Radioimmunoassay of ochratoxin A in barley

A simple and rapid radioimmunoassay was developed for the quantitative determination of ochratoxin A in barley. [14C]ochratoxin A, with a specific activity of 130 Ci/mol, was used as the tracer. Toxin levels below 100 ng/ml required a cleanup step. Three methods (the Association of Official Analytical Chemists cleanup method, the solvent partition method, and the Extrelut 3 column cleanup method) were compared.     

Ochratoxin A: Isolation and Subsequent Purification by High-Pressure Liquid Chromatography

A purification method for ochratoxin A, using liquid-liquid extractions and a final cleanup by high-pressure liquid chromatography, is described.     

Detection of ochratoxin A in porcine kidneys by a monoclonal antibody-based radioimmunoassay

By using an indirect enzyme-linked immunosorbent assay, eight monoclonal antibodies (MAbs) were selected. Mice were immunized with ochratoxin A that was conjugated to bovine serum albumin. The hybridoma cell line designated 10G2 was grown in tissue culture and as an ascites tumor. The MAb was characterized to be specific to ochratoxin A and of the immunoglobulin G (IgG) class. Subsequently, the ascites fluid of this hybridoma was used in a competitive solid-phase IgG radioimmunoassay on protein A-Sepharose CL-4B, with [14C]ochratoxin A as tracer. Porcine kidneys were extracted with 0.5% phosphoric acid in chloroform. A two-step cleanup was achieved on a Sep-Pak C18 cartridge and a Sep-Pak silica cartridge. Radioimmunoassay with MAbs coupled to protein A-Sepharose CL-4B allowed the detection of ochratoxin A in porcine kidneys at a concentration as low as 0.2 ng/g.     

Development of stable isotope dilution assays for ochratoxin A in blood samples

Two new stable isotope dilution assays were developed for the quantification of ochratoxin A in human blood samples for exposure studies. The methods based on two different sample extraction and cleanup procedures including liquid–liquid extraction with following immunoaffinity chromatography (IA) as well as a dispersive solid-phase extraction (DSPE) method. For detection, LC–MS/MS was applied. For the first time, exact quantitation of the reference compound ochratoxin A was performed by quantitative NMR spectroscopy (qNMR). Additionally, a comparison of different blood-drawing procedures revealed no differences for heparin plasma and serum whereas citrate plasma gave significantly lower results for the mycotoxin. Limits of detection (LOD: 0.02 ng/g (IA) vs 0.03 ng/g (DSPE)), limits of quantification (LOQ: 0.07 ng/g (IA) vs 0.08 ng/g (DSPE)), relative recovery (?94%), precision, and linearity indicated excellent performance of the developed methods.     

Occurrence of ochratoxin A in Korean red paprika and factors to be considered in prevention strategy

A large amount—260,000 tons—of red paprika is consumed annually in Korea, where the people prefer hot and pungent to sweet foods. Concern has recently grown among consumers over contamination of paprika powder by mycotoxins; contamination can occur at any stage from pre-harvest to drying, storage, grinding, and eventually transport to the retail market. This study had dual aims: to investigate the current level of contamination of hot peppers by ochratoxin A and to identify the critical control points in the food chain. We measured the ochratoxin A (OTA) content of 200 samples from various sources including supermarkets, an online shopping mall, small stakeholder mills, Hazard Analysis and Critical Control Points (HACCP)-implemented factories, and an import company. Mycotoxin was determined using immunoaffinity column cleanup/HPLC quantification as well as strong anion exchange cleanup/stable isotope dilution assay. Monitoring revealed that approximately 30% of red paprika samples were OTA-positive, indicating a need to establish a maximum level for regulation. We selected two model factories that had adopted HACCP in different ways, and compared data in order to develop guidelines for alleviation of mitigation of the mycotoxin contamination.     

Methods of detecting and determining nitrogen-containing mycotoxins]

The influence of various nitrogen functional groups used for extraction cleanup and determination of N-containing mycotoxins (NM) in feeds and foodstuffs have been considered. TLC and LC are the most common techniques for detection and determination of nitrogen-containing mycotoxins. Gas chromatography has been used for determination (with or without derivatization) of several nitrogen-containing mycotoxins and/or their degradation products. Immunochemical techniques, in particular ELISA are available for only a very limited number of NM (e.g. ochratoxin A). Numerous methods for determination of ochratoxin A in feeds, grains, animal products and other foodstuffs have been developed. Methods for which recoveries have been carried out on spiked samples are also available for several other NM.     

Isolation of secondary metabolites of Aspergillus ochraceus by HPLC

A method is described for the isolation and purification of ochratoxin A, ochratoxin B, ochratoxin ß mellein, 4-hydroxymellein and penicillic acid produced byAspergillus ochraceus in a synthetic liquid medium. Ochratoxin α, which was not found in the culture medium, was obtained by acid hydrolysis of ochratoxin A. A high pressure liquid Chromatograph equipped with Lichrosorb 100 and Lichrosorb RP-18 columns and UV and/or Refractive Index detectors was used.     

Ochratoxin A in blood from slaughter pigs in Sweden: use in evaluation of toxin content of consumed feed.

Samples of pig blood, intended for ochratoxin A analysis, were collected from pigs of 279 randomly selected herds. The samples were obtained at nine different slaughterhouses from different areas of Sweden. Pigs from 47 herds (16.8% of the total) exhibited ochratoxin A in amounts of greater than or equal to 2 ng of ochratoxin A per ml of blood. One sample each from a single pig per herd identified herds contaminated with ochratoxin A in amounts exceeding three times the detection limit of the method (3 x 2 ng of ochratoxin A per ml of blood = 6 ng of ochratoxin A per ml of blood). There was a good agreement between ochratoxin A concentrations in the blood from different pigs within the same herd (correlation coefficient = 0.80). The ochratoxin A concentration in pig blood was used as an estimate of the ochratoxin A content of the consumed feed. This method showed that feed from grain produced on-farm contained higher concentrations of ochratoxin A than commercial feed preparations. No geographical variation of ochratoxin A occurrence within Sweden was detected.     

Penicillium verrucosum in feed of ochratoxin A positive swine herds

Ochratoxin A contamination of cereal feed grain was monitored during October 1989–September 1990 by analysis of blood samples from slaughter swine in Sweden. The detection of ochratoxin A in swine blood was used as a method to identify swine herds fed ochratoxin A contaminated feed. The contamination level of ochratoxin A in the blood of the positive herds was in the range 2–45 ng/ml with the mean concentration 5.2 ng/ml. Feed samples for mycological analysis were collected from both ochratoxin A positive herds (2 ng/ml blood) and ochratoxin A negative herds (<2 ng/ml blood). From the ochratoxin A positive herds and the ochratoxin A negative herds 22 and 21 feed samples were collected, respectively. No quantitative differences in mould content, as determined by colony forming units, were observed between the two groups. However, there were differences in the mycoflora. The incidence of storage fungi (Penicillium and Aspergillus spp.) was significantly higher (p < 0.05) in feed from ochratoxin A positive herds. Particularly, Penicillium verrucosum was found to be significantly more common (p < 0.001). Altogether 274 isolates were screened for their ability to produce ochratoxin A. Ochratoxin A producers were found only within P. verrucosum; 38% of the 63 isolates produced detectable amounts of ochratoxin A. Ochratoxin A producing isolates of P. verrucosum were found in 60% of the feed samples collected from ochratoxin A positive swine herds and in one sample (5% ) of the feed samples collected from the ochratoxin A negative herds.     

Monitoring of residues of ochratoxin A in blood and kidney of chicken using HPLC-FLD

Detoxification of ochratoxin A can be achieved by chemical or enzymatic hydrolyzation, the products of such reactions are ochratoxin α and phenylalanine. Ochratoxin α like ochratoxin A, is a fluorescing molecule, therefore sensitive analysis is possible at very low concentration levels. Methods have been established that make it possible to look for residues of ochratoxin A and its main metabolite ochratoxin α in blood and tissues at very low concentration levels. Plasma is extracted by the use of small amounts of chloroform; the extract is cleaned with water and afterwards evaporated to dryness]. The residue is re-dissolved and analysed by HPLC-FLD. Using this method a limit of detection of 0.5μg/l for both ochratoxin A and ochratoxin α can be reached.     

Development of a multiplex flow cytometric microsphere immunoassay for mycotoxins and evaluation of its application in feed

A multi-mycotoxin immunoassay—using the MultiAnalyte Profiling (xMAP) technology—is developed and evaluated. This technology combines a unique color-coded microsphere suspension array, with a dedicated flow cytometer. We aimed for the combined detection of aflatoxins, ochratoxin A, deoxynivalenol, fumonisins, zearalenone and T-2-toxin in an inhibition immunoassay format. Sets of six mycotoxin-protein conjugates and six specific monoclonal antibodies were selected, and we observed good sensitivities and no cross-interactions between the assays in buffer. However, detrimental effects of the feed extract on the sensitivities and in some cases on the slopes of the curves were observed and different sample materials showed different effects. Therefore, for quantitative analysis, this assay depends on calibration curves in blank matrix extracts or on the use of a suitable multi-mycotoxin cleanup. To test if the method was suitable for the qualitative detection at EU guidance levels, we fortified rapeseed meal, a feed ingredient, with the six mycotoxins, and all extracts showed inhibited responses in comparison with the non-fortified sample extract. Contaminated FAPAS reference feed samples assigned for a single mycotoxin showed strong inhibitions in the corresponding assays but also often in other assays of the multiplex. In most cases, the presence of these other mycotoxins was confirmed by instrumental analysis. The multiplex immunoassay can be easily extended with other mycotoxins of interest, but finding a suitable multi-mycotoxin cleanup will improve its applicability.     

Entwicklung eines hochempfindlichen Enzymimmuntests zum Nachweis von Ochratoxin A

Antibodies against ochratoxin A were produced in rabbits after immunization with an ochratoxin A-keyhole limpet hemocyanine conjugate. The immunogen was found to be very efficient, and high antibody titers were detected in the sera of all immunized rabbits. In a competitive enzyme immunoassay using ochratoxin A-horseradish peroxidase as the labelled antigen, low levels of ochratoxin A in buffer solution could be detected. The mean standard curve detection limit and 50% inhibition level of the optimized assay were at 15 pg/ml and 50 pg/ml, respectively. Relative cross-reactivity of ochratoxin B was found to be 2%. With these characteristics, this novel enzyme immunoassay should be useful for the routine detection of ochratoxin A in food and in biological samples at levels well below 1 ng/g.     

Effect of Zinc, Copper, and Iron on Ochratoxin A Production

The effect of zinc, copper, and iron levels on production of ochratoxin A by Aspergillus ochraceus Wilhelm in a synthetic medium in a shake culture was investigated. Optimal concentrations of ZnSO₄, CuSO₄, and FeCl₃ for ochratoxin A production were 0.055 to 2.2 mg/liter, 0.004 to 0.04 mg/liter, and 1.2 to 24 mg/liter, respectively. Zinc and copper levels greater than optimum reduced the rate of ochratoxin accumulation without altering either glutamate or sucrose utilization. Ochratoxin A production was correlated with rapid utilization of sucrose by the fungus and decreasing pH of the medium. Most of the glutamic acid was removed from the medium prior to ochratoxin production. There was no correlation between mycelial dry weight and ochratoxin A production.     

Determination of ochratoxin A in urine and faeces of swine by high-performance liquid chromatography

Sensitive methods for the determination of ochratoxin A in urine and faeces of swine are described. The samples were extracted with chloroform at pH <2, and the extracts were cleaned up by a combination of solid-phase extraction and liquid—liquid partition. High-performance liquid chromatography with fluorescence detection was used for detection and determination. The detection limits were 0.3 ng/ml for urine and 1.5 ng/g for faeces. Recoveries of ochratoxin A from spiked samples of urine and faeces were 93% and 60%, respectively. Because of the low detection limit and the fast and relatively easy performance, the method for the determination of ochratoxin A in urine proved suitable for the estimation of possible contamination of live animals.     

Determination of ochratoxin A in liquorice products using HPLC-based analytical methods. Part II: harmonised method and method validation study

On the basis of the outcome of an European proficiency test series conducted on behalf of the CAOBISCO (Association of the Chocolate, Biscuit and Confectionery Industries of the EU) expert group on ochratoxin A, a new harmonised method was developed for the analysis of ochratoxin A in liquorice extracts. This method works without the use of halogenated solvents because, as the proficiency test showed, an aqueous extraction solution can be used instead of, for example, chloroform, whose use is restricted in the EU. The main objective of this method validation study was to check the performance of this harmonised method. To carry out the method validation study, a set of three different test samples (one liquorice powder and two liquorice pastes) and a liquorice powder sample with an indicated range of ochratoxin A (a so-called sunshine sample) was distributed to 21 laboratories in ten countries throughout Europe and to one laboratory in the USA. The study was evaluated according to internationally recognised guidelines. In terms of its repeatability and reproducibility for determining ochratoxin A in liquorice extracts with a relative standard deviation for repeatability (RSD_r) of between 6.68 and 19.95 and a relative standard deviation for reproducibility (RSD_R) of between 17.39 and 29.08 the performance of the harmonised method was found to be in the accepted range of the EU directive for the analysis of mycotoxins in several foodstuffs.     

Assessment of ochratoxin A and tenuazonic acid in Canadian ice-wines

Twenty-six samples of commercial ice-wine made from late-harvested grapes were assayed for the mycotoxins ochratoxin A and tenuazonic acid. Canadian wines originated in British Columbia (18) and Ontario (8). For comparison two German wines from Hesse were also studied. Four additional samples of research ice-wine originating in were also studied. In all wine samples, assays using immuno-affinity chromatography and fluorescence liquid chromatography indicated ochratoxin A below 0.15 μg/L, the limit of determination of the method. Tenuazonic acid was determined by solidphase micro-extraction and liquid chromatography and was below the limit of determination (70 μg/L) in all samples. The European Union food tolerance limit for ochratoxin A in wine is 2 μg/L. A tolerance for tenuazonic acid has not yet been established.     

Biosynthesis of ochratoxins by Aspergillus ochraceus.

Shaken liquid fermentation of an isolate of Aspergillus ochraceus showed growth-associated production of ochratoxins A and B, followed by production of a related polyketide diaporthin. Later, between 150 and 250 h, mellein accumulated transitorily. In contrast, shaken solid substrate (shredded wheat) fermentation over 14 days produced mainly ochratoxins A and B (ratio ca. 5:1) in very high yield (up to 10 mg/g). In these systems experiments with 14C-labelled precursors and putative intermediates revealed temporal separation of early and late stages of the ochratoxin biosynthetic pathway, but did not support an intermediary role for mellein. The pentaketide intermediate ochratoxin beta was biotransformed very efficiently into both ochratoxins A and B, 14 and 19%, respectively. The already chlorinated ochratoxin alpha was only biotransformed significantly (4.85%) into ochratoxin A, indicating that chlorination is mainly a penultimate biosynthetic step in the biosynthesis of ochratoxin A. This was supported by poor (1.5%) conversion of radiolabelled ochratoxin B into ochratoxin A. Experiments implied that some ochratoxin B may arise by dechlorination of ochratoxin A.     

Conversion of ochratoxin C into ochratoxin A in vivo.

The conversion of ochratoxin C to ochratoxin A was studied in rats after oral and intravenous administration. The concentration of ochratoxin A in the blood as a function of time was the same after oral administration of equivalent amounts of either ochratoxin C or ochratoxin A. The maximum ochratoxin A concentrations were measured 60 min after administration. Given intravenously, ochratoxin C was also converted to ochratoxin A. Maximum concentrations were reached after 90 min. It is concluded that ochratoxin C is readily converted to ochratoxin A after both oral and intravenous administration. There is reason to believe that a comparable toxicity of the two toxins is based upon this conversion and that only interference with the biotransformation mechanisms may cause a difference in their toxicity.     

Metabolism of ochratoxin B and its possible effects upon the metabolism and toxicity of ochratoxin A in rats

A metabolic product was formed from ochratoxin B by rat liver microsomal fractions in the presence of NADPH. It was isolated from the incubation mixture by extraction, thin-layer chromatography, high-pressure liquid chromatography, and crystallization. On the basis of mass and nuclear magnetic resonance spectroscopy, the structure is suggested to be 4-hydroxyochratoxin B. The Km for the formation of 4-hydroxyochratoxin B was determined, and the hydroxylation of ochratoxin A was not altered by the presence of ochratoxin B. Rats were given ochratoxin A or B, or a mixture of both intraperitoneally. The ratios of the three metabolites, ochratoxin A, (4R)-4-hydroxyochratoxin A, and ochratoxin alpha, excreted in the urine did not change in the presence of ochratoxin B. Ochratoxin B was metabolized to 4-hydroxyochratoxin B and ochratoxin beta, but in a different ratio than for the ochratoxin A metabolites. When given intraperitoneally, ochratoxin beta was excreted within 24 h. In rats treated with ochratoxin A alone, the food intake was reduced by 50%, and histologically severe lesions, degeneration, and necrosis were observed in the proximal tubules. When ochratoxin A and B given in combination, the animals were clinically unaffected and histologically there was only slight damage of proximal tubules. These observations indicate that ochratoxin B considerably reduces the toxic effects of ochratoxin A.