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基于单宁酸的纳米农药涂层,具有显著改善的叶面附着力,可增强叶面滞留效果。

Tannic acid-based nanopesticides coating with highly improved foliage adhesion to enhance foliar retention.

作者信息

Yu Manli, Sun Changjiao, Xue Yumiao, Liu Chang, Qiu Dewen, Cui Bo, Zhang Yan, Cui Haixin, Zeng Zhanghua

机构信息

Institute of Plant Protection, Chinese Academy of Agricultural Sciences Beijing 100193 PR China.

Institute of Environment and Sustainable Development in Agriculture, Chinese Academy of Agricultural Sciences Beijing 100081 PR China

出版信息

RSC Adv. 2019 Aug 28;9(46):27096-27104. doi: 10.1039/c9ra05843e. eCollection 2019 Aug 23.

DOI:10.1039/c9ra05843e
PMID:35528583
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9070571/
Abstract

Poor utilization efficiency of conventional pesticide formulation has resulted in overuse, which could increase costs, toxicity to other non-target organisms, concerns about human health and safety, groundwater contamination, causing ecosystem destruction and food pollution. The folia-adhesive formulation is supposed to enhance foliar retention time and utilization efficiency. According to the microstructure of the foliage, the nanopesticides surfaces were modified by affinity groups to improve folia adhesion and decrease the loss from crop foliage. In this study, tannic acid, a bioadhesive natural molecule, has been applied to develop abamectin nanopesticide (Abam-PLA-Tannin-NS) and azoxystrobin nanopesticide (Azox-PLA-Tannin-NS) with strong adhesion to foliage by chemical modification. Abam-PLA-Tannin-NS and Azox-PLA-Tannin-NS presented better photostability and continuous release behavior. The retention rates of Abam-PLA-Tannin-NS and Azox-PLA-Tannin-NS on the foliage was remarkably enhanced by more than 50%, compared with unmodified nanopesticides. Resultantly, the indoor toxicity of Abam-PLA-Tannin-NS and antifungal activity of Azox-PLA-Tannin-NS were enhanced. The interaction force between tannic acid coating nanoparticles and foliage was mainly from hydrogen bonding. Our findings could be beneficial to develop novel leaf-adhesive nanopesticides with high retention time and bioavailability.

摘要

传统农药制剂的利用效率低下导致了过度使用,这可能会增加成本、对其他非目标生物产生毒性、引发对人类健康和安全的担忧、造成地下水污染,进而导致生态系统破坏和食品污染。叶贴剂配方旨在延长叶面滞留时间并提高利用效率。根据叶片的微观结构,通过亲和基团对纳米农药表面进行改性,以提高叶面附着力并减少从作物叶片上的流失。在本研究中,单宁酸,一种具有生物粘附性的天然分子,已被用于通过化学改性开发对叶面具有强附着力的阿维菌素纳米农药(阿维菌素-PLA-单宁-纳米粒)和嘧菌酯纳米农药(嘧菌酯-PLA-单宁-纳米粒)。阿维菌素-PLA-单宁-纳米粒和嘧菌酯-PLA-单宁-纳米粒表现出更好的光稳定性和持续释放行为。与未改性的纳米农药相比,阿维菌素-PLA-单宁-纳米粒和嘧菌酯-PLA-单宁-纳米粒在叶面上的滞留率显著提高了50%以上。结果,阿维菌素-PLA-单宁-纳米粒的室内毒性和嘧菌酯-PLA-单宁-纳米粒的抗真菌活性得到增强。单宁酸包覆纳米粒与叶片之间的相互作用力主要来自氢键。我们的研究结果可能有助于开发具有高滞留时间和生物利用度的新型叶贴纳米农药。

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