The Effect of Household Food Processing on Pesticide Residues in Oranges (Citrus sinensis)

Current research development on food contaminants, future risks, regulatory regime and detection technologies: A systematic literature review

Food contaminants pose serious threats to public health, with profound negative impacts on the economy, society, and environment. However, there is a lack of timely and comprehensive reviews on the latest developments in food contaminants and effective measures to prevent contamination, particularly through novel intelligent detection technologies and regulatory regimes. This study addresses this knowledge gap by presenting a timely review of the literature, focusing on current types of food contaminants, advances in detection technologies, emerging risks, and the latest developments in regulatory frameworks. The study reviewed 116 relevant articles published between 2019 and 2024 and conducted a thematic analysis. The food contaminants were classified into three categories: biological, chemical, and physical. The study identified six key drivers of current and future food safety risks: demographic change, economic factors, environmental conditions, geopolitical shifts, consumer priorities, and technological advancements. Findings reveal the uneven understanding of contaminants of emerging concern, future drivers of contaminants of emerging concern, and their impact on the food system, the environment, and human health. These findings highlight the need for future research on systematically identifying and validating the regional differences in food contamination prevention measures and assessing the extent to which these differences impact the effectiveness of prevention, mitigation, and control efforts. The findings also call for more international cooperation in food contamination research and the active involvement of technology partners to facilitate the application of cutting-edge technologies in food contamination detection and control.

Possible Genotoxic Effects of Post-Harvest Fungicides Applied on Citrus Peels: Imazalil, Pyrimethanil, Thiabendazole and Their Mixtures

Post-harvest fungicides are frequently used on citrus peels to reduce post-harvest fungal contamination during the storage and transport of products. Despite these positive effects, fungicides can pose health risks to consumers. The aim of our study was to perform a genotoxicological risk assessment of imazalil, pyrimethanil, thiabendazole and their mixtures used as post-harvest treatments. A Salmonella mutagenicity Ames test and comet assay were performed to detect reverse mutation and assess DNA damage. Base-pair, frameshift mutations and metabolic activity were analyzed using the Ames test. In the comet assay, lymphocytes were treated with fungicides for 4 and 24 h. Thiabendazole was found to induce both frameshift and base-pair mutations in the Ames test despite the mutagenicity of both imzalil and pyrimethanil (p < 0.05). DNA-strand breaks were observed in lymphocytes, mainly with dimethyl-sulfoxide solvent fungicides (p < 0.05). The long-term exposure and consumption of fruits and vegetables treated with fungicides can increase the risks of developing genotoxic tumors. Our findings raise new questions about the health risks of fungicides and their mixtures to consumers. Further investigations are essential to explore the genotoxicological effects of fungicides on citrus peels.

Insights on Degradation, Processing Factors, and Risk Assessment of Pesticide Pymetrozine, Spirotetramat, and Its Four Metabolites on Goji Berry: "Third Pole" Medicine and Food Homologous Crop

Pesticides are widely used in agriculture, and agricultural commodities are generally consumed as processed foods. How effective these processing procedures are at removing pesticide residues is not well understood. We report initial concentrations of one pesticide that is used extensively on crops of Goji berries, spirotetramat (and its four metabolites: spirotetramat-enol, spirotetramat-enol-glucoside, spirotetramat-monohydroxy, and spirotetramat-keto-hydroxy), and pymetrozine, to be 231.31, 297.42, 229.15, 252.33, 292.73, and 83.18 μg kg-1, respectively. Only 0.18-3.18% of pesticides were eliminated from produce by maceration and washing. Pesticide reduction during processing was 21.23-58.72% (traditional methods), 33.86-73.66% (by cooking samples), and 71.24-90.23% (through vinification), with corresponding processing factors (PFs), a measure of how processing technique affects pesticide residue levels, 0.111-0.771, 0.016-2.33, and 0.008-43.1. For traditional methods, in particular, the PFs of pesticides were 1.77-43.1, suggesting that considerable pesticide enrichment occurred. Combined with the field trial and PF residue data, the acute and chronic dietary risks of pesticides using these processing methods ranged 0.031-1.83 and 0.002-2.51%, respectively. This study provides basic information that can be used to evaluate the potential risks to health of exposure to pesticide residues.

Removal of Pesticides from Lemon and Vegetables Using Electrolyzed Water Kitchen Devices

The possibility of using kitchen electrolyzed water devices (EWDs) for removing residual concentrations of pesticides (malathion, fenitrothion, and p,p'-DDT) from lemon, cucumber, and carrot surfaces was tested. Three commercial devices with different parameters were tested, and their effectiveness was compared with traditional washing methods using water. Based on the results, it was found that by using EWDs, the best removal of water-soluble pesticides was achieved with malathion and fenitrothion (reduction of up to 80%). The worst effectiveness was observed for lipophilic DDT, where a reduction of 20 to 40% was noted. Traditional methods proved to be more effective for removing DDT. Our studies have shown that EWDs can effectively remove pesticide residues; however, further studies should be conducted on a wider spectrum of pesticides and the process should be optimized.

Herbicide contamination of Batak plain agricultural soils and risk assessment

Herbicide residue levels were analyzed in agricultural soils of Batak plain and health risk assessments were made for relevant pesticides. Herbicide contamination levels were analyzed with the use of Quick-Easy-Cheap-Efficient-Rugged-Safe (QuEChERS)-liquid chromatography/tandem mass spectrometry (LC-MS/MS) procedure. Herbicide-free soil samples were spiked at two different levels. Overall recovery of the method was 87.32%. Present findings were parallel to SANTE recovery limits. About 50% of collected samples from the study sites contained herbicides at different concentrations. Totally, eight herbicides were detected, and herbicide concentrations ranged between 1.085 and 1724.23 μg kg-1. Metolachlor had the highest concentration (1724.23 μg kg-1) in a sample taken close to the pesticide waste disposal area. Six herbicides were detected at different concentrations in the same sample. Persistent herbicides (terbuthylazine and pendimethalin) were detected in 35 samples. Risk assessments revealed that hazard index (HI) and hazard quotient (HQ) were less than 1. The greatest HQ values were identified for terbuthylazine as 2772.48 × 10-7 and 20793.61 × 10-7 for adults and children, respectively. The HI for all herbicides were 3916.05 × 10-7 for adult and 29370.39 × 10-7 for children.

Assessment of Apple Peel Barrier Effect to Pesticide Permeation Using Franz Diffusion Cell and QuEChERS Method Coupled with GC-MS/MS

In this study, a new approach to pesticide permeation through the apple peel into the pulp is discussed. The tested compounds can be classified, based on mode of action, as systemic (boscalid, cyprodinil, pirimicarb, propiconazole and tebuconazole) or contact (captan, cypermethrin and fludioxonil) pesticides. The barrier effect was assessed using a Franz flow-type vertical diffusion cell system. A residue analysis was performed using a modified quick, easy, cheap, efficient, rugged and safe (QuEChERS) extraction method coupled to gas chromatography with tandem mass spectrometry (GC-MS/MS). The limits of detection (LODs) ranged between 2.6 µg kg-1 (pirimicarb) and 17 µg kg-1 (captan), with the coefficient of variability (CV) lower than 6%, while recoveries ranged from 85% (boscalid) to 112% (captan) at 0.1 and 1 mg kg-1 spiked levels. The highest peel penetration was observed for pirimicarb, captan and cyprodinil, with cumulative permeations of 90, 19 and 17 µg cm-2, respectively. The total absorption was in the range from 0.32% (tebuconazole) to 32% (pirimicarb). Only cypermethrin was not quantitatively detected in the pulp, and its use can be recommended in crop protection techniques. The obtained results indicate that molecular weight, octanol-water partition coefficient and water solubility are important parameters determining the process of pesticide absorption.

Cumulative health risk assessment of pesticide residues in apple products in the Northwest of Iran using Monte Carlo simulation

Pesticide residues in fruits and vegetables cause serious health issues, especially among children. This research was carried out to monitor and evaluate the risks of organophosphate pesticide residues in Maragheh County apple products from 2020. The Monte Carlo Simulation approach (MCS) was used to evaluate the non-cancerous effects of exposure to pesticide residues in adults and children. Apple samples were taken every two weeks at the Maragheh central market during the summer and fall months. In this study, seventeen pesticide residues in 30 apple samples were estimated using a modified QuECheRS extraction technique coupled with GC/MS. Of the seventeen organophosphate pesticides, thirteen were identified as pesticide residues (76.47%). The highest concentration found in the apple samples was associated with chlorpyrifos pesticide at 1.05 mg/kg. Pesticide residues exceeding the maximum residue limits (MRLs) were found in 100% of apple specimens, and more than 75% of the samples contained ten or more pesticide residues. Approximately 45%-80% of pesticide residues on apple samples were removed after washing and peeling. Chlorpyrifos pesticide had the highest health quotient (HQ) for men, women, and children with values of 0.046, 0.054, and 0.23, respectively. Cumulative risk assessment (CRA) of non-carcinogenic effects indicates that there is no significant health risk in the adult age group from apple consumption (HI < 1). Nevertheless, children are at high non-cancer risk from eating unwashed apples (HI = 1.3). This finding shows that high levels of pesticide residues in apple samples, especially unwashed apples, can be a serious concern for the health of children. To better protect consumer health, continuous and regular monitoring, strict regulations, training, and awareness of farmers, especially control pre-harvest interval (PHI) is recommended.

Determination of 355 Pesticides in Lemon and Lemon Juice by LC-MS/MS and GC-MS/MS

While pesticides have become a primary tool in modern agriculture, these compounds remain a high priority on the list of consumer concerns regarding food safety. The use of pesticides in the production and post-harvesting of lemon fruits is widely used to ensure agricultural yield and fruit quality. Therefore, monitoring studies on citrus fruits to enforce regulatory compliance and ensure food safety is in great demand. The aim of this study was to monitor multi-class pesticide residues in lemon fruits commercialized in Turkey. The transmission of residues that existed on the outer surface of the fruit into its juice was also studied. Whole fruits and lemon juice samples were prepared using the quick, easy, cheap, effective, rugged and safe (QuEChERS) methodology prior to analysis. For the screening and quantification of 355 pesticide residues, liquid chromatography-tandem mass spectrometry (LC-MS/MS) and gas chromatography-tandem mass spectrometry (GC-MS/MS) were used. The analytical method has been shown to have a sufficiently low limit of quantification with respect to current maximum residue limits (MRLs) for all target analytes. The obtained recovery and precision parameters fulfilled the requirements in DG SANTE guidelines. The in-house validated analytical method was then applied for the determination of 355 pesticide substances in 100 whole fruit samples and their juices. Sixteen different residues were detected in 43% of lemon fruits, whereas 57 lemon samples were pesticide-free. The MRLs exceedances were recorded in 29 lemon samples. The most frequently detected (17%) pesticide in lemon fruits was chlorpyrifos-methyl, with a range of 0.013-0.098 mg kg-1. A lower frequency was detected for metamitron (10%, 0.027-0.118 mg kg-1), buprofezin (9%, 0.023-0.076 mg kg-1), pyriproxyfen (9%, 0.021-0.102 mg kg-1) and malathion (7%, 0.100-0.482 mg kg-1) in whole fruits. However, none of the pesticide residues were detected in lemon juice samples. These results showed that target analytes are unable to penetrate the lemon exocarp and/or endocarp.