Preplanned Studies: Exposure to Fipronil Insecticide in the Sixth Total Diet Study — China, 2016–2019

This study reported the contamination levels of total FIPs in 24 PLADs in the Sixth China TDS, and analyzed the distribution characteristics of fipronil and its metabolites. As shown inFigure 1B, fipronil was found to be a major residue in plant-derived samples, followed by fipronil sulfone. However, fipronil sulfone became the major residue in animal-derived samples, and the parent compound fipronil was less distributed. Besides, fipronil desulfinyl demonstrated another major distribution contribution in dairy and aquatic products. In total, for products of plant origins, fipronil and fipronil sulfone were the main characteristic contaminants, while for products of animal origins, fipronil sulfone and fipronil desulfinyl were found at higher quantifiable levels of residues due to inconsistent metabolic modes of the parent compound in the body and the photolysis mode in the environment.

Due to an outbreak of fipronil egg contamination in Europe, egg samples were one of the key concerns of this study. Among the 12 dietary categories, no matter from the detection frequency and detection concentration in this study, the egg samples were the worst. The maximum residue limit (MRL) of total FIPs in eggs was set at 20 μg/kg in China. In this study, the average concentration level of eggs in 24 PLADs was 21.4 μg/kg, which exceeded the MRL in China. Details were shown inSupplementary Figure S2. In addition, considering that the egg samples in this study belonged to composite dietary samples, it means that some individual egg samples were likely to exceed the current MRL value. Compared with the results of the Fifth China TDS (6), as shown inSupplementary Figure S3, an upward trend for residue levels of total FIPs was observed in Sixth China TDS. Especially for egg samples, a significant increasing trend was observed for residue levels in Gansu, Inner Mongolia, and Liaoning PLADs from the Fifth to Sixth TDS, which exceeded the MRL with concentration levels of 383 μg/kg, 52.9 μg/kg, and 42.8 μg/kg, respectively.

The Sixth TDS results demonstrated that the EDIs of total FIPs in China were within acceptable levels with low health risk. However, the EDIs of total FIPs in Gansu accounted for 68.0% of the ADI, which was worthy of more attention. Compared with the results from the Fifth TDS (6), the EDI of total FIPs in Chinese adult populations increased slightly in the Sixth TDS. Among them, the contribution rate of animal-derived dietary intake to total EDI was greatly increased. The contribution of eggs was significant, which was mainly related to the high detection levels in Gansu, Inner Mongolia, and Liaoning. In the Fifth TDS, total FIPs were basically detected at <1 μg/kg, and the highest detectable concentration level was less than 9 μg/kg, mainly from vegetables (6). However, in the Sixth TDS, the number of dietary samples for concentration level of >1 μg/kg samples increased, and most of them appeared in animal-derived food. Therefore, to prevent improper or excessive use of fipronil, it is necessary to strengthen the monitoring and traceability for different kinds of animal-derived food, especially eggs.

This study was subject to some limitations. First, the current exposure assessment was based on the consumption patterns of Chinese adults, but it was not involved in that for infants and young children, which required follow-up breast milk monitoring or more detailed dietary exposure assessment at different ages. Second, the current exposure assessment only reflected the average exposure level of adults, but did not cover some highly exposed population with high consumption.

In conclusion, some suggestions are put forward to reduce the health risks of low-level fipronil exposure: 1) strengthen the monitoring of total FIPs in food, especially for animal-derived foods, such as eggs; and 2) seek the source of fipronil exposure in diet and provide some reliable suggestions for policymakers. Notably, fipronil, as the main active ingredient of hygienic insecticide, is still widely used in indoor hygiene and seed protection according to the Chinese pesticide information website (7). Several studies reported that fipronil exposure to indoor dust and environmental water reached noticeable levels (8–10). Therefore, in addition to dietary exposure, other exposure pathways should be closely monitored.

No conflicts of interest reported.

The 24 provincial-level CDCs.