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Lipophilic phycotoxins, produced by toxic phytoplankton species, accumulate in digestive glands of mussels. If contaminated mussels containing marine biotoxins over regulatory levels are consumed, it is assumed that this could result in e.g. gastrointestinal disorders.
Objectives
The aim of the study was to report contamination level of lipophilic marine biotoxins and to assess the potential health risk based on dietary intake for regular consumers and recreational harvesters from Bulgaria.
Method/Design
Wild and cultivated mussels were sampled in spring seasons of 2017 and 2018 from the North Black Sea coast. Positive phycotoxins concentrations determined via LC-MS/MS in extracts from digestive glands of the mussels were converted in phycotoxin levels for whole mussel meat (mm) by applying a factor of 5 proposed by EFSA. Dietary intakes were calculated by multiplying the mean positive phycotoxin levels (mg /kg mm) by the food consumption data for an average body weight (bw) of the investigated population group.
Results and discussion
In total 20 farmed and 15 wild mussel samples were investigated. Yessotoxins and pectenotoxin-2 were detected. The mean YTX levels in cultivated mussels were measured about two times higher in spring 2018 (1.64 mg/kg) than in 2017 (0.70 mg/kg). The mean YTX level in wild mussels was found much lower - 0.46 mg/kg (spring 2017). In this regard, estimation of mean dietary YTX intake show that exposure of both population groups by consumption of cultivated mussels from spring 2018 is highest. Nevertheless, the regulatory threshold – acute reference dose of 25 μg/kg bw, is much above the highest calculated dietary intake (0.006 μg/kg female consumers). The mean PTX2 level in wild mussel samples from spring 2017 (0.71 mg/kg) was found about six times higher than in farmed mussels.
The calculation of mean dietary PTX2 intake indicate that most exposed are females if wild mussels from spring 2017 were consumed. Still, the calculated value – 0.003 μg/kg bw were much lower than the ARfD - 0.8 μg/kg bw. All wild mussel samples from spring 2018 were negative. Lowest exposure to detected toxins were established for recreational harvesters.
Conclusion
This study showed in general low contamination level with YTX and PTX2 of investigated mussel samples. Thereon, the estimated dietary intake of selected population groups is also much lower than the regulatory thresholds.
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