- Email: [email protected]
Alternaria toxins and conjugates in selected foods in the Netherlands
Accepted Manuscript Alternaria toxins and conjugates in selected foods in the Netherlands Patricia López, Dini Venema, Hans Mol, Martien Spanjer, Joyce de Stoppelaar, Erika Pfeiffer, Monique de Nijs PII:
S0956-7135(16)30170-0
DOI:
10.1016/j.foodcont.2016.04.001
Reference:
JFCO 4960
To appear in:
Food Control
Received Date: 21 February 2016 Revised Date:
27 March 2016
Accepted Date: 1 April 2016
Please cite this article as: López P., Venema D., Mol H., Spanjer M., de Stoppelaar J., Pfeiffer E. & de Nijs M., Alternaria toxins and conjugates in selected foods in the Netherlands, Food Control (2016), doi: 10.1016/j.foodcont.2016.04.001. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Alternaria toxins and conjugates in selected foods in the Netherlands.
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Patricia Lópeza*, Dini Venemaa, Hans Mola, Martien Spanjerb, Joyce de Stoppelaarb, Erika
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Pfeifferc, Monique de Nijsa
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RIKILT – Wageningen UR, Akkermaalsbos 2, 6708 WB, Wageningen, The Netherlands
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NVWA – Netherlands Food and Consumer Product Safety Authority, Catherijnesingel 59,
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3511 GG Utrecht, The Netherlands
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Institute of Applied Biosciences, Department of Food Chemistry and Phytochemistry,
Karlsruhe Institute of Technology (KIT), Adenauerring 20a, 76131 Karlsruhe, Germany
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Corresponding author: [email protected]
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ABSTRACT
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A survey on Alternaria toxins in the food categories dried figs (n=14), sunflower products
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(n=24) and tomato products (n=43) was carried out in the Netherlands on samples collected in
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retail stores in autumn 2014.
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The occurrence data from this survey confirmed the previously reported data of a pilot survey
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in 2013, with tenuazonic acid being an ubiquitous Alternaria toxin in dried figs (100% of the
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samples), sunflower seeds (80% of the samples) and tomato products (60% of samples) at
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relatively high concentrations, up to 1,728 µg/kg in dried figs and 1,350 µg/kg in sunflower
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seeds. Despite the occurring of high concentrations of tenuazonic acid in sunflower seeds and
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figs, it is unlikely that the population in the Netherlands is exposed to levels of concern.
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Alternariol was detected in 27% of the tomato products ranging from LOQ (2 µg/kg) up to 26
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µg/kg, while alternariol monomethyl ether was present in 7% of the tomato products. In the
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worst case situation, consumption of these products may result in exposure at levels above the
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threshold of toxicological concern of 2.5 ng/kg body weight/day for alternariol. None of seven
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conjugates of Alternaria toxins was detected above the limit of quantification (LOQ) of 2.5
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µg/kg.
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Keywords: Alternaria toxins, conjugates, dried figs, sunflower, tomato processed products.
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1.
INTRODUCTION
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Alternaria toxins are mycotoxins produced by Alternaria species, pathogenic and saprophytic
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fungi widely distributed in soil. Alternaria species have been reported to occur in cereals
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(mainly in wheat, sorghum and barley), oilseeds, such as sunflower and rapeseed, tomatoes,
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apples, citrus fruits, olives and several other fruits and vegetables (EFSA, 2011). They grow
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at low temperature; hence they are generally associated with extensive spoilage during
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refrigerated transport and storage (Ostry, 2008).
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Alternaria species can produce more than 70 secondary metabolites, but only a small
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proportion of them have been chemically characterized and reported as toxic to humans and
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animals (Barkai-Golan, 2008). However, there are currently no harmonised legal limits for
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Alternaria toxins in food products in the EU. The European Food Safety Authority (EFSA)
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published their opinion in 2011 on the risks for animal and public health related to the
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presence of Alternaria toxins in feed and food (EFSA, 2011). EFSA evidenced a lack of
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robust occurrence data of Alternaria toxins in food and processed products, and recommended
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the collection of representative data across Europe. Following this conclusion, the Scientific
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Committee on the Food Chain and Animal Health identified the following five toxins of
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concern for human health: alternariol (AOH), alternariol monomethyl ether (AME),
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tenuazonic acid (TeA), tentoxin (TEN) and altenuene (ALT). Other groups of Alternaria
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toxins, such as altertoxins (ATX) and Alternaria alternate f. sp. lycopersici toxins (AAL
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toxins), were deemed to be of less relevance (Standard Committee on the Food Chain and
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Animal Health, 2012).
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In their opinion, EFSA stated that the risk for public health related to these mycotoxins is not
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expected to result from acute toxicity (EFSA, 2011). However, although AOH and AME
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showed no strong acute toxic effects, they could induce fetotoxic and teratogenic effects
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(EFSA, 2011). AOH, AME and especially ATX II showed genotoxic effects in cultured
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mammalian cells (Fleck, Burkhardt, Pfeiffer, & Metzler, 2012). As the toxicity data were not
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sufficient for identification of reference points for different toxicological effects, EFSA
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decided to use the threshold of toxicological concern (TTC) approach to assess the relative
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level of concern for dietary exposure of humans. For AOH and AME the TTC value of 2.5
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ng/kg b.w./day was applied, for TEN and TeA the TTC value of 1500 ng/kg b.w./day (EFSA,
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2011). In their risk assessment, the estimated chronic dietary exposure to AOH and AME
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exceeded the TTC value, which emphasized the need for more additional data on the toxicity
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of Alternaria toxins (EFSA, 2011).
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In response to the EFSA recommendation on the need for more data on the occurrence of
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Alternaria toxins, a survey was conducted in 2013 in the Netherlands, on 95 retail products
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classified in 10 different food categories, to identify the food groups of concern (López, et al.,
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2016). The results from that survey showed that TeA occurred in 27% of the samples and at
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highest concentrations in sunflower seeds, tomato sauces and dried figs. The prevalence of the
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other Alternaria toxins (AOH, AME, TEN and ALT) was low in all food groups. It was
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concluded that more occurrence data on each specific type of product were necessary for a
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proper evaluation of the occurrence of Alternaria toxins (e.g. annual variations) and for the
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exposure of the Dutch consumers to TeA through the consumption of these products.
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The possible occurrence of conjugated or “masked” Alternaria toxins, in which the mycotoxin
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is bound to a more polar substance like glucose or sulfate, has been pointed out (Ostry, 2008).
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Conjugates of Alternaria toxins may be of relevance to exposure, as they may release the
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native mycotoxin after hydrolysis in the human digestive tract. Hildebrand et al. have recently
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identified five β-D-glucopyranosides and a 6’-malonyl-β-D-glucopyranoside of AOH, as well
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as a D-glucopyranoside and 6’- and 4’-malony-β-D-glucopyranosides of AME in tobacco
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suspension cells (Hildebrand, et al., 2015). The same authors observed that in plant cells
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AME glucosides underwent malonyl conjugation, whereas AOH glucosides underwent
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glucosylation (Hildebrand, et al., 2015). AOH and AME sulfate conjugates were detected in
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tomato products and glucoside conjugates in sesame seeds in a survey performed in Belgium
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(Walravens, et al., 2014b).
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This work describes the results from a survey carried out in 2014 in the Netherlands for the
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occurrence of five Alternaria toxins (AOH, AME, TeA, TEN and ALT) in tomato products,
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sunflower products and dried figs. These products were identified as vulnerable to
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contamination with Alternaria toxins in a pilot study. The potential presence of seven
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conjugate forms of AOH and AME, i.e. AOH-9-glucoside (AOH9G), AOH-3-glucoside
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(AOH3G), AOH-9-diglucoside (AOH9DG), AOH-3-sulfate (AOH3S), AME-3-glucoside
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(AME3G), AME-3-malonylglucoside (AME3MG) and AME-3-sulfate (AME3S) was also
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monitored.
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MATERIALS AND METHODS
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2.1. Chemicals and reagents
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Acetonitrile and methanol, both UPLC grade, were purchased from Actu-all Chemicals (Oss,
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the Netherlands), formic acid (98–100%) from Merck (Amsterdam, the Netherlands), and 4
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ammonium formate (99%) from Across Organics (Geel, Belgium). MilliQ water (>18MΩ)
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was used (Millipore, Bedford, MA, USA). AOH and AME were purchased from Biosolve
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(Greyhound Chromatography and Allied Chemicals, Merseyside, UK). TeA, TEN and ALT
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were supplied by Sigma-Aldrich (Zwijndrecht, the Netherlands). All standards had a purity
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higher than 99%. Individual stock solutions of each mycotoxin at 100 µg/mL in acetonitrile
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and in methanol for TeA were prepared. A solution of ALT of 1 mg/mL was provided by the
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Chemistry laboratory of the Netherlands Food and Consumer Product Safety Authority. A
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mixture working solution containing AOH, AME, ALT and TEN at 1 µg/mL and TeA at 5
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µg/mL in acetonitrile was prepared.
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standard.
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The AOH and AME conjugates (AOH9G, AOH3G, AOH9DG, AME3G, AME3MG) were
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isolated and provided by the Institute of Applied Bioscience (Karlsruhe Institute of
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Technology, Germany). Figure 1 shows the structure of these conjugates. A mix stock
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solution containing the conjugates in concentrations ranging from 0.8 to 2 µg/mL was
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prepared in methanol.
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C-Caffeine (Sigma-Aldrich) was used as internal
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2.2. Samples
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A total of 81 samples was purchased from retail stores in the Netherlands in the autumn of
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2014. The samples covered the food categories dried figs (n=14), processed tomato products
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(15 tomato juices, 13 tomato sauces, 5 tomato ketchups and 10 other processed tomato
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samples) and sunflower products (11 sunflower oils, 3 sunflower pastes and 10 roasted
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shelled sunflower seed samples). The samples were stored at the temperature recommended
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on the label until processing. Sunflower paste and sunflower oil were stored as such at room
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temperature. Processed tomato samples were homogenized and stored at -20 °C. Dried figs
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and sunflower seeds were homogenized by milling and mixing with water to form a slurry.
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The water content in ratio was 1:3 for dried figs and 1:4 for sunflower seeds.
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2.3. Method
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An aliquot of 2.5 g of tomatoes, sunflower oil or sunflower pasta were weighed, spiked with
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12.5 µL of internal standard (13C-caffeine at 10 µg/mL) and extracted with 10 mL of
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acetonitrile/water (84/16, v/v) acidified with 1% of acetic acid. 10 g of the slurry of figs and
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12.5 g of the slurry of sunflower seeds were weighed, spiked with 12.5 µL of internal
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standard (13C-caffeine at 10 µg/mL) and extracted with 10 mL of acetonitrile containing 1%
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of acetic acid. Samples were shaken for two hours at 250 rpm and then centrifuged for 10 min 5
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at 3,000 rpm. The extracts were filtered in mini-uniprep PTFE filter vials and analysed by
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LC-MS/MS.
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The LC-MS/MS instrument was a Shimadzu ‘Prominence’ HPLC system (Shimadzu Europa
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GmbH, Duisburg, Germany), which consisted of a DGU-20A3 degasser, a SIL 20AC XR
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autosampler, two LC-20 AD XR UFLC pumps, and a CTO-20AC column oven. This system
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was coupled to an AB SCIEX QTRAP® 5500 mass spectrometer (AB Sciex Netherlands
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B.V., Nieuwerkerk aan den Ijssel, The Netherlands).
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HPLC separation was performed by injecting 5 µL of the extract into a Waters Atlantis HSS-
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T3, (3µm), 3.0 x 100 mm column (Waters, Milford, MA, USA). The chromatographic
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conditions were as follows: column temperature 35 °C; mobile phases consisting of water as
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eluent A and 4% (v/v) water in methanol as eluent B. Both mobile phases contained 1 mM of
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ammonium formate and 1% of formic acid. The flow rate was set at 0.4 mL/min. A gradient
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elution was applied as follows: after an initial hold time of 1 min at 100% eluent A, 50%
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eluent B was reached within 2 min, which was kept for 1 min, and 100% eluent B within the
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next 5 min. This composition was kept for 2 min, after which 100% eluent A was reached
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within the next 0.5 min and kept for 4.5 min for column re-equilibration. The gradient used
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before (López, et al., 2016) was slightly modified to allow the determination of the
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conjugates.
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The analysis of the samples was carried out using electrospray ionisation (ESI) and multiple
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reaction monitoring (MRM). The precursor and product ion transitions for the five Alternaria
158
toxins were the same as previously used. The determination of the precursor and parent ion
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for the Alternaria toxin glucoside conjugates was carried out by infusion of a solution
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containing the mixed conjugate standard. Optimization was conducted in both positive and
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negative ionisation modes. The transitions of the Alternaria toxin sulfate-conjugates were also
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monitored. Their transitions were taken from literature (Walravens, et al., 2014a). Table 1
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summarizes the retention times (RTs) and the applied values for fragmentation voltages and
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collision.
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2.4. Sample analysis
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The Alternaria toxins in the samples were quantified by standard addition. The addition was
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10 µg/kg of AOH, AME, TEN and ALT and 50 µg/kg of TeA. If necessary, the addition was
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repeated at higher levels (equivalent to 50 µg/kg for AOH, AME, TEN and ALT and 250
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µg/kg for TeA) and/or the extracts diluted. Quality control samples for each matrix under
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study were included in each analytical series. 6
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Recoveries for quality controls fell between 50-60% for each toxin in sunflower products, and
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between 80-120% for each toxin in tomato products and dried figs. As the standard addition
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procedure already takes into account the losses due to extraction and matrix effects in the LC-
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MS/MS instrument, the results were not corrected for recovery.
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The LOQs for each Alternaria toxin were estimated in previous work (López, et al., 2016) as
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the concentration in a spiked sample, for which the signal-to-noise (S/N) ratio of the
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quantifier ion was equal to ten, providing that the signal of the qualifier ion was equal to
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three. The LOQs were 1.5 µg/kg for ALT, 2.0 µg/kg for AOH, 1.0 µg/kg for AME, 2.5 µg/kg
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for TEN y 5.0 µg/kg for TeA.
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The Alternaria toxins and conjugates were identified by similarity of retention times and ion
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ratios between the compounds in the sample extract and the standards in the matrix. The
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criteria used to ensure the correct identification of the target mycotoxins were according to
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SANTE guidelines (SANTE, 2015): (a) the retention times of the analyte in the sample extract
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matched those of spiked sample extract within a deviation of ±0.2 min; (b) the deviation of
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the ion ratio of the sample extract fell within ±30% of the ion ratio for the spiked sample
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extract.
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2.5. Data treatment
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Non-detects for calculation purposes were treated with the substitution method (EFSA, 2010).
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In this study, the upper bound was followed, which means that results below LOD were
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equalled to LOD and results between LOD and LOQ were equalled to LOQ.
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RESULTS AND DISCUSSION
3.1. Optimization of the instrumental method for Alternaria toxin conjugates
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Seven Alternaria toxin conjugates were included in the LC-MS/MS method as published by
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Lopez et al. (López, et al., 2016). Their behaviour as regards separation and fragmentation
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was studied for the conditions described in the materials and method section. Under those
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conditions, the elution order of the Alternaria toxin conjugates is shown in Figure 2. The
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AOH and AME conjugates eluted according to their decreasing polarity: AOH9DG, AOH9G,
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AOH3G, AME3G and AME3MG.
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The protonated molecule of AOH glucosides ([M + H]+ m/z 421) lost the hexose group during
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fragmentation to produce the fragment m/z 259 [AOH + H]+, which in turn lost formic acid to
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form the fragment m/z 213. The fragmentation of the diglucoside conjugate of AOH ([M +
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H]+ m/z 583) resulted in the sequential loss of two hexose moieties (162) to yield the product
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ions m/z 421 ([glucoside + H]+ and m/z 259 [AOH + H]+.
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Two different parent ions were chosen to detect AME3G, the protonated molecule [M + H]+
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m/z 435 and the ammonium adduct [M+NH4]+ m/z 452. Both transitions provided the same
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product ion [AME + H]+ m/z 273. For AME3MG only one transition was detectable, which
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consisted of the loss of the malonylglucoside group to give the fragment [AME + H]+ m/z
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273.
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The transitions detected in this work were in agreement with those found when these
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glucosides conjugates were first elucidated and detected in tobacco cells (Hildebrand, et al.,
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2015). Walravens et al. (Walravens, et al., 2014a) analysed the AOH and AME conjugates
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with negative electrospray ionization. The parent ion was for both Alternaria toxins the
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deprotonated molecule [M – H]- and the resulting product ions were the deprotonated toxin,
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either [AME –H]- or [AOH – H]-, and the deprotonated toxin with a loss of formic acid
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moiety. Negative ionization was also assessed, but sensitivity was lower compared to positive
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mode.
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The method was not validated for the analysis of Alternaria toxin conjugates, due to the
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limited amounts of standards available. Therefore, an LOQ of 2.5 µg/kg for the Alternaria
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toxin conjugates was derived from the signal-to-noise ratio of injected standards in solvent.
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3.2. Occurrence of Alternaria toxins and their conjugates in the selected products
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The results of the survey of Alternaria toxins and their conjugates in the 81 samples are
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summarized in table 2 and table 3. Detailed information on the occurrence of Alternaria
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toxins and their conjugates in each sample is presented in Supplementary Information SS1.
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As described previously (López, et al., 2016), TeA was the most prevalent toxin, being
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present in this study in 100% of dried figs, 80% of sunflower seeds and 60% of tomato
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products.
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TeA was the main Alternaria toxin in sunflower seeds, ranging from LOQ to 1,350 µg/kg.
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AOH and AME were detected in one sample. These findings differed from reports by other
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authors in which AOH, AME and TEN were present in this food commodity (EFSA, 2011;
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Hickert, Bergmann, Ersen, Cramer, & Humpf, 2015). The processing of sunflower seeds
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might have resulted in a reduction of TeA, since it was detected neither in sunflower oil nor in
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sunflower paste samples in the present study. Sunflower oil is produced by pressing of seeds
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and/or solvent extraction. Solvent extraction with organic solvent was proven to enhance in
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particular the transfer of AME to oil, whereas TeA was hardly transferred to the oil (Chulze,
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et al., 1995). Sunflower paste is produced by hardening (hydrogenation) of sunflower oil.
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The results obtained for dried figs in the present survey confirmed the previous findings: all
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analysed samples contained TeA at relatively high levels ranging from 81 to 1,728 µg/kg.
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Despite the high levels of Alternaria toxins detected in sunflower seeds or figs in this study,
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their consumption does not pose a risk for the health of the population in the Netherlands. In
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the worst case scenario, a 70-kg person would need to eat more than 77 g of sunflower seeds
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contaminated with 1,350 µg/kg of TeA, or 60 g of dried figs contaminated with 1,728 µg/kg
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of TeA to exceed the level of concern (TTC) of 1,500 ng/kg b.w./day for TeA on routine basis
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(77 g x 1,350 ng/g / 70 kg b.w. = 1485 ng/kg b.w./day of TeA).
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TeA was the main Alternaria toxin detected in tomato products ranging from 5.0 to 344 µg/kg
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(60% of samples), followed by AOH (27% of samples) and AME (7%). AME only occurred
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in tomato paste, tomato sauces and ketchup samples, but not in tomato juices or processed
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tomato pieces. The highest concentrations of TeA were found in tomato pastes (60%, ranging
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from LOQ to 344 µg/kg) followed by tomato juices and tomato ketchup. These results are in
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agreement with the results in the study by Noser et al. in products on the market in
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Switzerland (Noser, Schneider, Rother, & Schmutz, 2011), but differed from the survey by
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Zhao in China (Zhao, Shao, Yang, & Li, 2015), where tomato ketchup samples contained the
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highest levels of TeA. The levels of AOH and AME were similar to previous studies (Hickert,
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et al., 2015; López, et al., 2016; Noser, et al., 2011; Zhao, et al., 2015). The fact that TeA was
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found at lower levels in tomato products containing whole tomato pieces may indicate that the
260
quality of the ingredients used for producing tomato pastes, tomato purees and tomato juices
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might be an issue. No significant correlations between AOH and AME (r2 = 0.42) or AOH
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and TeA (r2 = 0.39) were found in tomato samples. This may be due to the contamination of
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the raw material with different Alternaria strains with variations in their biosynthetic profile
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or the selective degradation of certain compounds during food processing (Hickert, et al.,
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2015).
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The levels of AOH and AME found in tomato products indicated that high consumption of
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these products may pose a health risk for the population in the Netherlands since the daily
268
intake may exceed the TTC level of 2.5 ng/kg b.w./day. In the worst case scenario, the intake
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of AOH would be above the threshold if a 70-kg person consumed 7 g of tomato paste
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contaminated with 26 µg/kg of AOH (7 x 26 / 70 = 2.6 ng/kg b.w./day) or 10 g of tomato
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ketchup contaminated with 18 µg/kg o1f AOH (10 x 18 / 70 = 2.6 ng/kg b.w./day). These data
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are in agreement with the risk assessment carried out in the Netherlands in 2013 (Sprong, et
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al., 2015), which revealed that tomato products were one of the main contributors to the
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exposure to Alternaria toxins and concluded that health risk based on the TTC approach for
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AME or AOH could not be ruled out.
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Masked mycotoxins or mycotoxin conjugates can be formed during food processing. None of
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the seven Alternaria toxin conjugates were detected in the 81 samples in the current survey.
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The presence of other mycotoxin conjugates in foodstuffs have been reported for
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deoxynivalenol (DON) (3-acetylDON, 15-acetylDON and DON-3-glucoside), zearalenone,
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fumonisins, ochratoxin A (Berthiller, et al., 2013) and HT-2 and T-2 toxins (Lattanzio, et al.,
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2015). In case of DON and DON-3-glucoside, the ratio of occurrence may be quite stable,
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although it can vary depending on the year and the plant genotype (Berthiller, et al., 2013).
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Alternaria toxins sulphate conjugates have been only reported to occur in tomato products and
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sesame seeds (Walravens, et al., 2014b). These authors detected AOH3S and AME3S in 23%
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and 41% of tomato juice samples, in 14% and 27% of tomato sauces and in 33% and 76% of
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tomato pastes, respectively, and co-occurring with AOH and AME. However, the authors did
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not provide information on the occurrence of Alternaria toxins and conjugates in the
288
individual samples, and therefore a ratio between conjugated and non-conjugated forms, as
289
carried out for DON-3-glucoside and DON (Janssen, Sprong, Wester, De Boevre, &
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Mengelers, 2015), could not be estimated. Taking into account the occurrence of AOH and
291
AME in the present study and the maximum concentration of AOH, AME and conjugates,
292
reported by Walravens, it is unlikely that AME3S would have been detected in the tomato
293
products in this study. However, AOH3S might have been detected in tomato pastes and/or
294
sauces at values close to the LOQ (2.5 µg/kg). Nevertheless, only the availability of high
295
quality commercial standards would allow a more accurate quantification on the occurrence
296
of Alternaria toxin conjugates.
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The results of this survey and the previous survey (López, et al., 2016) indicate that
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contamination of sunflower seeds, sunflower seed products and tomato products available on
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the retail market in the Netherlands with Alternaria toxins seem to be relatively constant over
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the years 2013-2104.
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CONCLUSIONS
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The study reported in this paper showed that TeA was present at relatively high
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concentrations in tomato products, in dried figs and sunflower oils available in retail market in 10
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the Netherlands in 2014. Due to its hydrophilic properties, TeA seems to be lost during the
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processing of seeds to obtain oil and/or sunflower paste. The data from this survey confirm
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the results from a previous study in 2013 and indicate that in the Netherlands contamination
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of sunflower seeds, dried figs and tomato products with Alternaria toxins seems to be
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relatively constant over the years 2013-2104. The seven conjugated forms of AOH and AME
311
(sulfates and glucosides) were not detected in any of the samples.
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The results showed that a risk to the health of consumers of high amounts of tomato products
313
in the Netherlands cannot be excluded. It is, therefore, advisable to monitor occurrence of
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Alternaria toxins at least in these mentioned food categories.
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ACKNOWLEDGMENTS
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The authors gratefully acknowledge Alwin Kruijt, Food Safety Laboratory of the Netherlands
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Food and Consumer Product Safety Authority, for kindly providing the altenuene standards,
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Manfred Metzler and Ron Hoogenboom for the fruitful discussions. This study was carried
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out in WOT project-02-001-061 ‘Method development and surveys on mycotoxins in food’ at
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RIKILT Wageningen UR, on behalf of and funded by the Netherlands Ministry of Economic
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Affairs.
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Barkai-Golan, R. (2008). Alternaria Mycotoxins. In R. B.-G. a. N. Paster (Ed.), Mycotoxins in fruits and vegetables. San Diego, CA, USA: Elsevier. Berthiller, F., Crews, C., Dall'Asta, C., De Saeger, S., Haesaert, G., Karlovsky, P., Oswald, I. P., Seefelder, W., Speijers, G., & Stroka, J. (2013). Masked mycotoxins: A review. Molecular Nutrition & Food Research, 57(1), 165-186. Chulze, S. N., Torres, A. M., Dalcero, A. M., Etcheverry, M. G., Ramirez, M. L., & Farnochi, M. C. (1995). Alternaria mycotoxins in sunflower seeds: Incidence and distribution of the toxins in oil and meal. Journal of Food Protection, 58(10), 1133-1135.
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Summary report of the Standing Committe on the food chain and animal health (section Toxicological Safety of the food chain), held in Brussels on 29 May 2012. Alternaria toxins. EFSA. (2011). Scientific Opinion on the risks for animal and public health related to the presence of Alternaria toxins in feed and food EFSA Journal, 9(10), 97. EFSA (2010). Management of left-censored data in dietary exposure assessment of chemical substances. EFSA Journal 8(3) 1557. Fleck, S. C., Burkhardt, B., Pfeiffer, E., & Metzler, M. (2012). Alternaria toxins: Altertoxin II is a much stronger mutagen and DNA strand breaking mycotoxin than alternariol and its methyl ether in cultured mammalian cells. Toxicology Letters, 214(1), 27-32. Hickert, S., Bergmann, M., Ersen, S., Cramer, B., & Humpf, H.-U. (2015). Survey of Alternaria toxin contamination in food from the German market, using a rapid HPLC-MS/MS approach. Mycotoxin research, 1-12. Hildebrand, A. A., Kohn, B. N., Pfeiffer, E., Wefers, D., Metzler, M., & Bunzel, M. (2015). Conjugation of the Mycotoxins Alternariol and Alternariol Monomethyl Ether in Tobacco Suspension Cells. Journal of Agricultural and Food Chemistry, 63(19), 4728-4736. Janssen, E. M., Sprong, R. C., Wester, P. W., De Boevre, M., & Mengelers, M. J. B. (2015). Risk assessment of chronic dietary exposure to the conjugated mycotoxin deoxynivalenol-3-β-glucoside in the Dutch population World Mycotoxin Journal, 8(5), 561-572. Lattanzio, V. M. T., Ciasca, B., Terzi, V., Ghizzoni, R., McCormick, S. P., & Pascale, M. (2015). Study of the natural occurrence of T-2 and HT-2 toxins and their glucosyl derivatives from field barley to malt by high-resolution Orbitrap mass spectrometry. Food Additives and Contaminants Part a-Chemistry Analysis Control Exposure & Risk Assessment, 32(10), 1647-1655.
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López, P., Venema, D., de Rijk, T., de Kok, A., Scholten, J. M., Mol, H. G. J., & de Nijs, M. (2016). Occurrence of Alternaria toxins in food products in The Netherlands. Food Control, 60, 196-204. Noser, J., Schneider, P., Rother, M., & Schmutz, H. (2011). Determination of six Alternaria toxins with UPLCMS/MS and their occurrence in tomatoes and tomato products from the Swiss market. Mycotoxin research, 27(4), 265-271. Ostry, V. (2008). Alternaria mycotoxins: an overview of chemical characterization, producers, toxicity, analysis and occurrence in foodstuffs. World Mycotoxin Journal, 1(2), 175-188. SANTE (2015). Guidance document on analytical quality control and method validation procedures for pesticides residues analysis in food and feed. SANTE/11945/2015. last accessed: 25-03-2016 http://ec.europa.eu/food/plant/docs/plant_pesticides_mrl_guidelines_wrkdoc_11945_en.pdf Sprong, R. C., de Wit-Bos, L., te Biesebeek, J. D., Alewijn, M., Lopez, P., & Mengelers, M. J. B. (2015). A mycotoxin-dedicated total diet study in the Netherlands in 2013: Part III – exposure and risk assessment World Mycotoxin Journal. Walravens, J., Mikula, H., Rychlik, M., Asam, S., Ediage, E. N., Di Mavungu, J. D., Van Landschoot, A., Vanhaecke, L., & De Saeger, S. (2014a). Development and validation of an ultra-high-performance liquid chromatography tandem mass spectrometric method for the simultaneous determination of free and conjugated Alternaria toxins in cereal-based foodstuffs. Journal of Chromatography A, 1372, 91101. Walravens, J., Mikula, H., Rychlik, M., Asam, S., Ediage, E. N., di Mavungu, J. D., Van Landschoot, A., Vanhaecke, L., & de Saeger, S. (2014b). Occurrence of (masked) Alternaria toxins - A survey in foodstuffs commercially available on the Belgian market. In 8th Conference of the World Mycotoxin Forum. Vienna, Austria. Zhao, K., Shao, B., Yang, D., & Li, F. (2015). Natural occurrence of four alternaria mycotoxins in tomato- and citrus-based foods in China. Journal of Agricultural and Food Chemistry, 63(1), 343-348.
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Table 1. Retention times, the ionisation mode, declustering potential (DP), collision
383
energy (CE), collision cell exit potential (CXP) and the precursor and product ions for
384
the targeted Alternaria toxins and conjugates. ESI mode
RT
Transition
(min) 6.8
TeA
Negative
7.4
AOH
Negative
8.1
TEN
Negative
8.1
AME
Negative
9.3
Positive
6.9
Positive
7.0
Positive
8.0
Positive
6.4
Positive
8.3
AOH-9glucoside
glucoside AME-3glucoside
AME-3-
AME-3-sulfate
(V)
293.1>257.0 56
20
10
293.1>239.1 60
30
10
196.0>112.0 -35
-20
-11
196.0>139.0 -35
-20
-11
257.0>215.0 -5
-30
-15
257.0>213.0 -5
-26
-15
413.0>141.0 -60
-26
-11
-22
-17
271.0>256.0 -90
-32
-13
271.0>227.0 -90
-50
-9
421.0>259.0 186
25
18
421.0>213.0 186
63
14
421.0>259.0 186
25
18
421.0>213.0 186
63
14
435.0>273.0 126
33
18
452.0>273.0 126
33
18
583.0>259.0 121
49
18
583.0>421.0 121
15
30
521.0>273.0 121
19
18
Negative
337.0>257.0 -190
-10
-34
Positive
339.0>259.0 120
33
18
Negative
351.0>271.0 -170
-10
-42
Positive
353.0>273.0 230
33
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malonylglucoside AOH-3-sulfate
(V)
413.0>271.0 -60
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AOH-9diglucoside
(V)
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AOH-3-
CXP
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Positive
CE
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Mycotoxin
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Table 2. Occurrence of Alternaria toxins (µg/kg) in sunflower seeds, sunflower paste, sunflower oil and figs in the current survey Product
Toxin
# above LOQ
Sunflower seeds
AOH
(N=10)
Concentration (µg kg-1) Range
a
1 (10%)
<2.0-36
5.4
AME
1 (10%)
<1.0-1.7
1.1
1.0
TeA
8 (80%)
<5.0-1,350 240
95
ALT
0
<1.5
TEN
0
<2.5
Sunflower paste
AOH
0
<2.0
(N=3)
AME
0
<1.0
TeA
0
<5.0
ALT
0
TEN
0
Sunflower oil
AOH
0
(N=11)
AME
1 (9%)
<1.0-17
TeA
0
<5.0
ALT
0
TEN
0
<2.5
Figs
AOH
1(7%)
<2.0-8.7
(N=14)
AME
0
<1.0
TeA
14 (100%)
41-1,728
ALT
0
<1.5
TEN
0
<2.5
Median
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2.0
<2.5
<2.0
2.5
1.0
2.5
2.0
473
316
<1.5
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<1.5
Based on upper bound conditions. If concentration was between LOD and LOQ, then for the
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Table 3. Occurrence of Alternaria toxins (µg/kg) in tomato products from the current survey Tomato product
Toxin
# above LOQ
All tomato products
AOH
(N=43)
Concentration (µg/kg) Range
a
16 (37%)
<2.0-26
4.8
AME
4 (9%)
<1.0-5.6
TeA
26 (60%)
<5.0-344
ALT
0
<1.5
TEN
0
<2.5
Tomato sauces
AOH
3 (33%)
<2.0-16
4.0
2.0
(N=9)
AME
2 (22%)
<1.0-1.6
1.1
1.0
TeA
7 (78%)
<5.0-111
41
37
Tomato pastes
AOH
3 (60%)
<2.0-26
8.1
3.8
(N=5)
AME
1 (20%)
<1.0-5.6
1.9
1.0
TeA
4 (80%)
<5.0-344
131
111
Tomato ketchup
AOH
3 (60%)
<2.0-18
7.2
6.7
(N=5)
AME
1 (20%)
<1.0-5.6
1.9
1.0
Tomato pieces (sieved, cubes) a
Median
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2.0 1.0
63
36
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1.2
2 (40%)
<5.0-138
44
5.0
AOH
4 (28%)
<2.0-11
3.3
2.0
TeA
7 (50%)
<5.0-220
77
50
AOH
3 (30%)
<2.0-15
4.7
2.0
6 (60%)
<5.0-100
38
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chopped, TeA
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(N=14)
a
TeA
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Tomato juices
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Mean
Based on upper bound conditions. If concentration was between LOD and LOQ, then for the
level was equalled to LOQ. If concentration
15
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FIGURE CAPTIONS Figure 1. Chemical structure of the glucosides conjugates of alternariol (a) and alternariol methyl ether (b). Figure 2. Chromatography of a standard containing the AOH and AME conjugates at 25
D-glucopyranoside;
3:
AOH-3-O-β-D-glucopyranoside;
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ng/mL (1: AOH-9-O-β-D-glucopyranosyl-(6’→1’’)-β-D-glucopyranoside; 2: AOH-9-O-β4:
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glucopyranoside; 5: AME-3-O-(6’-O-malonyl-β-D-glucopyranoside).
16
AME-3-O-β-D-
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HIGHLIGHTS
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•
Tenuazonic acid (TeA) occurs at high levels in sunflower seeds and dried figs in 2014. Processing of sunflower seeds to obtain oil or paste may degrade TeA. Alternariol (AOH), alternariol methyl ether (AME) and TeA occur in tomato products. The consumption of high amounts of tomato products may pose a risk for health in the Netherlands. Conjugates of Alternaria toxins could not be found at levels higher than 2.5 µg/kg.
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• • • •
S0956-7135(16)30170-0
DOI:
10.1016/j.foodcont.2016.04.001
Reference:
JFCO 4960
To appear in:
Food Control
Received Date: 21 February 2016 Revised Date:
27 March 2016
Accepted Date: 1 April 2016
Please cite this article as: López P., Venema D., Mol H., Spanjer M., de Stoppelaar J., Pfeiffer E. & de Nijs M., Alternaria toxins and conjugates in selected foods in the Netherlands, Food Control (2016), doi: 10.1016/j.foodcont.2016.04.001. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Alternaria toxins and conjugates in selected foods in the Netherlands.
2
Patricia Lópeza*, Dini Venemaa, Hans Mola, Martien Spanjerb, Joyce de Stoppelaarb, Erika
3
Pfeifferc, Monique de Nijsa
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6
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RIKILT – Wageningen UR, Akkermaalsbos 2, 6708 WB, Wageningen, The Netherlands
b
NVWA – Netherlands Food and Consumer Product Safety Authority, Catherijnesingel 59,
7 8 9
3511 GG Utrecht, The Netherlands
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c
Institute of Applied Biosciences, Department of Food Chemistry and Phytochemistry,
Karlsruhe Institute of Technology (KIT), Adenauerring 20a, 76131 Karlsruhe, Germany
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*
Corresponding author: [email protected]
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ABSTRACT
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A survey on Alternaria toxins in the food categories dried figs (n=14), sunflower products
18
(n=24) and tomato products (n=43) was carried out in the Netherlands on samples collected in
19
retail stores in autumn 2014.
20
The occurrence data from this survey confirmed the previously reported data of a pilot survey
21
in 2013, with tenuazonic acid being an ubiquitous Alternaria toxin in dried figs (100% of the
22
samples), sunflower seeds (80% of the samples) and tomato products (60% of samples) at
23
relatively high concentrations, up to 1,728 µg/kg in dried figs and 1,350 µg/kg in sunflower
24
seeds. Despite the occurring of high concentrations of tenuazonic acid in sunflower seeds and
25
figs, it is unlikely that the population in the Netherlands is exposed to levels of concern.
26
Alternariol was detected in 27% of the tomato products ranging from LOQ (2 µg/kg) up to 26
27
µg/kg, while alternariol monomethyl ether was present in 7% of the tomato products. In the
28
worst case situation, consumption of these products may result in exposure at levels above the
29
threshold of toxicological concern of 2.5 ng/kg body weight/day for alternariol. None of seven
30
conjugates of Alternaria toxins was detected above the limit of quantification (LOQ) of 2.5
31
µg/kg.
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Keywords: Alternaria toxins, conjugates, dried figs, sunflower, tomato processed products.
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1.
INTRODUCTION
38
Alternaria toxins are mycotoxins produced by Alternaria species, pathogenic and saprophytic
39
fungi widely distributed in soil. Alternaria species have been reported to occur in cereals
40
(mainly in wheat, sorghum and barley), oilseeds, such as sunflower and rapeseed, tomatoes,
41
apples, citrus fruits, olives and several other fruits and vegetables (EFSA, 2011). They grow
42
at low temperature; hence they are generally associated with extensive spoilage during
43
refrigerated transport and storage (Ostry, 2008).
44
Alternaria species can produce more than 70 secondary metabolites, but only a small
45
proportion of them have been chemically characterized and reported as toxic to humans and
46
animals (Barkai-Golan, 2008). However, there are currently no harmonised legal limits for
47
Alternaria toxins in food products in the EU. The European Food Safety Authority (EFSA)
48
published their opinion in 2011 on the risks for animal and public health related to the
49
presence of Alternaria toxins in feed and food (EFSA, 2011). EFSA evidenced a lack of
50
robust occurrence data of Alternaria toxins in food and processed products, and recommended
51
the collection of representative data across Europe. Following this conclusion, the Scientific
52
Committee on the Food Chain and Animal Health identified the following five toxins of
53
concern for human health: alternariol (AOH), alternariol monomethyl ether (AME),
54
tenuazonic acid (TeA), tentoxin (TEN) and altenuene (ALT). Other groups of Alternaria
55
toxins, such as altertoxins (ATX) and Alternaria alternate f. sp. lycopersici toxins (AAL
56
toxins), were deemed to be of less relevance (Standard Committee on the Food Chain and
57
Animal Health, 2012).
58
In their opinion, EFSA stated that the risk for public health related to these mycotoxins is not
59
expected to result from acute toxicity (EFSA, 2011). However, although AOH and AME
60
showed no strong acute toxic effects, they could induce fetotoxic and teratogenic effects
61
(EFSA, 2011). AOH, AME and especially ATX II showed genotoxic effects in cultured
62
mammalian cells (Fleck, Burkhardt, Pfeiffer, & Metzler, 2012). As the toxicity data were not
63
sufficient for identification of reference points for different toxicological effects, EFSA
64
decided to use the threshold of toxicological concern (TTC) approach to assess the relative
65
level of concern for dietary exposure of humans. For AOH and AME the TTC value of 2.5
66
ng/kg b.w./day was applied, for TEN and TeA the TTC value of 1500 ng/kg b.w./day (EFSA,
67
2011). In their risk assessment, the estimated chronic dietary exposure to AOH and AME
68
exceeded the TTC value, which emphasized the need for more additional data on the toxicity
69
of Alternaria toxins (EFSA, 2011).
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In response to the EFSA recommendation on the need for more data on the occurrence of
71
Alternaria toxins, a survey was conducted in 2013 in the Netherlands, on 95 retail products
72
classified in 10 different food categories, to identify the food groups of concern (López, et al.,
73
2016). The results from that survey showed that TeA occurred in 27% of the samples and at
74
highest concentrations in sunflower seeds, tomato sauces and dried figs. The prevalence of the
75
other Alternaria toxins (AOH, AME, TEN and ALT) was low in all food groups. It was
76
concluded that more occurrence data on each specific type of product were necessary for a
77
proper evaluation of the occurrence of Alternaria toxins (e.g. annual variations) and for the
78
exposure of the Dutch consumers to TeA through the consumption of these products.
79
The possible occurrence of conjugated or “masked” Alternaria toxins, in which the mycotoxin
80
is bound to a more polar substance like glucose or sulfate, has been pointed out (Ostry, 2008).
81
Conjugates of Alternaria toxins may be of relevance to exposure, as they may release the
82
native mycotoxin after hydrolysis in the human digestive tract. Hildebrand et al. have recently
83
identified five β-D-glucopyranosides and a 6’-malonyl-β-D-glucopyranoside of AOH, as well
84
as a D-glucopyranoside and 6’- and 4’-malony-β-D-glucopyranosides of AME in tobacco
85
suspension cells (Hildebrand, et al., 2015). The same authors observed that in plant cells
86
AME glucosides underwent malonyl conjugation, whereas AOH glucosides underwent
87
glucosylation (Hildebrand, et al., 2015). AOH and AME sulfate conjugates were detected in
88
tomato products and glucoside conjugates in sesame seeds in a survey performed in Belgium
89
(Walravens, et al., 2014b).
90
This work describes the results from a survey carried out in 2014 in the Netherlands for the
91
occurrence of five Alternaria toxins (AOH, AME, TeA, TEN and ALT) in tomato products,
92
sunflower products and dried figs. These products were identified as vulnerable to
93
contamination with Alternaria toxins in a pilot study. The potential presence of seven
94
conjugate forms of AOH and AME, i.e. AOH-9-glucoside (AOH9G), AOH-3-glucoside
95
(AOH3G), AOH-9-diglucoside (AOH9DG), AOH-3-sulfate (AOH3S), AME-3-glucoside
96
(AME3G), AME-3-malonylglucoside (AME3MG) and AME-3-sulfate (AME3S) was also
97
monitored.
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98 99
2.
MATERIALS AND METHODS
100 101
2.1. Chemicals and reagents
102
Acetonitrile and methanol, both UPLC grade, were purchased from Actu-all Chemicals (Oss,
103
the Netherlands), formic acid (98–100%) from Merck (Amsterdam, the Netherlands), and 4
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ammonium formate (99%) from Across Organics (Geel, Belgium). MilliQ water (>18MΩ)
105
was used (Millipore, Bedford, MA, USA). AOH and AME were purchased from Biosolve
106
(Greyhound Chromatography and Allied Chemicals, Merseyside, UK). TeA, TEN and ALT
107
were supplied by Sigma-Aldrich (Zwijndrecht, the Netherlands). All standards had a purity
108
higher than 99%. Individual stock solutions of each mycotoxin at 100 µg/mL in acetonitrile
109
and in methanol for TeA were prepared. A solution of ALT of 1 mg/mL was provided by the
110
Chemistry laboratory of the Netherlands Food and Consumer Product Safety Authority. A
111
mixture working solution containing AOH, AME, ALT and TEN at 1 µg/mL and TeA at 5
112
µg/mL in acetonitrile was prepared.
113
standard.
114
The AOH and AME conjugates (AOH9G, AOH3G, AOH9DG, AME3G, AME3MG) were
115
isolated and provided by the Institute of Applied Bioscience (Karlsruhe Institute of
116
Technology, Germany). Figure 1 shows the structure of these conjugates. A mix stock
117
solution containing the conjugates in concentrations ranging from 0.8 to 2 µg/mL was
118
prepared in methanol.
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C-Caffeine (Sigma-Aldrich) was used as internal
119
2.2. Samples
121
A total of 81 samples was purchased from retail stores in the Netherlands in the autumn of
122
2014. The samples covered the food categories dried figs (n=14), processed tomato products
123
(15 tomato juices, 13 tomato sauces, 5 tomato ketchups and 10 other processed tomato
124
samples) and sunflower products (11 sunflower oils, 3 sunflower pastes and 10 roasted
125
shelled sunflower seed samples). The samples were stored at the temperature recommended
126
on the label until processing. Sunflower paste and sunflower oil were stored as such at room
127
temperature. Processed tomato samples were homogenized and stored at -20 °C. Dried figs
128
and sunflower seeds were homogenized by milling and mixing with water to form a slurry.
129
The water content in ratio was 1:3 for dried figs and 1:4 for sunflower seeds.
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2.3. Method
132
An aliquot of 2.5 g of tomatoes, sunflower oil or sunflower pasta were weighed, spiked with
133
12.5 µL of internal standard (13C-caffeine at 10 µg/mL) and extracted with 10 mL of
134
acetonitrile/water (84/16, v/v) acidified with 1% of acetic acid. 10 g of the slurry of figs and
135
12.5 g of the slurry of sunflower seeds were weighed, spiked with 12.5 µL of internal
136
standard (13C-caffeine at 10 µg/mL) and extracted with 10 mL of acetonitrile containing 1%
137
of acetic acid. Samples were shaken for two hours at 250 rpm and then centrifuged for 10 min 5
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at 3,000 rpm. The extracts were filtered in mini-uniprep PTFE filter vials and analysed by
139
LC-MS/MS.
140
The LC-MS/MS instrument was a Shimadzu ‘Prominence’ HPLC system (Shimadzu Europa
141
GmbH, Duisburg, Germany), which consisted of a DGU-20A3 degasser, a SIL 20AC XR
142
autosampler, two LC-20 AD XR UFLC pumps, and a CTO-20AC column oven. This system
143
was coupled to an AB SCIEX QTRAP® 5500 mass spectrometer (AB Sciex Netherlands
144
B.V., Nieuwerkerk aan den Ijssel, The Netherlands).
145
HPLC separation was performed by injecting 5 µL of the extract into a Waters Atlantis HSS-
146
T3, (3µm), 3.0 x 100 mm column (Waters, Milford, MA, USA). The chromatographic
147
conditions were as follows: column temperature 35 °C; mobile phases consisting of water as
148
eluent A and 4% (v/v) water in methanol as eluent B. Both mobile phases contained 1 mM of
149
ammonium formate and 1% of formic acid. The flow rate was set at 0.4 mL/min. A gradient
150
elution was applied as follows: after an initial hold time of 1 min at 100% eluent A, 50%
151
eluent B was reached within 2 min, which was kept for 1 min, and 100% eluent B within the
152
next 5 min. This composition was kept for 2 min, after which 100% eluent A was reached
153
within the next 0.5 min and kept for 4.5 min for column re-equilibration. The gradient used
154
before (López, et al., 2016) was slightly modified to allow the determination of the
155
conjugates.
156
The analysis of the samples was carried out using electrospray ionisation (ESI) and multiple
157
reaction monitoring (MRM). The precursor and product ion transitions for the five Alternaria
158
toxins were the same as previously used. The determination of the precursor and parent ion
159
for the Alternaria toxin glucoside conjugates was carried out by infusion of a solution
160
containing the mixed conjugate standard. Optimization was conducted in both positive and
161
negative ionisation modes. The transitions of the Alternaria toxin sulfate-conjugates were also
162
monitored. Their transitions were taken from literature (Walravens, et al., 2014a). Table 1
163
summarizes the retention times (RTs) and the applied values for fragmentation voltages and
164
collision.
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2.4. Sample analysis
167
The Alternaria toxins in the samples were quantified by standard addition. The addition was
168
10 µg/kg of AOH, AME, TEN and ALT and 50 µg/kg of TeA. If necessary, the addition was
169
repeated at higher levels (equivalent to 50 µg/kg for AOH, AME, TEN and ALT and 250
170
µg/kg for TeA) and/or the extracts diluted. Quality control samples for each matrix under
171
study were included in each analytical series. 6
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Recoveries for quality controls fell between 50-60% for each toxin in sunflower products, and
173
between 80-120% for each toxin in tomato products and dried figs. As the standard addition
174
procedure already takes into account the losses due to extraction and matrix effects in the LC-
175
MS/MS instrument, the results were not corrected for recovery.
176
The LOQs for each Alternaria toxin were estimated in previous work (López, et al., 2016) as
177
the concentration in a spiked sample, for which the signal-to-noise (S/N) ratio of the
178
quantifier ion was equal to ten, providing that the signal of the qualifier ion was equal to
179
three. The LOQs were 1.5 µg/kg for ALT, 2.0 µg/kg for AOH, 1.0 µg/kg for AME, 2.5 µg/kg
180
for TEN y 5.0 µg/kg for TeA.
181
The Alternaria toxins and conjugates were identified by similarity of retention times and ion
182
ratios between the compounds in the sample extract and the standards in the matrix. The
183
criteria used to ensure the correct identification of the target mycotoxins were according to
184
SANTE guidelines (SANTE, 2015): (a) the retention times of the analyte in the sample extract
185
matched those of spiked sample extract within a deviation of ±0.2 min; (b) the deviation of
186
the ion ratio of the sample extract fell within ±30% of the ion ratio for the spiked sample
187
extract.
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188
2.5. Data treatment
190
Non-detects for calculation purposes were treated with the substitution method (EFSA, 2010).
191
In this study, the upper bound was followed, which means that results below LOD were
192
equalled to LOD and results between LOD and LOQ were equalled to LOQ.
193 194 195
3.
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RESULTS AND DISCUSSION
3.1. Optimization of the instrumental method for Alternaria toxin conjugates
197
Seven Alternaria toxin conjugates were included in the LC-MS/MS method as published by
198
Lopez et al. (López, et al., 2016). Their behaviour as regards separation and fragmentation
199
was studied for the conditions described in the materials and method section. Under those
200
conditions, the elution order of the Alternaria toxin conjugates is shown in Figure 2. The
201
AOH and AME conjugates eluted according to their decreasing polarity: AOH9DG, AOH9G,
202
AOH3G, AME3G and AME3MG.
203
The protonated molecule of AOH glucosides ([M + H]+ m/z 421) lost the hexose group during
204
fragmentation to produce the fragment m/z 259 [AOH + H]+, which in turn lost formic acid to
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form the fragment m/z 213. The fragmentation of the diglucoside conjugate of AOH ([M +
206
H]+ m/z 583) resulted in the sequential loss of two hexose moieties (162) to yield the product
207
ions m/z 421 ([glucoside + H]+ and m/z 259 [AOH + H]+.
208
Two different parent ions were chosen to detect AME3G, the protonated molecule [M + H]+
209
m/z 435 and the ammonium adduct [M+NH4]+ m/z 452. Both transitions provided the same
210
product ion [AME + H]+ m/z 273. For AME3MG only one transition was detectable, which
211
consisted of the loss of the malonylglucoside group to give the fragment [AME + H]+ m/z
212
273.
213
The transitions detected in this work were in agreement with those found when these
214
glucosides conjugates were first elucidated and detected in tobacco cells (Hildebrand, et al.,
215
2015). Walravens et al. (Walravens, et al., 2014a) analysed the AOH and AME conjugates
216
with negative electrospray ionization. The parent ion was for both Alternaria toxins the
217
deprotonated molecule [M – H]- and the resulting product ions were the deprotonated toxin,
218
either [AME –H]- or [AOH – H]-, and the deprotonated toxin with a loss of formic acid
219
moiety. Negative ionization was also assessed, but sensitivity was lower compared to positive
220
mode.
221
The method was not validated for the analysis of Alternaria toxin conjugates, due to the
222
limited amounts of standards available. Therefore, an LOQ of 2.5 µg/kg for the Alternaria
223
toxin conjugates was derived from the signal-to-noise ratio of injected standards in solvent.
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3.2. Occurrence of Alternaria toxins and their conjugates in the selected products
226
The results of the survey of Alternaria toxins and their conjugates in the 81 samples are
227
summarized in table 2 and table 3. Detailed information on the occurrence of Alternaria
228
toxins and their conjugates in each sample is presented in Supplementary Information SS1.
229
As described previously (López, et al., 2016), TeA was the most prevalent toxin, being
230
present in this study in 100% of dried figs, 80% of sunflower seeds and 60% of tomato
231
products.
232
TeA was the main Alternaria toxin in sunflower seeds, ranging from LOQ to 1,350 µg/kg.
233
AOH and AME were detected in one sample. These findings differed from reports by other
234
authors in which AOH, AME and TEN were present in this food commodity (EFSA, 2011;
235
Hickert, Bergmann, Ersen, Cramer, & Humpf, 2015). The processing of sunflower seeds
236
might have resulted in a reduction of TeA, since it was detected neither in sunflower oil nor in
237
sunflower paste samples in the present study. Sunflower oil is produced by pressing of seeds
238
and/or solvent extraction. Solvent extraction with organic solvent was proven to enhance in
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particular the transfer of AME to oil, whereas TeA was hardly transferred to the oil (Chulze,
240
et al., 1995). Sunflower paste is produced by hardening (hydrogenation) of sunflower oil.
241
The results obtained for dried figs in the present survey confirmed the previous findings: all
242
analysed samples contained TeA at relatively high levels ranging from 81 to 1,728 µg/kg.
243
Despite the high levels of Alternaria toxins detected in sunflower seeds or figs in this study,
244
their consumption does not pose a risk for the health of the population in the Netherlands. In
245
the worst case scenario, a 70-kg person would need to eat more than 77 g of sunflower seeds
246
contaminated with 1,350 µg/kg of TeA, or 60 g of dried figs contaminated with 1,728 µg/kg
247
of TeA to exceed the level of concern (TTC) of 1,500 ng/kg b.w./day for TeA on routine basis
248
(77 g x 1,350 ng/g / 70 kg b.w. = 1485 ng/kg b.w./day of TeA).
249
TeA was the main Alternaria toxin detected in tomato products ranging from 5.0 to 344 µg/kg
250
(60% of samples), followed by AOH (27% of samples) and AME (7%). AME only occurred
251
in tomato paste, tomato sauces and ketchup samples, but not in tomato juices or processed
252
tomato pieces. The highest concentrations of TeA were found in tomato pastes (60%, ranging
253
from LOQ to 344 µg/kg) followed by tomato juices and tomato ketchup. These results are in
254
agreement with the results in the study by Noser et al. in products on the market in
255
Switzerland (Noser, Schneider, Rother, & Schmutz, 2011), but differed from the survey by
256
Zhao in China (Zhao, Shao, Yang, & Li, 2015), where tomato ketchup samples contained the
257
highest levels of TeA. The levels of AOH and AME were similar to previous studies (Hickert,
258
et al., 2015; López, et al., 2016; Noser, et al., 2011; Zhao, et al., 2015). The fact that TeA was
259
found at lower levels in tomato products containing whole tomato pieces may indicate that the
260
quality of the ingredients used for producing tomato pastes, tomato purees and tomato juices
261
might be an issue. No significant correlations between AOH and AME (r2 = 0.42) or AOH
262
and TeA (r2 = 0.39) were found in tomato samples. This may be due to the contamination of
263
the raw material with different Alternaria strains with variations in their biosynthetic profile
264
or the selective degradation of certain compounds during food processing (Hickert, et al.,
265
2015).
266
The levels of AOH and AME found in tomato products indicated that high consumption of
267
these products may pose a health risk for the population in the Netherlands since the daily
268
intake may exceed the TTC level of 2.5 ng/kg b.w./day. In the worst case scenario, the intake
269
of AOH would be above the threshold if a 70-kg person consumed 7 g of tomato paste
270
contaminated with 26 µg/kg of AOH (7 x 26 / 70 = 2.6 ng/kg b.w./day) or 10 g of tomato
271
ketchup contaminated with 18 µg/kg o1f AOH (10 x 18 / 70 = 2.6 ng/kg b.w./day). These data
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are in agreement with the risk assessment carried out in the Netherlands in 2013 (Sprong, et
273
al., 2015), which revealed that tomato products were one of the main contributors to the
274
exposure to Alternaria toxins and concluded that health risk based on the TTC approach for
275
AME or AOH could not be ruled out.
276
Masked mycotoxins or mycotoxin conjugates can be formed during food processing. None of
277
the seven Alternaria toxin conjugates were detected in the 81 samples in the current survey.
278
The presence of other mycotoxin conjugates in foodstuffs have been reported for
279
deoxynivalenol (DON) (3-acetylDON, 15-acetylDON and DON-3-glucoside), zearalenone,
280
fumonisins, ochratoxin A (Berthiller, et al., 2013) and HT-2 and T-2 toxins (Lattanzio, et al.,
281
2015). In case of DON and DON-3-glucoside, the ratio of occurrence may be quite stable,
282
although it can vary depending on the year and the plant genotype (Berthiller, et al., 2013).
283
Alternaria toxins sulphate conjugates have been only reported to occur in tomato products and
284
sesame seeds (Walravens, et al., 2014b). These authors detected AOH3S and AME3S in 23%
285
and 41% of tomato juice samples, in 14% and 27% of tomato sauces and in 33% and 76% of
286
tomato pastes, respectively, and co-occurring with AOH and AME. However, the authors did
287
not provide information on the occurrence of Alternaria toxins and conjugates in the
288
individual samples, and therefore a ratio between conjugated and non-conjugated forms, as
289
carried out for DON-3-glucoside and DON (Janssen, Sprong, Wester, De Boevre, &
290
Mengelers, 2015), could not be estimated. Taking into account the occurrence of AOH and
291
AME in the present study and the maximum concentration of AOH, AME and conjugates,
292
reported by Walravens, it is unlikely that AME3S would have been detected in the tomato
293
products in this study. However, AOH3S might have been detected in tomato pastes and/or
294
sauces at values close to the LOQ (2.5 µg/kg). Nevertheless, only the availability of high
295
quality commercial standards would allow a more accurate quantification on the occurrence
296
of Alternaria toxin conjugates.
297
The results of this survey and the previous survey (López, et al., 2016) indicate that
298
contamination of sunflower seeds, sunflower seed products and tomato products available on
299
the retail market in the Netherlands with Alternaria toxins seem to be relatively constant over
300
the years 2013-2104.
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CONCLUSIONS
304
The study reported in this paper showed that TeA was present at relatively high
305
concentrations in tomato products, in dried figs and sunflower oils available in retail market in 10
ACCEPTED MANUSCRIPT
the Netherlands in 2014. Due to its hydrophilic properties, TeA seems to be lost during the
307
processing of seeds to obtain oil and/or sunflower paste. The data from this survey confirm
308
the results from a previous study in 2013 and indicate that in the Netherlands contamination
309
of sunflower seeds, dried figs and tomato products with Alternaria toxins seems to be
310
relatively constant over the years 2013-2104. The seven conjugated forms of AOH and AME
311
(sulfates and glucosides) were not detected in any of the samples.
312
The results showed that a risk to the health of consumers of high amounts of tomato products
313
in the Netherlands cannot be excluded. It is, therefore, advisable to monitor occurrence of
314
Alternaria toxins at least in these mentioned food categories.
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ACKNOWLEDGMENTS
317
The authors gratefully acknowledge Alwin Kruijt, Food Safety Laboratory of the Netherlands
318
Food and Consumer Product Safety Authority, for kindly providing the altenuene standards,
319
Manfred Metzler and Ron Hoogenboom for the fruitful discussions. This study was carried
320
out in WOT project-02-001-061 ‘Method development and surveys on mycotoxins in food’ at
321
RIKILT Wageningen UR, on behalf of and funded by the Netherlands Ministry of Economic
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Affairs.
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REFERENCES
325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355
Barkai-Golan, R. (2008). Alternaria Mycotoxins. In R. B.-G. a. N. Paster (Ed.), Mycotoxins in fruits and vegetables. San Diego, CA, USA: Elsevier. Berthiller, F., Crews, C., Dall'Asta, C., De Saeger, S., Haesaert, G., Karlovsky, P., Oswald, I. P., Seefelder, W., Speijers, G., & Stroka, J. (2013). Masked mycotoxins: A review. Molecular Nutrition & Food Research, 57(1), 165-186. Chulze, S. N., Torres, A. M., Dalcero, A. M., Etcheverry, M. G., Ramirez, M. L., & Farnochi, M. C. (1995). Alternaria mycotoxins in sunflower seeds: Incidence and distribution of the toxins in oil and meal. Journal of Food Protection, 58(10), 1133-1135.
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Summary report of the Standing Committe on the food chain and animal health (section Toxicological Safety of the food chain), held in Brussels on 29 May 2012. Alternaria toxins. EFSA. (2011). Scientific Opinion on the risks for animal and public health related to the presence of Alternaria toxins in feed and food EFSA Journal, 9(10), 97. EFSA (2010). Management of left-censored data in dietary exposure assessment of chemical substances. EFSA Journal 8(3) 1557. Fleck, S. C., Burkhardt, B., Pfeiffer, E., & Metzler, M. (2012). Alternaria toxins: Altertoxin II is a much stronger mutagen and DNA strand breaking mycotoxin than alternariol and its methyl ether in cultured mammalian cells. Toxicology Letters, 214(1), 27-32. Hickert, S., Bergmann, M., Ersen, S., Cramer, B., & Humpf, H.-U. (2015). Survey of Alternaria toxin contamination in food from the German market, using a rapid HPLC-MS/MS approach. Mycotoxin research, 1-12. Hildebrand, A. A., Kohn, B. N., Pfeiffer, E., Wefers, D., Metzler, M., & Bunzel, M. (2015). Conjugation of the Mycotoxins Alternariol and Alternariol Monomethyl Ether in Tobacco Suspension Cells. Journal of Agricultural and Food Chemistry, 63(19), 4728-4736. Janssen, E. M., Sprong, R. C., Wester, P. W., De Boevre, M., & Mengelers, M. J. B. (2015). Risk assessment of chronic dietary exposure to the conjugated mycotoxin deoxynivalenol-3-β-glucoside in the Dutch population World Mycotoxin Journal, 8(5), 561-572. Lattanzio, V. M. T., Ciasca, B., Terzi, V., Ghizzoni, R., McCormick, S. P., & Pascale, M. (2015). Study of the natural occurrence of T-2 and HT-2 toxins and their glucosyl derivatives from field barley to malt by high-resolution Orbitrap mass spectrometry. Food Additives and Contaminants Part a-Chemistry Analysis Control Exposure & Risk Assessment, 32(10), 1647-1655.
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López, P., Venema, D., de Rijk, T., de Kok, A., Scholten, J. M., Mol, H. G. J., & de Nijs, M. (2016). Occurrence of Alternaria toxins in food products in The Netherlands. Food Control, 60, 196-204. Noser, J., Schneider, P., Rother, M., & Schmutz, H. (2011). Determination of six Alternaria toxins with UPLCMS/MS and their occurrence in tomatoes and tomato products from the Swiss market. Mycotoxin research, 27(4), 265-271. Ostry, V. (2008). Alternaria mycotoxins: an overview of chemical characterization, producers, toxicity, analysis and occurrence in foodstuffs. World Mycotoxin Journal, 1(2), 175-188. SANTE (2015). Guidance document on analytical quality control and method validation procedures for pesticides residues analysis in food and feed. SANTE/11945/2015. last accessed: 25-03-2016 http://ec.europa.eu/food/plant/docs/plant_pesticides_mrl_guidelines_wrkdoc_11945_en.pdf Sprong, R. C., de Wit-Bos, L., te Biesebeek, J. D., Alewijn, M., Lopez, P., & Mengelers, M. J. B. (2015). A mycotoxin-dedicated total diet study in the Netherlands in 2013: Part III – exposure and risk assessment World Mycotoxin Journal. Walravens, J., Mikula, H., Rychlik, M., Asam, S., Ediage, E. N., Di Mavungu, J. D., Van Landschoot, A., Vanhaecke, L., & De Saeger, S. (2014a). Development and validation of an ultra-high-performance liquid chromatography tandem mass spectrometric method for the simultaneous determination of free and conjugated Alternaria toxins in cereal-based foodstuffs. Journal of Chromatography A, 1372, 91101. Walravens, J., Mikula, H., Rychlik, M., Asam, S., Ediage, E. N., di Mavungu, J. D., Van Landschoot, A., Vanhaecke, L., & de Saeger, S. (2014b). Occurrence of (masked) Alternaria toxins - A survey in foodstuffs commercially available on the Belgian market. In 8th Conference of the World Mycotoxin Forum. Vienna, Austria. Zhao, K., Shao, B., Yang, D., & Li, F. (2015). Natural occurrence of four alternaria mycotoxins in tomato- and citrus-based foods in China. Journal of Agricultural and Food Chemistry, 63(1), 343-348.
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Table 1. Retention times, the ionisation mode, declustering potential (DP), collision
383
energy (CE), collision cell exit potential (CXP) and the precursor and product ions for
384
the targeted Alternaria toxins and conjugates. ESI mode
RT
Transition
(min) 6.8
TeA
Negative
7.4
AOH
Negative
8.1
TEN
Negative
8.1
AME
Negative
9.3
Positive
6.9
Positive
7.0
Positive
8.0
Positive
6.4
Positive
8.3
AOH-9glucoside
glucoside AME-3glucoside
AME-3-
AME-3-sulfate
(V)
293.1>257.0 56
20
10
293.1>239.1 60
30
10
196.0>112.0 -35
-20
-11
196.0>139.0 -35
-20
-11
257.0>215.0 -5
-30
-15
257.0>213.0 -5
-26
-15
413.0>141.0 -60
-26
-11
-22
-17
271.0>256.0 -90
-32
-13
271.0>227.0 -90
-50
-9
421.0>259.0 186
25
18
421.0>213.0 186
63
14
421.0>259.0 186
25
18
421.0>213.0 186
63
14
435.0>273.0 126
33
18
452.0>273.0 126
33
18
583.0>259.0 121
49
18
583.0>421.0 121
15
30
521.0>273.0 121
19
18
Negative
337.0>257.0 -190
-10
-34
Positive
339.0>259.0 120
33
18
Negative
351.0>271.0 -170
-10
-42
Positive
353.0>273.0 230
33
13
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malonylglucoside AOH-3-sulfate
(V)
413.0>271.0 -60
EP
AOH-9diglucoside
(V)
TE D
AOH-3-
CXP
SC
Positive
CE
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DP
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Mycotoxin
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Table 2. Occurrence of Alternaria toxins (µg/kg) in sunflower seeds, sunflower paste, sunflower oil and figs in the current survey Product
Toxin
# above LOQ
Sunflower seeds
AOH
(N=10)
Concentration (µg kg-1) Range
a
1 (10%)
<2.0-36
5.4
AME
1 (10%)
<1.0-1.7
1.1
1.0
TeA
8 (80%)
<5.0-1,350 240
95
ALT
0
<1.5
TEN
0
<2.5
Sunflower paste
AOH
0
<2.0
(N=3)
AME
0
<1.0
TeA
0
<5.0
ALT
0
TEN
0
Sunflower oil
AOH
0
(N=11)
AME
1 (9%)
<1.0-17
TeA
0
<5.0
ALT
0
TEN
0
<2.5
Figs
AOH
1(7%)
<2.0-8.7
(N=14)
AME
0
<1.0
TeA
14 (100%)
41-1,728
ALT
0
<1.5
TEN
0
<2.5
Median
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2.0
<2.5
<2.0
2.5
1.0
2.5
2.0
473
316
<1.5
TE D
EP
a
<1.5
Based on upper bound conditions. If concentration was between LOD and LOQ, then for the
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Mean
level was equalled to LOQ. If concentration
14
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Table 3. Occurrence of Alternaria toxins (µg/kg) in tomato products from the current survey Tomato product
Toxin
# above LOQ
All tomato products
AOH
(N=43)
Concentration (µg/kg) Range
a
16 (37%)
<2.0-26
4.8
AME
4 (9%)
<1.0-5.6
TeA
26 (60%)
<5.0-344
ALT
0
<1.5
TEN
0
<2.5
Tomato sauces
AOH
3 (33%)
<2.0-16
4.0
2.0
(N=9)
AME
2 (22%)
<1.0-1.6
1.1
1.0
TeA
7 (78%)
<5.0-111
41
37
Tomato pastes
AOH
3 (60%)
<2.0-26
8.1
3.8
(N=5)
AME
1 (20%)
<1.0-5.6
1.9
1.0
TeA
4 (80%)
<5.0-344
131
111
Tomato ketchup
AOH
3 (60%)
<2.0-18
7.2
6.7
(N=5)
AME
1 (20%)
<1.0-5.6
1.9
1.0
Tomato pieces (sieved, cubes) a
Median
RI PT
2.0 1.0
63
36
SC
1.2
2 (40%)
<5.0-138
44
5.0
AOH
4 (28%)
<2.0-11
3.3
2.0
TeA
7 (50%)
<5.0-220
77
50
AOH
3 (30%)
<2.0-15
4.7
2.0
6 (60%)
<5.0-100
38
15
chopped, TeA
AC C
(N=10)
TE D
(N=14)
a
TeA
EP
Tomato juices
M AN U
Per category
Mean
Based on upper bound conditions. If concentration was between LOD and LOQ, then for the
level was equalled to LOQ. If concentration
15
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FIGURE CAPTIONS Figure 1. Chemical structure of the glucosides conjugates of alternariol (a) and alternariol methyl ether (b). Figure 2. Chromatography of a standard containing the AOH and AME conjugates at 25
D-glucopyranoside;
3:
AOH-3-O-β-D-glucopyranoside;
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ng/mL (1: AOH-9-O-β-D-glucopyranosyl-(6’→1’’)-β-D-glucopyranoside; 2: AOH-9-O-β4:
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glucopyranoside; 5: AME-3-O-(6’-O-malonyl-β-D-glucopyranoside).
16
AME-3-O-β-D-
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HIGHLIGHTS
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•
Tenuazonic acid (TeA) occurs at high levels in sunflower seeds and dried figs in 2014. Processing of sunflower seeds to obtain oil or paste may degrade TeA. Alternariol (AOH), alternariol methyl ether (AME) and TeA occur in tomato products. The consumption of high amounts of tomato products may pose a risk for health in the Netherlands. Conjugates of Alternaria toxins could not be found at levels higher than 2.5 µg/kg.
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• • • •