Bioinspired Design and Functionalization of Pesticide Nanocarriers: From Synthesis Strategies to Foliar-Targeted Delivery Mechanisms.

IF 6.2 1区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Journal of Agricultural and Food Chemistry Pub Date : 2025-10-01 DOI:10.1021/acs.jafc.5c06765

Shuang Chen,Yixin Zhang,Di Gao,Wenxuan Cao,Xin Zou,Siying Xu,Ranhua Xiong,Chaobo Huang,Wenjing Ma

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引用次数: 0

Abstract

Traditional pesticide formulations suffer from poor adhesion and limited deposition efficiency, causing overuse and ecological risks. Functional nanocarriers present a promising solution by leveraging bioinspired adhesive and structural topographies tailored to hydrophobic foliar surfaces. This review investigates progress in adhesive nanocarrier systems for enhanced foliar retention. We analyze the physicochemical and micronano/architectural features of leaves, evaluating their influence on droplet spreading and interfacial binding strength. Design principles for nanocarriers are established through two complementary approaches: molecular-level affinity (e.g., polyphenol-assisted hydrogen bonding and cation-π coordination) and multiscale structural matching (e.g., size-conforming geometries and hierarchical surface replication). Innovative methodologies, including environmental-triggered release, biohybrid engineering, and adaptive covalent bonding, are examined for enhanced deposition and controlled delivery. Furthermore, we evaluated the environmental and economic viability, considering scalability, field stability, and biodegradability. Future directions propose intelligent nanocarriers with machine-learning-assisted design, multimechanistic adhesion, and integration with precision agricultural platforms, bridging bioadhesion research with sustainable agrochemical applications.

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农药纳米载体的生物灵感设计和功能化：从合成策略到叶面靶向递送机制。

传统农药配方存在粘附性差、沉积效率有限等问题，造成过度使用和生态风险。功能性纳米载体通过利用生物灵感粘合剂和为疏水叶面量身定制的结构拓扑结构，提供了一个有前途的解决方案。本文综述了用于增强叶面保持性的黏附纳米载体系统的研究进展。我们分析了叶片的物理化学和微纳米/结构特征，评估了它们对液滴扩散和界面结合强度的影响。纳米载体的设计原则是通过两种互补的方法建立的：分子水平亲和（例如，多酚辅助氢键和阳离子-π配位）和多尺度结构匹配（例如，尺寸一致的几何形状和分层表面复制）。创新的方法，包括环境触发释放，生物杂交工程和自适应共价键，研究增强沉积和控制递送。此外，我们还评估了环境和经济可行性，考虑了可扩展性、野外稳定性和生物降解性。未来的发展方向是采用机器学习辅助设计、多机械粘附以及与精准农业平台集成的智能纳米载体，将生物粘附研究与可持续农化应用联系起来。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Agricultural and Food Chemistry 农林科学-农业综合

CiteScore

9.90

自引率

8.20%

发文量

1375

审稿时长

2.3 months

期刊介绍： The Journal of Agricultural and Food Chemistry publishes high-quality, cutting edge original research representing complete studies and research advances dealing with the chemistry and biochemistry of agriculture and food. The Journal also encourages papers with chemistry and/or biochemistry as a major component combined with biological/sensory/nutritional/toxicological evaluation related to agriculture and/or food.