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

Ewa Rutkowska; Elżbieta Wołejko; Piotr Kaczyński; Stanisław Łuniewski; Bożena Łozowicka

doi:10.1016/j.chemosphere.2022.137498

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

Chemosphere. 2023 Feb:313:137498. doi: 10.1016/j.chemosphere.2022.137498. Epub 2022 Dec 7.

Authors

Ewa Rutkowska¹, Elżbieta Wołejko², Piotr Kaczyński³, Stanisław Łuniewski⁴, Bożena Łozowicka³

Affiliations

¹ Institute of Plant Protection - National Research Institute, Laboratory of Food and Feed Safety, Chelmonskiego 22, 15-195, Bialystok, Poland. Electronic address: E.Rutkowska@iorpib.poznan.pl.
² Bialystok University of Technology, Department of Chemistry, Biology and Biotechnology, Faculty of Civil Engineering and Environmental Sciences, Wiejska 45, 15-351, Bialystok, Poland. Electronic address: e.wolejko@pb.edu.pl.
³ Institute of Plant Protection - National Research Institute, Laboratory of Food and Feed Safety, Chelmonskiego 22, 15-195, Bialystok, Poland.
⁴ The University of Finance and Management, Ciepla 40, 15-472, Bialystok, Poland.

PMID: 36495984
DOI: 10.1016/j.chemosphere.2022.137498

Abstract

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.

Keywords: Acute exposure; Apple; Baking; Freeze-drying; Fungicide; Technological process.

MeSH terms

Adult
Captan / analysis
Eating
Food Contamination / analysis
Food Contamination / prevention & control
Fruit / chemistry
Humans
Malus* / chemistry
Pesticide Residues* / analysis
Pesticides* / analysis
Risk Assessment
Temperature

Substances

Pesticides
carbendazim
Pesticide Residues
Captan