纳米农药及载体材料的研究现状

doi:10.11924/j.issn.1000-6850.casb2025-0279

中国农学通报 ›› 2026, Vol. 42 ›› Issue (3): 155-162.doi: 10.11924/j.issn.1000-6850.casb2025-0279

纳米农药及载体材料的研究现状

陈雷¹^,²(), 李连蓉¹^,², 张秋圆¹, 段双刚¹, 吴俨²(), 姚琼¹()

¹ 广东省农业科学院植物保护研究所，农业农村部华南果蔬绿色防控重点实验室，广东省植物保护新技术重点实验室，广州 510640
² 贵阳学院，贵州省农业生物安全全省重点实验室，贵阳 550005

收稿日期:2025-04-26 修回日期:2025-08-15 出版日期:2026-02-15 发布日期:2026-02-09
通讯作者:
姚琼，1984年出生，研究员，博士，研究方向：农业昆虫与害虫防治。通信地址：510640 广州市天河区金颖路7号广东省农业科学院植物保护研究所，E-mail：joanyao_0603@163.com；
吴俨，1987年出生，教授，博士，研究方向：农业昆虫与害虫防治。通信地址：550005 贵州省贵阳市南明区见龙洞路103号贵阳学院，E-mail：15150535703@163.com。
作者简介:
陈雷，男，1998年出生，贵州毕节人，硕士研究生，研究方向：生物与医药。通信地址：510640 广州市天河区金颖路7号广东省农业科学院植物保护研究所，E-mail：xc15528629@163.com。
基金资助:
国家自然科学基金“化学感受蛋白CSPs介导荔枝蒂蛀虫解毒高效氯氟氰菊酯的机制研究”(32472564); 国家荔枝龙眼产业技术体系(CARS-32); 广东省农业和乡村振兴人才项目(NYQN202417); 贵州省第六批高层次创新型人才贵阳市培养对象项目((2022)005); 贵州省农业生物安全全省重点实验室(黔科合ZSYS(2025)024)

Current Status of Research on Nano-pesticides and Carrier Materials

CHEN Lei¹^,²(), LI Lianrong¹^,², Zhang Qiuyuan¹, DUAN Shuanggang¹, WU Yan²(), YAO Qiong¹()

¹ Institute of Plant Protection, Guangdong Academy of Agricultural Sciences/ Key Laboratory of Green Prevention and Control on Fruits and Vegetables in South China, Ministry of Agriculture and Rural Affairs/ Guangdong Provincial Key Laboratory of High Technology for Plant Protection, Guangzhou 510640
² Guizhou Key Laboratory of Agricultural Biosecurity, Guiyang University, Guiyang 550005

Received:2025-04-26 Revised:2025-08-15 Published:2026-02-15 Online:2026-02-09

摘要/Abstract

摘要：

近年来，纳米技术在植物病虫害防治领域取得了一系列突破性进展，为农业高效生产与可持续发展提供了有力技术支撑。本文系统梳理了纳米技术在农药控释领域的研究进展，重点分析了聚合物类、无机非金属类、金属类及生物类四类纳米载体材料的特性，总结了各类载体在农药负载效率、控释性能与环境响应特性等方面的优势，并着重分析了多糖、介孔二氧化硅、金属有机框架等典型载体材料的作用机制及应用潜力。结果显示：（1）各类载体均能提升农药稳定性与靶向性，介孔二氧化硅、金属有机框架等载药率可达33.58%~ 46.27%，且具备pH、温度等环境响应释放能力；（2）纳米农药可降低农药降解率（经52 h紫外照射后降解率降低20%以上），提升对靶标生物的防治效果，减少环境风险；（3）目前存在制备工艺复杂、成本偏高、载药率不足及生态安全性尚不明确等问题。提出应进一步强化载体材料的功能化设计、推动低成本绿色合成技术研发、建立健全安全性评价体系等建议，以促进纳米农药在可持续农业中的规模化应用与推广。

关键词: 纳米材料, 杀虫剂, 纳米载体, 控释, 安全农业

Abstract:

In recent years, a series of breakthrough advances of nano-technology have been made in the field of plant disease and pest control, providing strong technological support for efficient agricultural production and sustainable development. This review systematically outlines the research progress of nano-technology in pesticide controlled-release, with a focus on summarizing the current status of four categories of carrier materials: polymeric, inorganic non-metallic, metallic, and bio-based carriers; highlights the advantages of these carriers in terms of pesticide loading efficiency, controlled-release performance, and environmental responsiveness; special emphasis is placed on analyzing the mechanisms and application potential of representative materials such as polysaccharides, mesoporous silica, and metal-organic frameworks, offering insights for the development of efficient, eco-friendly, and intelligent nano-pesticides. The results show that: (1) all kinds of carriers can improve the stability and targeting of pesticides. The drug loading rate of mesoporous silica and metal organic frameworks can reach 33.58%-46.27%, and they have environmental response release ability such as pH and temperature. (2) Nano-pesticides can reduce the degradation rate of pesticides (the degradation rate is reduced by more than 20% after 52 h UV irradiation), improve the control effect on target organisms, and reduce environmental risks. (3) The review identifies existing challenges in nano-pesticide development, including complex fabrication processes, relatively high costs, insufficient drug-loading capacity, and unresolved ecological safety concerns. Recommendations are proposed to further enhance the functional design of carrier materials, advance research on low-cost green synthesis technologies, and establish comprehensive safety evaluation systems to promote the large-scale application and adoption of nano-pesticides in sustainable agriculture.

Key words: nanomaterials, insecticides, nanocarriers, controlled release, safe agriculture

陈雷, 李连蓉, 张秋圆, 段双刚, 吴俨, 姚琼. 纳米农药及载体材料的研究现状[J]. 中国农学通报, 2026, 42(3): 155-162.

CHEN Lei, LI Lianrong, Zhang Qiuyuan, DUAN Shuanggang, WU Yan, YAO Qiong. Current Status of Research on Nano-pesticides and Carrier Materials[J]. Chinese Agricultural Science Bulletin, 2026, 42(3): 155-162.

参考文献 61

[1]	郭勇飞, 张小军. 纳米农药研究进展[J]. 世界农药, 2021, 43(4):1-7.
[2]	师正浩. 纳米农药的分类及研究现状[J]. 现代农药, 2024, 23(3):33-40.
[3]	PÁSCOLI M, LOPES-OLIVEIRA P J, FRACETO L F, et al. State of the art of polymeric nanoparticles as carrier systems with agricultural applications: a minireview[J]. Energy, ecology and environment, 2018, 3(3):137-148. doi: 10.1007/s40974-018-0090-2
[4]	PRASAD R, BHATTACHARYYA A, NGUYEN Q D. Nanotechnology in sustainable agriculture: recent developments, challenges, and perspectives[J]. Fronters in microbiology, 2017, 8:1014.
[5]	CAMARA M C, CAMPOS E V R, MONTEIRO R A, et al. Development of stimuli-responsive nano-based pesticides: emerging opportunities for agriculture[J]. Journal of nanobiotechnology, 2019, 17(1):100. doi: 10.1186/s12951-019-0533-8 pmid: 31542052
[6]	WANG D, SALEH N B, BYRO A, et al. Nano-enabled pesticides for sustainable agriculture and global food security[J]. Nature nanotechnology, 2022, 17(4):347-360. doi: 10.1038/s41565-022-01082-8 pmid: 35332293
[7]	KUMAR S, NEHRA M, DILBAGHI N, et al. Nano-based smart pesticide formulations: emerging opportunities for agriculture[J]. Journal of controlled release, 2019, 294:131-153. doi: S0168-3659(18)30709-0 pmid: 30552953
[8]	DEL PRADO-AUDELO M L, BERNAL-CHÁVEZ S A, GUTIÉRREZ-RUÍZ S C, et al. Stability phenomena associated with the development of polymer-based nanopesticides[J]. Oxidative medicine and cellular longevity, 2022, 2022(1):5766199. doi: 10.1155/omcl.v2022.1 URL
[9]	SOPPIMATH K S, AMINABHAVI T M, KULKARNI A R, et al. Biodegradable polymeric nanoparticles as drug delivery devices[J]. Journal of controlled release, 2001, 70(1-2):1-20. doi: 10.1016/s0168-3659(00)00339-4 pmid: 11166403
[10]	ALCALÁ-ALCALÁ S, BENÍTEZ-CARDOZA C G, LIMA-MUÑOZ E J, et al. Evaluation of a combined drug-delivery system for proteins assembled with polymeric nanoparticles and porous micro spheres; characterization and protein integrity studies[J]. International journal of pharmaceu tics, 2015, 489(1-2):139-147.
[11]	王淼, 周杰, 陈鸽, 等. 纳米生物农药的设计及控缓释研究进展[J]. 江苏农业科学, 2023, 51(17):9-18.
[12]	PENG R, YANG D, QIU X, et al. Preparation of self-dispersed lignin-based drug-loaded material and its application in avermectin nano-formulation[J]. International journal of biological macromolecules, 2020, 151:421-427. doi: S0141-8130(19)40177-3 pmid: 32061696
[13]	ZHOU M S, XIONG Z C, YANG D J, et al. Preparation of slow release nanopesticide microspheres from benzoyl lignin[J]. Holzforschung, 2018, 72(7):599-607. doi: 10.1515/hf-2017-0155 URL
[14]	ZHANG Z, YANG N, YU J, et al. Research progress of a pesticide polymer-controlled release system based on polysaccharides[J]. Polymers, 2023, 15(13):2810. doi: 10.3390/polym15132810 URL
[15]	THIRUGNANASAMBANDAN T, GOPINATH S C B. Laboratory to industrial scale synthesis of chitosan-based nanomaterials: a review[J]. Process biochemistry, 2023, 130:147-155. doi: 10.1016/j.procbio.2023.04.008 URL
[16]	WU D, ZHU L, LI Y, et al. Chitosan-based colloidal polyelectrolyte complexes for drug delivery: a review[J]. Carbohydrate polymers, 2020, 238:116126. doi: 10.1016/j.carbpol.2020.116126 URL
[17]	POPOVA E V, ZORIN I M, DOMNINA N S, et al. Chitosan-tripolyphosphate nanoparticles: synthesis by the ionic gelation method, properties, and biological activity[J]. Russian journal of general chemistry, 2020, 90(7):1304-1311. doi: 10.1134/S1070363220070178
[18]	BAKSHI P S, SELVAKUMAR D, KADIRVELU K, et al. Chitosan as an environment friendly biomaterial-a review on recent modifications and applications[J]. International journal of biological macromolecules, 2020, 150:1072-1083. doi: 10.1016/j.ijbiomac.2019.10.113 URL
[19]	KASHYAP P L, XIANG X, HEIDEN P. Chitosan nanoparticle based delivery systems for sustainable agriculture[J]. International journal of biological macromoleculesl, 2015, 77:36-51.
[20]	PATHAK R, BHATT S, PUNETHA V D, et al. Chitosan nanoparticles and based composites as a biocompatible vehicle for drug delivery: a review[J]. International journal of biological m acromolecules, 2023, 253(7):127369.
[21]	ZHENG Q, WANG R, QIN D, et al. Novel application of biodegradable chitosan in agriculture: using green nanopesticides to control Solenopsis invicta[J]. International journal of biological macromolecules, 2022, 220:193-203. doi: 10.1016/j.ijbiomac.2022.08.066 URL
[22]	潘华, 李文婧, 吴立涛, 等. 新型纳米农药制剂载体材料的研究进展[J]. 材料导报, 2020, 34(2):1099-1103.
[23]	LIN G, ZHOU H, LIAN J, et al. Preparation of pH-responsive avermectin/feather keratin-hyaluronic acid with anti-UV and sustained-release properties[J]. Colloids and surfaces b: biointerfaces, 2019, 175:291-299. doi: 10.1016/j.colsurfb.2018.11.074 URL
[24]	HAO L, LIN G, WANG H, et al. Preparation and characterization of Zein-based nanoparticles via ring-opening reaction and self-assembly as aqueous nanocarriers for pesticides[J]. Journal of agricultural and food chemistry, 2020, 68(36):9624-9635. doi: 10.1021/acs.jafc.0c01592 pmid: 32809821
[25]	NGUYEN H M, HWANG I C, PARK J W, et al. Enhanced payload and photo-protection for pesticides using nanostructured lipid carriers with corn oil as liquid lipid[J]. Journal of microencapsulation, 2012, 29(6):596-604. doi: 10.3109/02652048.2012.668960 pmid: 22424134
[26]	NGUYEN H M, HWANG I C, PARK J W, et al. Photoprotection for deltamethrin using chitosan-coated beeswax solid lipid nanoparticles[J]. Pest management science, 2012, 68(7):1062. doi: 10.1002/ps.3268 pmid: 22383397
[27]	KUMAR L, KUKRETI G, RANA R, et al. Poly (lactic-co-glycolic) acid (PLGA) nanoparticles and transdermal drug delivery: an overview[J]. Current pharmaceutical design, 2023, 29(37):2940-2953. doi: 10.2174/0113816128275385231027054743 URL
[28]	HAN J R, WENG Y X, XU J, et al. Thermo-sensitive micelles based on amphiphilic poly (butylene 2-methylsuccinate)-poly(ethylene glycol) multi-block copolyesters as the pesticide carriers[J]. Colloids and surfaces a: physicochemical and engineering aspects, 2019, 575:84-93. doi: 10.1016/j.colsurfa.2019.04.057 URL
[29]	闫硕, 蒋沁宏, 沈杰. 纳米农药及载体材料的增效机理研究现状[J]. 植物保护学报, 2022, 49(1):366-373.
[30]	GAO Y, KAZIEM A E, ZHANG Y, et al. A hollow mesoporous silica and poly (diacetone acrylamide) composite with sustained-release and adhesion properties[J]. Microporous and mesoporous materials, 2018, 255:15-22. doi: 10.1016/j.micromeso.2017.07.025 URL
[31]	ZHOU Y, QUAN G, WU Q, et al. Mesoporous silica nanoparticles for drug and gene delivery[J]. Acta pharmaceutica sinica b, 2018, 8(2):165-177. doi: 10.1016/j.apsb.2018.01.007 pmid: 29719777
[32]	FENG J, YANG J, SHEN Y, et al. Mesoporous silica nanoparticles prepared via a one-pot method for controlled release of abamectin: properties and applications[J]. Microporous and mesoporous materials, 2021, 311:110688. doi: 10.1016/j.micromeso.2020.110688 URL
[33]	XU W, SHEN D, CHEN X, et al. Rotenone nanoparticles based on mesoporous silica to improve the stability, translocation and insecticidal activity of rotenone[J]. Environmental science and pollution research, 2023, 30(48):106047-106058. doi: 10.1007/s11356-023-29842-6
[34]	YAN X H, SHAN Y P, MA Y J, et al. Thiacloprid-silica nano-delivery system enhances toxicity against Aphis gossypii and improves non-target biosafety[J]. Chemosphere, 2024, 367:143596. doi: 10.1016/j.chemosphere.2024.143596 URL
[35]	KUMARI S, SHARMA V, SONI S, et al. Layered double hydroxides and their tailored hybrids/composites: progressive trends for delivery of natural/synthetic-drug/cosmetic biomolecules[J]. Environmental research, 2023, 238:117171. doi: 10.1016/j.envres.2023.117171 URL
[36]	KANKALA R K. Nanoarchitectured two-dimensional layered double hydroxides-based nanocomposites for biomedical applications[J]. Advanced drug delivery reviews, 2022, 186:114270. doi: 10.1016/j.addr.2022.114270 URL
[37]	PARK M, LEE C I, SEO Y J, et al. Hybridization of the natural antibiotic, cinnamic acid, with layered double hydroxides (LDH) as green pesticide[J]. Environmental science and pollution researcht, 2010, 17(1):203-209.
[38]	ZHANG X, LIU J, REN J. Structure and release properties of pyrethroid/sulfobutyl ether β-cyclodextrin intercalated into layered double hydroxide and layered hydroxide salt[J]. Frontiers in chemistry, 2022, 10:894386. doi: 10.3389/fchem.2022.894386 URL
[39]	TANG X, JIANG X, CHEN Q, et al. Amphiphilic layered double hydroxides enhance plant-mediated delivery of dsRNAs to phloem‑feeding planthoppers[J]. Chemical engineering journal, 2024, 491:151953. doi: 10.1016/j.cej.2024.151953 URL
[40]	CHENG X, ZHOU Q, XIAO J, et al. Nanoparticle LDH enhances RNAi efficiency of dsRNA in piercing-sucking pests by promoting dsRNA stability and transport in plants[J]. Journal of nanobiotechnology, 2024, 22(1):544. doi: 10.1186/s12951-024-02819-4 pmid: 39237945
[41]	ABU ELELLA M H, GODA E S, ABDALLAH H M, et al. Innovative bactericidal adsorbents containing modified xanthan gum/montmorillonite nanocomposites for wastewater treatment[J]. International journal of biological macromoleculesl, 2021, 167:1113-1125.
[42]	LÜDERWALD S, MEYER F, GERSTLE V, et al. Reduction of pesticide toxicity under Field-relevant conditions? the interaction of titanium dioxide nanoparticles, ultraviolet, and natural organic matter[J]. Environmental toxicology and chemistry, 2020, 39(11):2237-2246. doi: 10.1002/etc.4851 pmid: 33464613
[43]	MOGHADAM M, KARIMI S, NAMAZI H. A targeted biosystem based on l-lysine coated GO@rod-Cu(II) metal-organic frameworks for pH-controlled co-delivery of doxorubicin and curcumin[J]. Food bioscience, 2024, 58:103578. doi: 10.1016/j.fbio.2024.103578 URL
[44]	MA Y J, ZHAO R, SHANG H Y, et al. pH-responsive ZIF-8-based metal-organic-framework nanoparticles for termite control[J]. ACS applied nano materials, 2022, 5(8):11864-11875. doi: 10.1021/acsanm.2c02856 URL
[45]	XUE Q, LI J, VEREECKEN S, et al. Functionally modified graphene oxide as an alternative nanovehicle for enhanced dsRNA delivery in improving RNAi-based insect pest control[J]. Journal of agricultural and food chemistry, 2024, 72(41):22512-22523.
[46]	CHEN C, ZHANG G, DAI Z, et al. Fabrication of light-responsively controlled-release herbicide using a nanocomposite[J]. Chemical engineering journal, 2018, 349:101-110. doi: 10.1016/j.cej.2018.05.079 URL
[47]	PENG F, WANG X, ZHANG W, et al. Nanopesticide formulation from pyraclostrobin and graphene oxide as a nanocarrier and application in controlling plant fungal pathogens[J]. Nanomaterials, 2022, 12(7):1112. doi: 10.3390/nano12071112 URL
[48]	SENBILL H, GANGAN A, SAEED A M, et al. Effects of copper/graphene oxide core-shell nanoparticles on Rhipicephalus ticks and their detoxification enzymes[J]. Scientific reports, 2025, 15(1):3334. doi: 10.1038/s41598-025-86560-4
[49]	GAO X, SHI F, PENG F, et al. Formulation of nanopesticide with graphene oxide as the nanocarrier of pyrethroid pesticide and its application in spider mite control[J]. RSC advances, 2021, 11(57):36089-36097. doi: 10.1039/d1ra06505j pmid: 35492771
[50]	LIANG W, CHENG J, ZHANG J, et al. pH-Responsive on-demand alkaloids release from core-shell ZnO@ZIF-8 nanosphere for synergistic control of bacterial wilt disease[J]. ACS nano, 2022, 16(2):2762-2773. doi: 10.1021/acsnano.1c09724 pmid: 35135193
[51]	YANG C, TANG Y, YAO X, et al. Polysaccharide-gated metal-organic framework nanoparticles for pH-triggered site-specific delivery and enhanced fungicide bioavailability[J]. Chemical engineering journal, 2025, 503:158226. doi: 10.1016/j.cej.2024.158226 URL
[52]	LIANG Y, WANG S, JIA H, et al. Pectin functionalized metal-organic frameworks as dual-stimuli-responsive carriers to improve the pesticide targeting and reduce environmental risks[J]. Colloids and surfaces b: biointerfaces, 2022, 219:112796. doi: 10.1016/j.colsurfb.2022.112796 URL
[53]	SIERRA-SERRANO B, GARCÍA-GARCÍA A, HIDALGO T, et al. Copper glufosinate-based metal-organic framework as a novel multifunctional agrochemical[J]. ACS applied materials & interfaces, 2022, 14(30):34955-34962.
[54]	KHOT L R, SANKARAN S, MAJA J M, et al. Applications of nanomaterials in agricultural production and crop protection: a review[J]. Crop protection, 2012, 35:64-70. doi: 10.1016/j.cropro.2012.01.007 URL
[55]	IHEGWUAGU N E, SHA'ATO R, TOR-ANYIIN T A, et al. Facile formulation of starch-silver-nanoparticle encapsulated dichlorvos and chlorpyrifos for enhanced insecticide delivery[J]. New journal of chemistry, 2016, 40(2):1777-1784. doi: 10.1039/C5NJ01831E URL
[56]	YOUNG M, OZCAN A, MYERS M E, et al. Multimodal generally recognized as safe ZnO/nanocopper composite: a novel antimicrobial material for the management of citrus phytopathogens[J]. Journal of agricultural and food chemistry, 2017, 66(26):6604-6608. doi: 10.1021/acs.jafc.7b02526 URL
[57]	LIANG Y, DUANY F, FAN C L, et al. Preparation of kasugamycin conjugation based on ZnO quantum dots for improving its effective utilization[J]. Chemical engineering journal, 2019, 361:671-679. doi: 10.1016/j.cej.2018.12.129 URL
[58]	SHAN Y, CAO L, MUHAMMAD B, et al. Iron-based porous metal-organic frameworks with crop nutritional function as carriers for controlled fungicide release[J]. Journal of colloid and interface science, 2020, 566:383-393. doi: S0021-9797(20)30128-4 pmid: 32018178
[59]	CAO J, GUENTHER R, SIT T L, et al. Development of abamectin loaded plant virus nanoparticles for efficacious plant parasitic nematode control[J]. ACS applied materials & interfaces, 2015, 7(18):9546-9553.
[60]	CHARIOU P L, STEINMETZ N F. Delivery of pesticides to plant parasitic nematodes using tobacco mild green mosaic virus as a nanocarrier[J]. ACS nano, 2017, 11(5):4719-4730. doi: 10.1021/acsnano.7b00823 pmid: 28345874
[61]	YAN Y S, HOU H W, REN T R, et al. Utilization of environmental waste cyanobacteria as pesticide carrier: studies on controlled release and photostability of avermectin[J]. Colloids and surfaces b: biointerfaces, 2013, 102:341-347. doi: 10.1016/j.colsurfb.2012.07.043 URL

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