杀菌剂
杀虫剂
纳米载体
材料科学
镰刀菌
生物杀虫剂
控制释放
农药降解
生物安全
疾病控制
环境友好型
纳米技术
食品科学
植物病害
农药残留
作物保护
牙冠(牙科)
生物技术
化学
环境工程
毒理
农学
作者
Haonan Zhang,Donglai Zhang,Bin Yu,Qiuyu Xiong,Yun Fang,Zifeng Yang,Zhiyi Li,Jingli Cheng,Jinhao Zhao
标识
DOI:10.1021/acsami.5c13386
摘要
The design of intelligent pesticide delivery systems based on the characteristics of soil-borne diseases is of great significance for improving pesticide utilization efficiency and achieving long-lasting disease control. Herein, a cost-effective and degradable functional poly(butylene oxalate) (PBO) material was constructed and applied for the encapsulation of metconazole (MEZ) to develop a sustained-release pesticide delivery system (MEZ@PBO). The optimized MEZ@PBO was mainly distributed within the 200-300 nm range, with a fungicide-loading capacity reaching 55.7%. Release experiments confirmed the regulatory effect of the PBO molecular weight on the release rate, with higher molecular weight resulting in a longer sustained release period, thereby prolonging the duration of efficacy. MEZ@PBO significantly enhances the photostability of the fungicide while preventing pesticide loss caused by leaching. Moreover, pot experiments indicated that MEZ@PBO achieved long-lasting control of the Fusarium crown rot. After 14 days, the inhibition rate against Fusarium crown rot was 37.9 and 22.4% higher than those of the metconazole technical material and commercial formulation, respectively. Biosafety evaluation and degradation tests further confirmed the environmental friendliness and crop safety. This work offers a promising strategy for enhancing the stability, release control, and efficacy of fungicides in sustainable agriculture.
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