Liquid Chromatography Post-Column Oxidation (PCOX) Method for the Determination of Paralytic Shellfish Toxins in Mussels, Clams, Oysters, and Scallops: Collaborative Study

Sixteen laboratories participated in a collaborative study to evaluate method performance parameters of a liquid chromatographic method of analysis for paralytic shellfsh toxins (PST) in blue mussels (Mytilus edulis), soft shell clams (Mya arenaria), sea scallops (Placopectin magellanicus), and American oysters (Crassostrea virginicus). The specifc analogs tested included saxitoxin, neosaxitoxin, gonyautoxins-1 to -5, decarbamoyl-gonyautoxins-2 and -3, decarbamoyl-saxitoxin, and N-sulfocarbamoylgonyautoxin-2 and -3. This instrumental technique has been developed as a replacement for the current AOAC biological method (AOAC Offcial MethodSM 959.08) and an alternative to the pre-column oxidation LC method (AOAC Offcial MethodSM 2005.06). The method is based on reversed-phase liquid chromatography with post-column oxidation and fluorescence detection (excitation 330 nm and emission 390 nm). The shellfsh samples used in the study were prepared from the edible tissues of clams, mussels, oysters, and scallops to contain concentrations of PST representative of low, medium, and high toxicities and with varying profles of individual toxins. These concentrations are approximately equivalent to ½ maximum level (ML), ML, or 2×ML established by regulatory authorities (0.40, 0.80, and 1.60 mg STX·diHCl eq/kg, respectively). Recovery for the individual toxins ranged from 104 to 127%, and recovery of total toxin averaged 116%. Horwitz Ratio (HorRat) values for individual toxins in the materials included in the study were generally within the desired range of 0.3 to 2.0. For the estimation of total toxicity in the test materials, the reproducibility relative standard deviation ranged from 4.6 to 20%. A bridging study comparing the results from the study participants using the post-column oxidation (PCOX) method with the results obtained in the study director’s laboratory on the same test materials using the accepted reference method, the mouse bioassay (MBA; AOAC Offcial MethodSM 959.08), showed that the average ratio of results obtained from the two methods was 1.0. A good match of values was also achieved with a new certifed reference material. The results from this study demonstrated that the PCOX method is a suitable method of analysis for PST in shellfsh tissue and provides both an estimate of total toxicity, equivalent to that determined using the MBA AOAC Offcial MethodSM 959.08, and a detailed profle of the individual toxin present in the sample.

Carry-over of pyrrolizidine alkaloids from feed to milk in dairy cows

Pyrrolizidine alkaloids are toxins present in many plants belonging to the families of Asteraceae, Boraginaceae and Fabaceae. Particularly notorious are pyrrolizidine alkaloids present in ragwort species (Senecio), which are held responsible for hepatic disease in horses and cows and may lead to the death of the affected animals. In addition, these compounds may be transferred to edible products of animal origin and as such be a threat for the health of consumers. To investigate the possible transfer of pyrrolizidine alkaloids from contaminated feed to milk, cows were put on a ration for 3 weeks with increasing amounts (50-200 g day(-1)) of dried ragwort. Milk was collected and sampled twice a day; faeces and urine twice a week. For milk, a dose-related appearance of pyrrolizidine alkaloids was found. Jacoline was the major component in milk despite being a minor component in the ragwort material. Practically no N-oxides were observed in milk, notwithstanding the fact that they constituted over 80% of the pyrrolizidine alkaloids in ragwort. The overall carry-over of the pyrrolizidine alkaloids was estimated to be only around 0.1%, but for jacoline 4%. Notwithstanding the low overall carry-over, this may be relevant for consumer health considering the genotoxic and carcinogenic properties demonstrated for some of these compounds. Analysis of the faeces and urine samples indicated that substantial metabolism of pyrrolizidine alkaloids is taking place. The toxicity and potential transfer of metabolites to milk is unknown and remains to be investigated.

Improved microbial screening assay for the detection of quinolone residues in poultry and eggs

An improved microbiological screening assay is reported for the detection of quinolone residues in poultry muscle and eggs. The method was validated using fortified tissue samples and is the first microbial assay to effectively detect enrofloxacin, difloxacin, danofloxacin, as well as flumequine and oxolinic acid, at or below their EU maximum residue limits (MRL). The accuracy of the assay was shown by analysing incurred tissue samples containing residue levels around the MRL. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) quantification of the quinolone concentration in these samples showed that the test plate can be used semi-quantitatively, allowing the definition of an "action level" as an inhibition zone above which a sample can be considered "suspect". The presented assay is a useful improvement or addition to existing screening systems.

The determination of biurea: A novel method to discriminate between nitrofurazone and azodicarbonamide use in food products

Recently doubts have arisen on the usefulness of semicarbazide as marker residue for the illegal use of the antibiotic nitrofurazone (NFZ) in aquaculture and poultry production. Most notably azodicarbonamide (ADC) has been implicated as an alternative source of semicarbazide. ADC is used in some countries as a dough conditioner at concentrations up to 45 mg kg(-1). The use of ADC-treated flour or dough in coated or breaded food products may generate false non-compliant results in the analytical method for nitrofurazone metabolites, which is currently in use. During the dough preparation process ADC is largely reduced to biurea, which can be considered as an appropriate marker residue of ADC. Thus far no methods have been published for the determination of biurea in food commodities. Due to its polar nature it is very difficult to generate sufficient retention on conventional C18 HPLC columns. With a TSK amide HILIC type column good retention was obtained. A straightforward extraction-dilution protocol was developed. Using a mixture of dimethyl formamide and water biurea was nearly quantitatively extracted from a variety of fresh, coated and processed products. Mass spectrometric detection was performed with positive electrospray ionisation. The sensitivity and selectivity of the mass spectrometer for biurea was very good, allowing detection at concentrations as low as 10 microg kg(-1). However, in some extracts severe ion suppression effects was observed. To overcome the implications of ion suppression on the quantitative performance of the method an isotopically-labelled biurea internal standard was synthesized and incorporated in the method. The method developed can be used effectively in nitrofurazone analysis to eliminate the risk of false non-compliant results due to the presence of azodicarbonamide-treated components in the food product.

Can high-performance liquid chromatography coupled with fluorescence detection under all conditions be regarded as a sufficiently conclusive confirmatory method for B-group substances?

Commission Decision 2002/657/EC requires confirmatory analysis of B-group compounds when detected at levels above the permitted limit. In contrast to banned substances, for B-group substances, the use of mass spectrometric techniques is not obligatory and several techniques including liquid chromatography (LC)-ultraviolet light (UV) on two different LC columns and (single-column) high-performance liquid chromatography (HPLC)-fluorescence (Flu) are considered to deliver sufficient evidence for the identification of the detected substance. The analysis of sodium salicylate in animal drinking water collected at poultry farms is presented here as an example to show that even in a simple matrix such as animal drinking water, fluorescence detection in some cases may provide inadequate specificity. Of 50 samples analysed by LC-Flu, 18 tested positive for sodium salicylate. However, only in one sample was the presence of the analyte confirmed with mass spectrometric detection; the others were blank. Consequently, the LC-Flu results obtained were false-non-compliant for sodium salicylate. A second case concerning the analysis of avermectins in milk by HLPC-Flu is briefly described. For a number of samples analysed in the framework of a proficiency test, false non-compliant results for emamectin were reported due to a background interference sometimes present that practically co-eluted with the analyte. The observed retention time difference (1%) was well below the criterion (2.5%) specified in Commission Decision 2002/657/EC. Considering the impact of positive findings on individual farmers as well as on trade, product image and food safety perception by the consumer, it is concluded that also for B-group substances false-non-compliant results should be avoided whenever possible. This is especially important when the results are treated as and are expected to have the same repercussions as in the case of banned A-group substances. In these circumstances, only results obtained by mass spectrometry should be considered for confirmatory purposes.

Depletion of four nitrofuran antibiotics and their tissue-bound metabolites in porcine tissues and determination using LC-MS/MS and HPLC-UV

Depletion of the nitrofuran antibiotics furazolidone, furaltadone, nitrofurantoin and nitrofurazone and their tissue-bound metabolites AOZ, AMOZ, AHD and SEM from pig muscle, liver and kidney tissues is described. Groups of pigs were given feed medicated with one of the nitrofuran drugs at a therapeutic concentration (400?mg?kg(-1)) for ten days. Animals were slaughtered at intervals and tissue samples collected for analysis for six weeks following withdrawal of medicated feed. These samples were analysed both for parent nitrofurans (using LC-MS/MS and HPLC-UV), and for tissue-bound metabolites (using LC-MS/MS). The parent drugs were detectable only sporadically and only in pigs subjected to no withdrawal period whatsoever. This confirms the instability of the four major nitrofuran antibiotics in edible tissues. In contrast, the metabolites accumulated to high concentrations in tissues (ppm levels) and had depletion half lives of between 5.5 and 15.5 days. The metabolites of all four drugs were still readily detectable in tissues six weeks after cessation of treatment. This emphasizes the benefits of monitoring for the stable metabolites of the nitrofurans.

Determination of nifursol metabolites in poultry muscle and liver tissue. Development and validation of a confirmatory method

A method is described for the identification and quantitative determination of 3,5-dinitrosalicylic acid hydrazide (DSH), the marker residue of nifursol metabolites in poultry (turkey, broiler) muscle and liver tissue. The method is based on the acid-catalysed hydrolysis of tissue-bound metabolites to free DSH and in situ derivatisation with 2-nitrobenzaldehyde to the corresponding nitrophenyl derivative NPDSH. A structural analogue of DSH, 4-hydroxy-3,5-dinitrobenzoic acid hydrazide (HBH) was synthesised to serve as an internal standard. The analytes were isolated from the matrix by liquid-liquid extraction with ethyl acetate. Determination was performed by LC-MS/MS with negative electrospray ionisation. The [M - H](+) ions of NPDSH and NPHBH at m/z 374 were fragmented by collision induced dissociation (CID) producing transition ions at m/z 182, 183 and 226. The transition ions at m/z 182 and 226 were selected for monitoring of NPDSH while the transition ion at m/z 183 was selected for NPHBH. The method has been validated according to the EU criteria of Commission Decision 2002/657/EC at 0.5, 1.0 and 1.5 microg kg(-1) in muscle and liver tissue. A decision limit (CC(alpha)) was obtained of 0.04 and 0.025 microg kg(-1) in muscle and liver, respectively. Similarly a detection capability (CC(beta)) was obtained of 0.10 and 0.05 microg kg(-1) in muscle and liver, respectively. The introduction of HBH as an internal standard did not lead to a significant improvement of the quantitative performance of the method. In fact for liver better performance characteristics were obtained when the IS was not taken into account. Nevertheless, as a qualitative marker for recovery, HBH could still be very useful in the analysis of unknown samples.

Synthesis of 8-, 9-, 12-, and 13-mono-13C-retinal

The 8-, 9-, 12-, and 13-mono-13C-retinals were synthesized with > 98% chemical purity and 93% 13C incorporation from 13C-labelled acetonitrile. Their 13C–13C and 13C–1H nmr coupling constants were determined.