Porous Silica Nanocarriers: Advances in Structural Orientation and Modification to Develop Sustainable Pesticide Delivery Systems

IF 2.3 Q1 AGRICULTURE, MULTIDISCIPLINARY ACS agricultural science & technology Pub Date : 2024-01-08 DOI:10.1021/acsagscitech.3c00436
Saifullah Omar Nasif, Md Nuruzzaman and Ravi Naidu*, 
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Abstract

In precision agriculture, nanotechnology has made significant contributions to the development of a smart cropping system through the support of unique properties of nanomaterials. Of the various nanomaterials, porous nanomaterials have an outstanding performance in building a sustainable delivery system for agrochemicals. In pesticide delivery, amorphous porous silica nanomaterials are considered as some of the most suitable options because of their easy synthesis processes, nontoxic nature, structural variation, tunable porous structure, physical and chemical stability, and ease of surface functionality. So far, multiple roles of these materials have been discussed in the literature; however, the influence of porous structure and structural variations toward developing a sustainable delivery system was not clear. A comprehensive review of the compatibility among the porous silica nanocarriers and pesticide molecules is also lacking. Thus, this review discusses the progress of porous amorphous silica nanomaterial synthesis, their structural variation, and surface modification for effective delivery of different pesticides to explore their potential as carriers.

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多孔二氧化硅纳米载体:结构定向和改性方面的进展,以开发可持续的农药输送系统
在精准农业领域,纳米技术通过支持纳米材料的独特性能,为开发智能耕作系统做出了重大贡献。在各种纳米材料中,多孔纳米材料在构建可持续的农用化学品递送系统方面表现突出。在农药递送方面,无定形多孔二氧化硅纳米材料因其易于合成、无毒、结构多变、可调多孔结构、物理和化学稳定性以及易于实现表面功能而被认为是最合适的选择。迄今为止,文献中已经讨论了这些材料的多种作用;但是,多孔结构和结构变化对开发可持续递送系统的影响尚不明确。关于多孔二氧化硅纳米载体与农药分子之间的兼容性也缺乏全面的综述。因此,本综述讨论了多孔无定形二氧化硅纳米材料的合成、结构变化和表面改性在有效递送不同农药方面的进展,以探索其作为载体的潜力。
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