Impact of technological processes on tebuconazole reduction in selected cereal species and the primary cereal product, and dietary exposure assessment.

Contamination of cereals with tebuconazole (TEB) can affect the dietary risk assessment. This study investigates, for the first time, how mechanical, thermal, physical-chemical, and biochemical processes affect the TEB level in wheat, rye, and barley. The biochemical process of malting was the most effective for tebuconazole reduction (by 86%) in cereals. Thermal processes were also effective, i.e., boiling (70%) and baking (55%). These processes considerably decreased the concentration of tebuconazole, and Procesing Factors (PFs) were from 0.10 to 0.18 (malting), 0.56 to 0.89 (boiling), and 0.44 to 0.45 (baking), respectively. The concentration of TEB was not reduced after the application of mechanical processing. The risk was estimated in dietary exposure assessment on the basis of the highest reported levels of tebuconazole residues bread. At a high level of rye bread consumption, the potential exposure to tebuconazole reached only 3.5% and 2.7% in children and adults, respectively.

High and low temperature processing: Effective tool reducing pesticides in/on apple used in a risk assessment of dietary intake protocol.

Apples play an important role in everyone's diet and may contain pesticide residues that can pose a significant health problem for consumers. Various technological processes are promising methods for minimizing pesticide concentrations in fruit. Therefore, the subject of this comprehensive study was to investigate the effects of high-temperature (baking) and low-temperature (freeze-drying) processes on the change in the levels of nine fungicides in apples with skin and peeled. The investigated compounds belong to the chemical groups of benzimidazole (thiophanate methyl and carbendazim), phtalimide (captan and their metabolite tetrahydrophtalimid (THPI)), strobilurin (pyraclostrobin, trifloxystrobin) and triazole (difenoconazole, tebuconazole, tetraconazole). Processing factors (PF) were calculated for each pesticide-process-product combination. The results show that baking and freeze-drying generally reduced pesticide concentrations, with PFs ranging from 0.31 to 0.81 and 0.26 to 0.68, respectively. Apart from freeze-drying for carbendazim and baking for captan, PFs were above 1. Only for thiophanate-methyl, a complete reduction was observed, which resulted from complete degradation to carbendazim. The study also aimed to assess human risk according to the new strategy for different sub-populations with conversion using the 36 PFs obtained. The highest acute exposure (expressed as %ARfD) was obtained for tebuconazole in raw apples (initial concentration of 1.42 mg/kg; 400% ARfD) for Dutch toddlers. After food processing, this decreased to 284% (0.74 mg/kg, baking) and to 137% (0.37 mg/kg, freeze-drying), but was still above the safety limit. Similarly, for adults and the general French population for tebuconazole, the %ARfD was high as it reached the values of 104% (initial concentration of 0.89 mg/kg) in unprocessed apples, 73.9% after baking (0.73 mg/kg) and 35.6% after freeze-drying (0.35 mg/kg). The results indicate that food processing techniques can potentially be used to minimize the hazardous effects of pesticide residues on human health.

Chlorpyrifos Occurrence and Toxicological Risk Assessment: A Review.

Chlorpyrifos (CPF) was the most frequently used pesticide in food production in the European Union (EU) until 2020. Unfortunately, this compound is still being applied in other parts of the world. National monitoring of pesticides conducted in various countries indicates the presence of CPF in soil, food, and water, which may have toxic effects on consumers, farmers, and animal health. In addition, CPF may influence changes in the population of fungi, bacteria, and actinomycete in soil and can inhibit nitrogen mineralization. The mechanisms of CPF activity are based on the inhibition of acetylcholinesterase (AChE) activity. This compound also exhibits reproductive toxicity, neurotoxicity, and genotoxicity. The problem seems to be the discrepancy between the actual observations and the final conclusions drawn for the substance's approval in reports presenting the toxic impact of CPF on human health. Therefore, this influence is still a current and important issue that requires continuous monitoring despite its withdrawal from the market in the EU. This review traces the scientific reports describing the effects of CPF resulting in changes occurring in both the environment and at the cellular and tissue level in humans and animals. It also provides an insight into the hazards and risks to human health in food consumer products in which CPF has been detected.

Toxicological Effects of Traumatic Acid and Selected Herbicides on Human Breast Cancer Cells: In Vitro Cytotoxicity Assessment of Analyzed Compounds.

The main consequence of herbicides use is the presence of their residues in food of plant origin. A growing body of evidence indicates that herbicides cause detrimental effects upon human health while demonstrating a direct link of pesticides exposure with the occurrence of human chronic diseases, including cancer. There is a pressing need to develop our knowledge regarding interactions of food contaminants and food components both in vitro and in vivo. Pesticides are highly undesirable food contaminants, and traumatic acid (TA) is a very beneficial food ingredient, therefore we decided to study if TA may act as a compound that delays the stimulatory effect of pesticides on breast cancer cells. To analyze the potential effects that selected herbicides (MCPA, mesotrione, bifenox and dichlobenil) may have upon cancerous cells, we conducted studies of the cytotoxicity of physiological concentrations of four pesticides and the mix of TA with tested herbicides in three different breast cancer cell lines (MCF-7, ZR-75-1 and MDA-MB-231) and one normal healthy breast cell line MCF-12A. Based on the obtained results we conclude that TA in a concentration-dependent manner might influence selected effects of the studied herbicides for particular cancer cells lines.

The influence of effective microorganisms (EM) and yeast on the degradation of strobilurins and carboxamides in leafy vegetables monitored by LC-MS/MS and health risk assessment.

The aim of this study was to determine the behaviour of strobilurin and carbocyamides commonly used in chemical protection of lettuce depending on carefully selected effective microorganisms (EM) and yeast (Y). Additionally, the assessment of the chronic health risk during a 2-week experiment was performed. The statistical method for correlation of physico-chemical parameters and time of degradation for pesticides was applied. In this study, the concentration of azoxystrobin, boscalid, pyraclostrobin and iprodione using liquid chromatography-mass spectrometry (LC-MS/MS) in the matrix of lettuce plants was performed, and there was no case of concentration above maximum residues levels. Before harvest, four fungicides and their mixture with EM (1 % and 10 %) and/or yeast 5 % were applied. In our work, the mixtures of 1%EM + Y and 10%EM + Y both stimulated and inhibited the degradation of the tested active substances. Adding 10%EM to the test substances strongly inhibited the degradation of iprodione, and its concentration decreased by 30 %, and in the case of other test substances, the degradation was approximately 60 %. Moreover, the addition of yeast stimulated the distribution of pyraclostrobin and boscalid in lettuce leaves. The risk assessment for the pesticides ranged from 0.4 to 64.8 % on day 1, but after 14 days, it ranged from 0.0 to 20.9 % for children and adults, respectively. It indicated no risk of adverse effects following exposure to individual pesticides and their mixtures with EM and yeast.