Affiliation:
1. Institute for the Control of Agrochemicals Ministry of Agriculture and Rural Affairs Beijing China
2. Key Laboratory of Pesticide Assessment Ministry of Agriculture and Rural Affairs Beijing China
3. Safety Evaluation Center Shenyang Research Institute of Chemical Industry Shenyang Liao Ning China
Abstract
AbstractDiamide insecticides are widely used in rice paddies and pose a potential threat to aquatic organisms. However, the risk research related to their application in major rice‐producing areas is very limited, especially mesocosm research to simulate the impact on aquatic ecosystems of long‐term exposure, as well as exposure analysis based on local models and local scenarios. To assess potential risks from a novel diamide insecticide (tetrachlorantraniliprole) to aquatic nontarget organisms in the field over long‐term exposure, an outdoor mesocosm study was performed, and the environmental concentrations were predicted by the multimedia paddy‐pond model (TOPRICE). The mesocosm experiment showed that tetrachlorantraniliprole mainly stayed in the aqueous phase after entering the water body. Although the chemical dissipated quickly in the aqueous phase (half‐life of 0.79–1.5 days), it showed toxic effects on zooplankton communities. Cladocerans, represented by Simocephalus vetulus, were most sensitive to tetrachlorantraniliprole stress. Significant short‐term toxicity to cladocerans occurred in all treatment groups, but all recovered within 8 weeks except for the highest concentration group (30.0 µg /L). Based on the ecological recovery results, 7.74 µg tetrachlorantraniliprole/L (nominal concentration, 10.0 µg /L) is suggested to be the no‐observed‐ecological‐adverse‐effect concentration (NOEAEC) for the zooplankton community. When this NOEAEC was compared with predicted environmental concentrations (PECs; the PECs in natural ponds simulated by the TOPRICE model for 148 application scheme combinations in major rice‐producing areas), a relatively high risk of applying tetrachlorantraniliprole during the rice tillering stage was found. The present study makes a positive contribution to the hypothesis that the current Tier 1 approaches for global acute risk assessment have a sufficient protective effect for assessing the risk of tetrachlorantraniliprole to aquatic organisms. Also, the present results should help us to gain a fuller understanding of the ecological risk of diamide insecticides in aquatic ecosystems and their rational application schemes. Environ Toxicol Chem 2024;43:429–439. © 2023 SETAC
Subject
Health, Toxicology and Mutagenesis,Environmental Chemistry