Determination of resorcylic acid lactones in biological samples by GC-MS. Discrimination between illegal use and contamination with fusarium toxins.

An EU project, FAIR5-CT-1997-3443, has been undertaken to distinguish illegal use of zeranol from consumption of food contaminated with Fusarium spp. toxin. One of the tasks was development of screening and confirmatory methods of analysis. This paper describes a new method based on two-step clean-up and GC-MS analysis. The first clean-up step is matrix-dependant; the second is applicable to both urine and meat. The MS is operated in negative chemical ionisation mode. The method is quantitative for zeranol and taleranol, alpha- and beta-zearalenol, and zearalenone and qualitative for zearalanone. Validation was performed according to the latest EU performance criteria (Commission Decision 2002/657). For analysis of urine CC(alpha) and CC(beta) for the method (microg L(-1)) were 0.06-0.11 for zeranol, 0.07-0.12 for taleranol, 0.07-0.11 for alpha-zearalenol, 0.21-0.36 for beta-zearalenol, 0.35-0.60 for zearalenone, and 0.19-0.33 zearalanone. Within-laboratory reproducibility was 16.2, 11.2, 31.9, 30.1, 26.6, and 54.2% for zeranol, taleranol, alpha-zearalenol, beta-zearalenol, zearalenone, and zearalanone, respectively. It was found that all the compounds are stable in urine at -20 degrees C for at least a year. Part of the validation program was organisation of a small proficiency study (ringtest) and a correlation study with an LC-MS-MS method developed by the Veterinary Science Division (VSD; Belfast, UK-NI). This study showed there was good correlation between results from both laboratories. The method can be used for quantitative analysis discriminating illegal use of zeranol from consumption of zearalenone-contaminated food.

Confirmatory assay for zeranol, taleranol and the Fusarium spp. toxins in bovine urine using liquid chromatography-tandem mass spectrometry.

A method is described for the quantitative determination of the veterinary drug zeranol, its epimer taleranol and the mycotoxins zearalenone, alpha-zearalenol and beta-zearalenol in bovine urine. The method is based on liquid chromatography coupled to negative-ion electrospray mass spectrometry-mass spectrometry of urine extracts prepared by solid-phase extraction with C(18) columns. Two transition ions at m/z 277 and 91 are monitored for zeranol and taleranol along with the transition ion at m/z 281 for their respective deuterated (d(4)) internal standards. Similarly, two transitions are monitored for each of the three mycotoxins along with a transition ion for each of their corresponding internal standards. The method has been validated according to the new European Union criteria for analysis of veterinary drug residues, and is suitable for monitoring urine samples taken under National Surveillance Schemes. The method has been validated at 1, 1.5 and 2 ng ml(-1) for zeranol and taleranol and at 5, 10 and 15 ng ml(-1) for each of the three mycotoxins. Correlation between the described method and a routine method, based on gas chromatography-mass spectrometry, was assessed using a range of naturally incurred samples.

Prevalence of zeranol, taleranol and Fusarium spp. toxins in urine: implications for the control of zeranol abuse in the European Union.

There is currently little information concerning the prevalence of zeranol and taleranol in animal urine following metabolism of the naturally occurring Fusarium spp. toxins. An epidemiological study is described which involves four European Union control laboratories in which 8008 urine samples were screened for the presence of zeranol using a time-resolved fluoroimmunoassay (TR-FIA). Of these samples, 93.6% screened negative for zeranol. All samples testing positive for zeranol were then analysed with a confirmatory method. Based on the confirmatory results, the TR-FIA-positive samples were then categorized as false-positive, true-positive or 'equivocal' (zeranol/taleranol and the Fusarium spp. toxins detected). The true-positive samples represented only 0.05% of the total number of samples (n = 4). After statistical analysis, 170 of 174 equivocal samples proved to belong to a 'normal' population in which the amount of zeranol/taleranol could be related to the total amount of Fusarium spp. toxins through a linear regression with a 99% prediction interval. This suggested that the presence of zeranol in these samples might be due to in vivo metabolism of the Fusarium spp. toxins. The presence of zeranol in the four remaining 'outliers' might be attributable to zeranol abuse rather than to natural contamination. The results are of interest for control laboratories as they might provide an analytical tool to help distinguish between abuse and natural contamination in zeranol testing.