectrometry

Capillary electrophoresis (CE) separations are reported for sulfonamides and benzodiazepines in an uncoated fused-silica capillary. The capillary column exit was connected to a liquid junction-ion spray interface combination coupled to an atmospheric pressure ionization (API) triple quadrupole mass spectrometric (MS) system. On-line UV detection occurred 20 cm from the inlet of the capillary and with the API mass spectrometer (CE-API-MS) after the entire length of the capillary (100 cm). The separations were made using volatile buffers composed of ammonium acetate (15-20 mM) with 15-20% of methanol to facilitate ionization under electrospray conditions. This study showed that the major metabolite of flurazepam in man, N-1-hydroxyethylflurazepam, could be detected and characterized in human urine by CE-UV-MS following the administration of a single oral dose of 30 mg of flurazepam dihydrochloride. The presence of additional flurazepam metabolites in human urine was observed by using the system, suggesting that a combination of UV with MS detection should be useful for metabolic studies. In addition to molecular weight determination of compounds, structural information may be obtained by utilizing online tandem mass spectrometry (CE-UV-MS-MS). This was demonstrated for sulfamethazine where the protonated molecule species was transmitted into the collision cell of the tandem triple quadrupole mass spectrometer. Collision-induced dissociation of the protonated sulfamethazine molecule yielded structural information characteristic of the sulfa drug following the on-column injection of 2 pmol of sulfamethazine.

Determination of sulfonamides by liquid chromatography, ultraviolet diode array detection and ion-spray tandem mass spectrometry with application to cultured salmon flesh

Ion-spray mass spectrometry was investigated for the analysis of 21 antibacterial sulfonamide drugs. All of the sulfonamides analyzed gave positive ion mass spectra with abundant protonated molecules and no fragmentation. Tandem mass spectrometry (MS-MS) using collision-induced dissociation provided structural information, allowing the identification of common fragmentation pathways and the differentiation of isomeric and isobaric sulfonamides. A reversed-phase high-performance liquid chromatographic method was developed, using gradient elution and ultraviolet diode-array detection (DAD), enabling the separation of 16 of the sulfonamides. Combined liquid chromatography (LC)-MS was accomplished using the ion-spray interface. Analyses of a mixture of sulfonamide standards were performed with gradient elution and the mass spectrometer configured for full-scan acquisition, selected-ion monitoring, or selected-reaction monitoring. Procedures for the analysis of sulfadimethoxine (SDM), a representative sulfonamide used in the aquaculture industry, are described. The presence of SDM in cultured salmon flesh was confirmed at levels as low as 25 ng/g by a combination of LC-DAD and LC-MS-MS.

Screening, confirmation, and quantification of sulphonamide residues in pig kidney by tandem mass spectrometry of crude extracts

Collisionally activated dissociation mass spectra, observed with a hybrid tandem instrument, of the chemical ionization protonated molecular ions of sulphonamide drugs have been used as the basis of a rapid screening procedure for these drugs in crude extracts of pig's kidney by scanning to detect the parents of a characteristic daughter fragment. Extracts were introduced without chromatography by a moving belt interface. Detection limits of 0.1 mg/kg were achieved. Confirmation was made by obtaining daughter ion spectra of the protonated molecular ions. Multiple reaction monitoring with a stable isotope analogue as internal standard permitted the quantification of targeted compounds with high sensitivity and precision.

Extraction and clean-up of contaminants and toxicants from food for mass spectrometric analysis--a literature review

This report presents a review of the literature on the extraction and clean-up procedures used prior to the analysis, by mass spectrometry, of organic contaminants and toxicants in foods and food-related materials. It includes a brief description of the uses of a mass spectrometer and shows how the mode of operation of the machine can influence the amount of clean-up necessary before a sample is presented for analysis. The review covers a variety of contaminants of different compound types in a wide range of foods and not only discusses sample preparation techniques that have been used for contaminant analysis by mass spectrometry but also considers some that could be used. The most commonly used techniques involve solvent extraction followed by a clean-up using liquid-liquid partition or column chromatography or both, although a number of newer methods being evolved are moving towards the ideal of a single-step extraction and clean-up process.

[Chemical analysis of veterinary drugs in food. 1. General methods and gas chromatographic procedures]

A review is presented that in the first section describes current techniques for preparation, extraction and clean up of food samples for the determination of veterinary drug residues by chemical methods. The second section gives an overview of gas chromatographic methods published up to 1983 for the analysis of meat, liver, kidney, egg and milk for residues of antibiotics and chemotherapeutic agents. Discussed are stability of the compounds, derivatization, detection and particular aspects of their metabolism. The structural formula is given for all drugs mentioned. The procedures for determination are summarized in a table, together with the most important analytical parameters.

Derivatization reactions in the gas—liquid chromatographic analysis of drugs in biological fluids

Alkylation, acylation, silylation and other derivatization reactions applied to the gas chromatographic analysis of drugs in biological matrices are reviewed. Reaction conditions are discussed in relation to reaction mechanisms. Detector-oriented labelling of drugs, and derivatization with chiral reagents for the separation of enantiomers are surveyed. Data on the sample clean-up, derivatization and GLC analysis of more than 300 drugs and related compounds are listed.

Micro LC/MS in drug analysis and metabolism studies

LC/MS has become a routine research tool in some laboratories. Although no single approach to LC/MS presently is without limitations, each approach offers encouraging results and prompts continued improvements. The remaining hurdles appear to be the introduction of total LC effluent into the MS, increased sensitivity, and the ability to analyze higher molecular weight, polar molecules. The micro LC/MS results discussed in this paper offer an opportunity for significantly increased sensitivity by allowing total micro LC effluent introduction into the MS. It remains to be seen whether the development of micro LC column and equipment technology will allow practical micro LC/MS. It may someday provide improved separation of drugs, metabolites, and their conjugates from high levels of endogenous materials in reasonable time periods. Currently, the impressive efficiencies demonstrated for micro LC columns involve mixtures containing low molecular weight solutes that are perhaps more amenable to GC analysis. The analyst routinely involved with problem solving must deal with complex mixtures composed of components with large concentration differences. The future of micro LC, and hence micro LC/MS, will depend upon how well the technique helps solve problems. We believe the future is bright for micro LC/MS. The techniques may require some fine tuning of operating procedures, just as with capillary GC/MS, but certainly the potential for increased efficiency and sensitivity is worth the effort. Currently we are testing a new micro LC/MS DLI probe wherein the exit of the micro column is within 1 cm of the MS ion source [82]. The micro LC column is contained within the DLI probe and should offer the lowest dead volume and the least extracolumn effects yet achieved by LC/MS. Initial testing of this new probe is under way, and experimental results will be reported subsequently. The analytical potential of micro LC/MS is receiving considerable interest. Practical micro LC performance can provide increased capabilities to all types of LC/MS reported to date, and perhaps offer new insight into alternative methods of LC/MS not yet reported. We look forward to learning of these breakthroughs as they become available.