Mycoflora and mycotoxins natural occurrence in corn from entre rios province, Argentina

Corn samples were collected in 1999 from three departments of Entre Réos province, Argentina, and were surveyed for mould contamination and natural occurrence ofFusarium mycotoxins, ochratoxin A and aflatoxins.Fusarium verticillioides was the most prevalent fungal species recorded at all departments. Zearalenone, deoxynivalenol and ochratoxin A were not found in any samples. Only one of the 52 corn samples analysed was contaminated with aflatoxin B₁ (17 μg/kg). Fumonisin B₁ was found in 58 % of samples (range of positive samples: 47– 3,347 μg/kg), fumonisin B₂ in 33.0 % (range of positive samples: 23–537 μg/kg) and fumonisin B₃ in 25.0 % (range of positive samples: 24–287 μg/kg) of them. This is the first report on the natural occurrence of mycotoxins in corn from Entre Ríos province, Argentina. Levels of fumonisins were lower than detected in other Argentinian provinces.     

A survey of fumonisins (B1, B2, B3) in Indonesian corn-based food and feed samples

In this paper a survey is described for determination of contamination level of fumonisins (B¹, B², B³) in Indonesian cornbased feed and food samples. The survey was conducted from February to May 2001. Foodstuffs, which are consumed directly such as snacks and other products, were investigated for fumonisin contamination. Of 105 food and feed samples purchased from local retail stores and local poultry shops around Yogyakarta, Java, Indonesia were analyzed using ELISA. Results indicate that 74.3% of samples analyzed were contaminated in a large range of 10.0 – 3307 μg/kg, and the concentration of fumonisins depends on the type of samples. Detection limit of the method used was 9 μg/kg.From eight food samples of maize flour, and corn-based beverages and cereals, none was contaminated (below detection limit). For food samples of industrial products (19 samples), 13 were contaminated in the range of 22.8 – 105 μg/kg and 19 of 20 samples from home made products were contaminated between 12.9 – 234 μg/kg. The food samples contaminated in highest level occurred in corn. Of ten samples, 6 were contaminated from 68.0 – 2471 μg/kg. For feed samples, 17 corn samples were evaluated. Of those samples, 16 contained in a large range of 17.6 – 3306 μg/kg.     

Antimalarial Use of Malagasy Plants Is Poorly Correlated with Performance in Antimalarial Bioassays

Bioassay screening of plant extracts can identify unique lead compounds for drug development, but the “hit rate” from random screening is very low. Targeted screening of medicinal plants has been repeatedly reported to increase the percentage of samples displaying bioactivity. Contrarily, Maranz (2012) suggested that African antimalarial plants were unsuitable sources of antimalarial drugs because high prevalence of malaria would result in rapid evolution of resistance to active compounds that directly targeted the parasite. As malaria is highly prevalent in much of Madagascar, it was of interest to determine whether Malagasy antimalarial plants would outperform randomly selected plants in conventional antimalarial assays being conducted as part of a discovery program. Of 1294 plant samples screened for antimalarial activity, 39.6% had an IC₅₀ <50 μg/ml and 21.1% had an IC₅₀ <20 μg/ml (the minimum to qualify as a first-pass “hit”). Ethnobotanical uses were coded at both the generic and the species level, as neither samples nor use reports in literature were always identifiable to species level. The 526 samples belonging to genera having reported uses for malaria were slightly more likely than average to display activity (44.3% with IC₅₀ <50 μg/ml, p < .01; 23.2% with IC₅₀ <20 μg/ml). Of these, 67 samples from individual species with documented use were still more likely to be modestly active (49.3% with IC₅₀ <50 μg/ml), yet less likely to be highly active (17.9% with IC₅₀ <20 μg/ml). Thus, in this specific context, ethnobotanically directed screening would not have substantially improved screening efficiency and would have missed most of the potential hits.     

Natural occurrence of aflatoxin B<Subscript>1</Subscript> in some Indonesian food and feed products in Yogyakarta in year 1998–1999

A survey was conducted between 1998–1999 to evaluate the level of aflatoxin B₁ (AfB₁) contamination in some selected Indonesian food products, mainly peanuts and peanut products for sale in supermarkets or traditional markets in Yogyakarta, Indonesia. Quantitative analysis was carried out on 118 samples using the ELISA (Enzyme-Linked Immunosorbent Assay) technique. The results indicate that (61.1%) samples were contaminated with AfB₁ at range 2.0 to 249.0 μg/kg. Approximately 50% of the baby food products analysed were contaminated with AfB₁ and the maximum level found was 7.0 μg/kg. In corn products and fermented products, AfB₁ was detected in 66.7 and 50.0% of samples, respectively. A level as high as 5.6 μg/kg of AfB₁ was found in the corn and 6.0 μg/kg in fermented product. AfB₁ was also detected in all rice products, feed products, and other processed products at levels of up to 7.0, 27.0, and 26.0 μg/kg, respectively.     

Natural occurrence of fumonisins in corn puff in Argentina

Maize presents a substantial contamination by fumonisins (FB) throughout the world. In particular, Argentina presents a high frequency of positive samples and levels of up to 10,000 μg/kg of total FB, depending on the harvest campaign studied. Corn puff, an extruded product of high consumption among children and adolescent populations, was analyzed with the aim of determining the presence and levels of fumonisins B₁, B₂ and B₃. In the present study, 20 samples of different brands were collected from commercial stores. Two solvent systems, two types of agitation, and the number of extractions were tested in order to find the most suitable method to establish the level of fumonisins in corn puff. Extracts were analyzed by high performance liquid chromatography (HPLC) with fluorescence detection. A C18 column and precolumn derivatization with orthophtalaldialdehyde were utilized. The average of fumonisins found in 20 samples was 257.5 μg/kg (n?=?19), 70.4 μg/kg (n??=?14) and 73.3 μg/kg (n??=?6) for FB₁, FB₂ and FB₃, on positive samples, respectively. These are the first analyses in Argentina of this type of product, highlighting the need to continue the studies in the processing industries because, despite the extrusion process that the raw material suffers, a sample was found with a contamination of 1,649 μg/kg total fumonisins.     

Spatial and temporal variations in contamination of mycotoxins in sub-humid,semi-arid areas of Eastern Central Tanzania

Studies were conducted to determine the incidences and levels of mycotoxin contamination in household stored maize and groundnuts in Kilosa District, Tanzania. Four villages were chosen for sampling. Seventy-two samples were collected from four villages in 2010, and then tested using a high-performance liquid chromatography method. Levels of Fumonisin B₁ ranged from 63.26 to 213.15 μg/kg in all collected maize samples, while levels of aflatoxin B₁ ranged from 72.97 to 195.17 μg/kg in all collected groundnut samples. Significant differences in levels of fumonisins were observed over time (p < 0.0001) but not among villages (p < 0.3209). Aflatoxin levels differed significantly among villages (p < 0.0491) and over time (p < 0.0001). The association between altitude and the level of aflatoxin contaminations was also significant. This study indicates that stored maize and groundnuts were more prone to mycotoxin contamination.     

A limited survey of aflatoxin B1 contamination in Indonesian palm kernel cake and copra meal sampled from batches

Samples from large (100–200 tons) batches of palm kernel cake (PKC, n?=?20) and copra meal (CM, n?=?13) were collected at production facilities of four Indonesian feed mill manufacturers and analysed for aflatoxin B₁ (AFB₁) by ELISA. Recoveries using spiked samples ranged from 86 to 113 %, with relative standard deviations of <9 % (PKC) and <6 % (CM). All batches were positive for AFB₁: in PKC, at levels of 5.8–93.1 μg/kg (mean 49 μg/kg), and in CM, at levels of 1.1–147 μg/kg (mean 38.1 μg/kg). AFB₁ levels were, in most batches, below the maximum level (100 μg/kg) recommended by the National Standardisation Agency, Republic of Indonesia. However, about half of the batches exceeded both the European Union and USA regulations for AFB₁ in animal feed. In conclusion, serious efforts are necessary to control production, storage and shipment of palm kernel cake and copra meal for feed purposes, and clearly not only for products intended for export but also to reduce AFB₁ levels in domestic Indonesian feed.     

Detection and estimation of aflatoxins using both chemical and biological techniques

Production of aflatoxins on both natural (rice and corn) and semisynthetic (YES) media was conducted using an identified toxin-producing strain ofAspergillus flavus. TheA flavus strain was able to produce 4 types of aflatoxins, namely B₁, B₂, G₁, and G₂ on rice, corn, and YES media. Quantitative data showed that the concentrations of aflatoxins B₁ and G₁ produced were 52, 40.3, and 39.6; and 64.7, 45.0, and 58.0jug for 50g of rice, corn, and YES media, respectively. In comparison, the yielded amounts of aflatoxins B₂ and G₂ were much lower: 11.5, 17.9, and 17.5; and 28.S, 40.3, and 39.5 μg for 50 g of rice, corn, and YES media, respectively. A bioassay was conducted using the following 5 standard bacterial strains:Bacillus megaterium. Bacillus subtilis, Streptococcus faecal is, Staphylococcus epidermidis, andParacoccus denitrificans as well as a field strain of Candida albicans. All strains exceptP denitrificans showed varied degrees of inhibition when applied with crude aflatoxins at 5 to 40μg/mL. The minimum concentration of crude aflatoxins needed to inhibitP denitrificans was 10μg/mL. Moreover,Candida albicans was not inhibited at any concentration of aflatoxins applied in this work. Both undiluted and diluted (1/10, 1/100, and 1/1000) bacterial broth cultures showed a direct relationship between the diameter of inhibition zones and the concentrations of crude aflatoxins. Mean diameters of (7.0–20.5), (5–14), (4.5–13.0), (3.0–12.0), and (1.5–11.0) mm were observed when various concentrations of aflatoxins were applied usingB megaterium, S epidermidis, S faecal is, B subtilis, andP denitrificans, respectively. Field trials were applied to testify the validity of our data. A 1/100 dilution was prepared from each strain of 4 different species to estimate aflatoxins in samples of contaminated corn. Both chemical and biological assays were carried out at the same time. Data revealed that the most sensitive organism inhibited by as low as 7.5μg aflatoxins/mL wasB megaterium giving an inhibition zone of 10.5 mm, followed byS epidermidis with an inhibition zone of 7.5mm. In relation, the other 2 organisms were less sensitive to crude aflatoxins. Similarly, the biological assay was applied to detect aflatoxins in some samples of wheat, corn, peanut, rice, and poultry rations. Of the 14 wheat and 10 corn samples, only 4 wheat and 2 corn samples were found to be positive. The same results were obtained using TLC analysis.     

A limited survey of fumonisins in corn and corn-based products in Asian countries

Natural occurrence of fumonisins B₁ (FB₁) and B₂ (FB₂), a promoter for hepato-carcinogenesis, was investigated in corn and corn — based products sampled in Japan, Nepal, and China by high — performance liquid chromatographic method. From the 9 imported corn kernel and 6 gluten feed samples, FB₁ was detected in 8 corn (0.6 ～ 4.1μg/g) and all gluten feed (0.3 ～ 2.4μg/g) samples, while FB₂ was found in the same corn (0.3 ～ 10μg/g) and 3 gluten feed (0.8 ～ 8.5μg/g) samples. ELISA analysis also revealed the contamination of aflatoxin B₁ in 2 corn and all gluten feed samples along with fumonisins. Of 17 corn grit samples, 14 and 5 samples were contaminated with fumonisin B₁ and B₂, with maximum levels of 2.6 and 2.8μg/g, respectively. As for corn-based foodstuffs marketed in Japan, no significant contamination of fumonisins was observed. Among 24 corn kernel samples in Nepal, 12 and 7 samples were positive for FB₁ and FB₂, and averaged to 0.6 and 1.6μg/g, respectively. One sample showed the highest fumonisin contents as 4.6 and 5.5μg/g, respectively. In corn samples harvested at Shanghai and Beijing, China, FB₁ and FB₂ were detected in various concentrations. Mycological survey has also revealed the presence of a fumonisin — producing fungus in a crop field of Japan. These findings have for the first time demonstrated high levels of contamination of fumonisins in corn and corn — based products in Asian countries. Natural co — occurrence of fumonisins and aflatoxin B₁ was also detected in raw materials for mixed feed.     

Aflatoxins in peanut butter in Khartoum State,Sudan

Forty-three peanut butter samples from Khartoum State, Sudan, were analyzed for aflatoxins (AFs, AFB₁ + AFB₂ + AFG₁ + AFG₂) using high performance liquid chromatography (HPLC) with fluorescence detection after extraction with methanol:water (8:1, v/v) and clean-up using chloroform. All samples were contaminated with AFs, with total AF levels ranging between 26.7 and 853 μg/kg, and a mean total AF level of 287 ± 200.5 μg/kg. The highest concentrations were found for AFB₁, (28 positive samples, maximum 534 μg/kg), while AFG₁ was most frequently detected (43 positive samples, maximum 401 μg/kg). AFB₂ (42 positive samples, maximum 3.2 μg/kg) and AFG₂ (4 positive samples, maximum 30 μg/kg) were also present in these samples. The mean AF contamination levels found in this study exceeded by far all international regulations concerning maximum levels for this group of toxins. From the data, it is concluded that the levels of AF contamination in peanut butter from the Kartoum area are quite alarming, and may pose serious health hazards to consumers. Therefore, an intervention strategy to manage AF in peanut butter is urgently needed.     

Sterigmatocystin and aflatoxin B<Subscript>1</Subscript> contamination of corn,soybean meal,and formula feed in Japan

Sterigmatocystin (STC) and aflatoxin B₁ (AFB₁) were analyzed in 246 corn samples, 126 soybean meal samples, and 861 formula feed samples from the Japanese market between April 2010 and March 2015. The detection rate, the highest concentration, and the mean concentration of STC were respectively 14%, 6.4 μg/kg, and 1.2 μg/kg for corn; 14%, 1.1 μg/kg, and 0.63 μg/kg for soybean meal; and 43%, 9.1 μg/kg, and 0.97 μg/kg for formula feed. The detection rate, the highest concentration, and the mean concentration of AFB₁ were respectively 46%, 24 μg/kg, and 3.9 μg/kg for corn; 30%, 6.7 μg/kg, and 1.1 μg/kg for soybean meal; and 47%, 20 μg/kg, and 1.6 μg/kg for formula feed. A weak negative correlation between the STC and AFB₁ concentrations was observed: there was a high concentration of AFB₁ in samples that contained a lower concentration of STC and vice versa. Spearman’s rank correlation coefficient showed a weak negative correlation of ? 0.30 (p < 0.001, n = 128) for corn and ? 0.23 (p < 0.001, n = 575) for formula feed. In conclusion, no correlation was observed between the mean concentrations of STC contamination in formula feed (0.97 μg/kg) and in corn (1.2 μg/kg) and the blending rate (approximately 50%). The rate of STC contamination in the formula feed (43%) was higher than that in corn (14%). Therefore, it is likely that ingredients other than corn contribute to the contamination of formula feed with STC. In this study, regarding STC, problematic samples were not found.     

Aflatoxin B<Subscript>1</Subscript> contamination in feed from Puglia and Basilicata regions (Italy): 5 years monitoring data

During a 5-year period from 2010 to 2014, n = 919 samples of feed and raw materials were analyzed for aflatoxin B₁ (AFB₁) contamination using accredited ELISA screening methods. Only 0.76 % of these samples were non-compliant with maximum levels set by the European Union Regulation 32/2002. Non-compliant samples were mainly from the province of Bari (n = 3 samples, mean AFB₁ value 7.03 μg/kg), although the highest AFB₁ levels were found in two samples from the provinces of Foggia and Brindisi, at 32.6 ± 3.6 μg/kg and 31.0 ± 4.0 μg/kg, respectively. Mean AFB₁ levels in samples contaminated but compliant with the limits ranged from 1.4 to 2.2 μg/kg. Considering the great importance of climate conditions in mycotoxins production, during crops production and during the critical phases of materials storage and/or transport, to better understand the variability in contamination levels, the analytical results were reviewed in term of temperature and relative environmental humidity in the sampling areas. Correlations between aflatoxin B₁ levels in feed and these climate factors might explain seasonal and annual variations in contamination levels. The data from the present study provide useful suggestions for the organization of targeted monitoring plans and the protection of consumers, as well as for improvement in the quality standards of zootechnological activities and feed industry.     

Aflatoxin contamination of pearl millet during field and storage conditions with reference to stage of grain maturation and insect damage

Aflatoxin contamination in five varieties of pearl millet (ICMH-451, ICMP-50I, ICTP-8203, WCC-75 and ICMV-155) was studied from field and storage conditions in three districts of Andhra Pradesh State, India and the inter-relationships between various parameters such as stage of grain maturation in the field and insect pest infestation in storage in relation to aflatoxin production were evaluated. Aflatoxin contamination was more frequent in the seed samples collected from the fields during rainy season than winter season. All major aflatoxins were isolated from one or the other varieties of pearl millet, whereas aflatoxin G₂ was not commonly observed in the seed samples collected during winter. Among all the varieties tested, ICMH-451 was vulnerable to aflatoxin contamination whereas ICMV-155 was the least susceptible variety. The higher amount of aflatoxins was observed in the matured seed samples followed by pre-matured and milky stage. Among all the toxins reported in the field, aflatoxin B₁ was found in higher concentration (185 (μg/kg) followed by B₂ (105 μg/kg). The four major types of aflatoxins with higher levels (35, 40, 140, 190 μg/kg of G₁, G₂, B₂, B₁ were reported in the rainy season seed samples after six months of storage, whereas aflatoxin G₁ was not observed in any variety of stored seed sample from winter. Statistical analysis revealed that the aflatoxin incidence in relation to different parameters studied was significantly different for each factor. The relationship between aflatoxin contamination and insect damaged-grain clearly indicated that the seed samples with 16-40% of insect damage contained higher amounts of aflatoxins (758 μg/kg). Presented at the 29^th Mykotoxin-Workshop, Fellbach, Germany, May 14–16, 2007     

Occurrence of fumonisins in maize imported into Iran during 2001–2002

Fumonisins, fungal toxins found primarily in maize and produced by various Fusarium species, have been shown to cause a variety of significant adverse health effects in livestock and experimental animals, and are probable human carcinogens. Thirty-three maize samples were collected at ports from bulk shipments, which were imported into Iran from six countries during 2001–2002, and analysed by HPLC for the most abundant of the naturally occurring fumonisin analogues, namely fumonisins B₁ (FB₁), B₂ (FB₂) and B₃ (FB₃). Of the 33 samples, 21 (64%) were found to contain FB₁ (58–512 μg/kg) at levels above 10 μg/kg. The frequency of FB₁ found in maize samples imported from Uruguay and Canada was 75%, followed by China and Argentina (67%), USA (60%), and Brazil (50%). The average FB₁ level was 266 and 169 μg/kg for positive and all samples, respectively. Medians were 250 and 146 μg/kg for positive and all samples, respectively. FB₂ levels ranged from not detected (<10 μg/kg) to 53 μg/kg, whereas no sample had an FB₃ level above the detection level (10 μg/kg). This is the first report of fumonisin contamination of imported maize in Iran. Although, the level of all detected fumonisins were below the Iranian and FDA tolerance levels for foods and feeds, It is necessary to maintain the strict rules to ensure continued safety of imported maize.     

Simultaneous occurrence of mycotoxins in human food commodities from Cameroon

Eighty-two samples of dried food commodities from Cameroon were screened and quantified for different mycotoxins, including fumonisin B₁ (FB₁), zearalenone (ZEA), deoxynivalenol (DON), aflatoxin (AF) and ochratoxin A (OTA), by thin-layer chromatography (TLC) and high-performance liquid chromatography (HPLC), respectively. The percentage of positive samples was as follows: FB₁ 41%, AF 51%, ZEA 57%, DON 65% and OTA 3%. High FB₁ contents were found in maize, averaging 3,684 μg/kg (range: 37-24,225 μg/kg), whereas the highest average ZEA level was found in peanuts (70 μg/kg), followed by maize (69 μg/kg), rice (67 μg/kg) and beans (48 μg/kg) with no ZEA was detected in soybeans. DON contents were low, ranging from 13 to 273 μg/kg, and for AF the average content was 2.6 μg/kg with peanuts and maize as principal substrates. The incidence of OTA was low, with a mean level of 6.4 μg/kg recorded. The majority (79%) of samples contained more than one mycotoxin and the most frequent co-occurrence found was FB₁ + ZEA + DON, detected in 21% of samples (mainly maize) analysed. Co-contamination with FB₁ + ZEA + DON + AF was found in 11% of the samples. Although a large proportion of samples had fairly low levels of individual mycotoxins, this should be of concern as the co-occurrence of mycotoxins may generate additive or synergistic effect in humans, especially if the respective commodities are consumed almost on a daily basis.     

A preliminary study on the occurrence of Aspergillus spp. and aflatoxin B1 in imported wheat and barley in Penang, Malaysia

Thirty samples consisting of wheat (15) and barley (15) were collected from different markets in Penang, Malaysia, originating from India and Thailand, respectively. All samples were analyzed for occurrence of Aspergillus spp. and aflatoxin B₁ (AFB1). Aspergillus flavus was dominant in all samples followed by A. niger. AFB1 could be detected in three wheat samples ranging from 0.42 to 1.89 μg/kg and one barley sample had 0.58 μg/kg of AFB1. The AFB1 levels in all the samples were below the Malaysian regulatory limits (<35 μg/kg). The frequency and quantity of AFB1 levels in this study were very low in wheat and barley samples compared to other agricultural commodities reported in India and Thailand. This is the first report on determination of Aspergillus spp. and AFB1 in imported wheat and barley grains in Penang, Malaysia.     

Mycotoxins in horse feed

A total of 62 samples of commercial horse feed preparations (complementary feeds) containing cereal mixtures (“muesli” or mash, n = 39; pelleted feeds, n = 12), and plain horse feed grains (maize, n = 5; oats, n = 4; barley, n = 2) were purchased from 21 different producers/distributors from the German market. All samples were analysed by competitive enzyme immunoassays (EIA) for six different mycotoxins (mycotoxin groups). Analytes (detection limit, mean recovery) were: deoxynivalenol (DON, 10 μg/kg, 84%), zearalenone (ZEA, 5 μg/kg, 93%), fumonisin B₁ (FB₁, 2 μg/kg, 113%), T-2 toxin (T-2, 0.1 μg/kg, 71%), sum of T-2 + HT-2 toxin (T-2/HT2, 0.2 μg/kg, 97%), ochratoxin A (OTA, 0.2 μg/kg, 67%), and total ergot alkaloids (Generic Ergot Alkaloids “GEA”, 30 μg/kg, 132%). All samples contained DON (16–4,900 μg/kg, median 220 μg/kg), T-2/HT-2 (0.8–230 μg/kg, median 24 μg/kg), and T-2 (0.3–91 μg/kg, median 7 μg/kg). ZEA was detected in 98% of the samples (7–310 μg/kg, median 61 μg/kg). Most samples (94%) were positive for FB₁ (2–2,200 μg/kg, median 27 μg/kg). Ergot alkaloids were detected in 61% of samples (28–1,200 μg/kg, median 97 μg/kg), OTA was found in 42% of samples (0.2–4 μg/kg, median 0.35 μg/kg). The results demonstrate that a co-contamination with several mycotoxins is very common in commercial horse feed from the German market. The toxin concentrations were in most cases well below the levels which are usually considered as critical or even toxic. The highest mycotoxin concentrations were mostly found in single-grain cereal feed: the maximum values for DON and FB₁ were found in maize, the highest T-2/HT-2 toxin concentrations were found in oats, and the highest concentration of ergot alkaloids was found in barley. In composed feeds, no correlation between cereal composition and mycotoxin levels could be found.     

Direct and indirect competitive monoclonal antibody-based ELISA of Aflatoxin B1 in groundnut

Direct and indirect competitive enzyme-linked immunosorbent assays were optimized for the determination of aflatoxin B₁ in groundnut utilizing a specific monoclonal antibody developed at the University of Strathclyde, UK. The monoclonal antibody was conjugated to horseradish peroxidase (HRP) for direct competitive assay, while a commercially available goat-antimouse IgG-HRP conjugate was employed for indirect competitive ELISA. Both ELISAs detected aflatoxin B₁ as low as 20 pg/well. Methanol-water-KCl (70 + 30 v/v, 0.5 %) extracts of groundnut were assayed by ELISA after diluting 1: 10 with PBS-Tween buffer or subjected to simple cleanup for 5:1 concentration prior to assay. The mean recoveries from groundnut spiked with 10 to 200/ig/kg of pure aflatoxin B₁ were >90% in either ELISA, but the toxin recoveries at concentrations of 1–5μg/kg were only 65–67 % when subjected to cleanup and concentration before assay. The mean within-assay, inter-assay, and sub-sample coefficients of variation by ELISA of aflatoxin B₁ in naturally contaminated groundnuts were, respectively, 8.9%, 11.1%, and 7.9% for direct competitive assay and 4.6%, 11.2%, and 8% for indirect competitive assay. Both ELISA methods are useful for routine analysis of aflatoxin B₁ in groundnuts.     

Fungi,Aflatoxins, Fumonisin B<Subscript>l</Subscript> and Zearalenone Contaminating Sorghum-based Traditional Malt,Wort and Beer in Botswana

Brewing and consumption of traditional beer have social–economic significance in most African countries including Botswana. Traditional sorghum malt, wort, and beer samples were collected from three villages around Gaborone, Botswana. Forty-six malt samples were analyzed for fungi on three different media and developing colonies were subcultured for identification. Rhizopus, Fusarium, Mucor, and Aspergillus were the most common genera isolated. Out of the 46 malt samples, 72% contained Rhizopus stolonifer, 63% Fusarium verticillioides (syn. Fusarium moniliforme), and 37% Aspergillus flavus. Although Aspergillus flavus was isolated from malt samples, aflatoxins (B₁, B₂, G₁, and G₂) were not detected in any of the samples analyzed. When the malt, wort, and beer samples were analyzed for fumonisin B_l and zearalenone, fumonisin B₁ was detected in 3 malt samples, with concentrations ranging from 47 to 1316 μg/kg, while zearalenone was detected in 56%, 48% and 48% of the malt, wort and beer samples, respectively. Zearalenone concentration in samples ranged from 102 to 2213 μg/kg in malt, 26 to 285 μg/l in wort and 20 to 201 μg/l, in beer. Zearalenone carry-over from wort to beer ranged from 23 to 403%. Therefore, although aflatoxins and fumonisin B₁ do not appear to be major contaminants, zearalenone is common and could pose a potential problem in traditional beer in Botswana.     

Evaluation of an enzyme immunoassay for the detection of the mycotoxin tenuazonic acid in sorghum grains and sorghum-based infant food

An enzyme-linked immunosorbent assay (ELISA) for the Alternaria mycotoxin tenuazonic acid (TeA) was evaluated by comparative analysis of naturally contaminated sorghum grains and sorghum-based infant food, using a stable isotope dilution LC-MS assay (SIDA; limit of detection (LOD) 1.0 μg/kg) as the reference method. LODs of the ELISA were 30 μg/kg in sorghum grains and 220 μg/kg in sorghum-based infant cereals. With SIDA, 100% of the samples (n = 28) had been positive for TeA in a concentration range of 6–584 μg/kg (mean 113 μg/kg). The ELISA consistently detected TeA in all naturally contaminated samples at cut-off levels of 30–60 μg/kg (sorghum) and 200–300 μg/kg (infant cereals), as based on corresponding to SIDA values. Although the ELISA was much less sensitive than the SIDA method, it may be useful as a screening method for sorghum and sorghum-based infant foods and can be employed to identify samples containing elevated concentrations of TeA in food, well below the proposed level of concern (500 μg/kg).