Reducing pesticide use: Synthesis and application of ROS-SPC as an efficient nanocarrier and scavenger of reactive oxygen species in plants

Tian-shi Jiang , Su-zhen Qi , Chang-heng Zhu , Han-qing Zhao , Liu-sheng Duan
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Abstract

There is an increasing need to reduce the use of pesticides to reduce their potential threat to food/environmental safety. At the same time, an increase in reactive oxygen species (ROS) induced by abiotic stresses in plants can lead to an increase in ROS in the plant and affect yield. In this paper, ROS-SPC was synthesised by two reactions and used as an efficient pesticide nanocarrier/adjuvant and scavenger of reactive oxygen species (ROS) in plants. By hydrophobic interaction, ROS-SPC spontaneously conjugated to fluazinam with a pesticide loading capacity (PLC) of 15.1 %. After fluazinam was conjugated to ROS-SPC, the particle size of fluazinam was reduced from 64.70 nm reduced to 19.82 nm, and the contact angle of pesticide droplets on plant leaves was significantly reduced from 59.44° to 26.76°. ROS-SPC as a carrier was tested to inhibit phytopathogenic fungi by 200 % more than conventional delivery methods. In addition, we also learned that ROS-SPC with endocytosis capability can indeed remove reactive oxygen species from plants. Tests using HUVEC cells showed that ROS-SPC has low cytotoxicity within a reasonable range of applications, and ROS-SPC was tested to have low toxicity to pollinating bees.

Abstract Image

减少杀虫剂的使用:合成和应用 ROS-SPC 作为植物中活性氧的高效纳米载体和清除剂
人们越来越需要减少杀虫剂的使用,以降低其对食品/环境安全的潜在威胁。与此同时,植物非生物胁迫诱发的活性氧(ROS)增加会导致植物体内的 ROS 增加,影响产量。本文通过两个反应合成了 ROS-SPC,并将其用作一种高效的农药纳米载体/佐剂和植物体内活性氧(ROS)的清除剂。通过疏水作用,ROS-SPC 自发地与氟嗪草胺共轭,农药负载量(PLC)为 15.1%。氟啶虫酰胺与 ROS-SPC 共轭后,氟啶虫酰胺的粒径从 64.70 nm 减小到 19.82 nm,农药液滴在植物叶片上的接触角从 59.44° 显著减小到 26.76°。经测试,ROS-SPC 作为载体对植物病原真菌的抑制率比传统给药方法高出 200%。此外,我们还了解到,具有内吞能力的 ROS-SPC 确实可以清除植物体内的活性氧。使用 HUVEC 细胞进行的测试表明,在合理的应用范围内,ROS-SPC 的细胞毒性很低,而且经测试,ROS-SPC 对授粉蜜蜂的毒性也很低。
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