Scientia Agricultura Sinica ›› 2024, Vol. 57 ›› Issue (15): 2997-3009.doi: 10.3864/j.issn.0578-1752.2024.15.007

• PLANT PROTECTION • Previous Articles     Next Articles

Preparation of Fluopyram-Loaded Nanofiber Nematicide and Its Biological Activity Against Meloidogyne incognita

LING WenZheng1(), CAO HaiChao1, YU JiaMin2, ZONG Hao3, WANG Kai4, FENG Chao1(), CHEN Dan1()   

  1. 1 Tobacco Research Institute of Chinese Academy of Agricultural Sciences, Qingdao 266101, Shandong
    2 China National Tobacco Corporation Sichuan Company/Sichuan Tobacco Research Institute, Chengdu 610000
    3 Shandong Linyi Tobacco Co., Ltd., Linyi 276000, Shandong
    4 Shandong Binnong Technology Co., Ltd., Binzhou 256600, Shandong
  • Received:2024-03-15 Accepted:2024-05-22 Online:2024-08-05 Published:2024-08-05
  • Contact: FENG Chao, CHEN Dan

RichHTML

11

PDF

138

Abstract:

Objective】Root-knot nematode disease has become an important influencing factor restricting the development of protected agriculture in China, among which Meloidogyne incognita has caused the most serious yield loss. At present, there are few types of nematicides in China, the objectives of this study are to prepare the fluopyram-loaded nanofiber nematicide based on the electrospinning technique, evaluate its biological activity against M. incognita, and to enrich the types of effective nematicides for controlling root-knot nematode disease of crops and expand the application field of nanofiber agents.【Method】Two kinds of fluopyram-loaded nanofiber nematicide (Flu@NF) were prepared by coaxial electrospinning technology with different biodegradable materials as shell materials and solvated fluopyram as core materials. The morphology, structure, elemental composition, functional components and thermal stability of Flu@NF were characterized by SEM, EDS, TEM, FTIR and TGA. With 41.7% fluropyram suspension as control agent, the biological activity of Flu@NF against 2nd stage juveniles (J2) and egg mass of M. incognita was evaluated.【Result】PEG/PCL-Flu@NF and CA-Flu@NF using polyethylene glycol (PEG), polycaprolactone (PCL) and cellulose acetate (CA) as shell materials were successfully prepared under high pressure +15 kV, core-shell solution flow rate 1﹕4 and receiver side distance of 24 cm. The average diameter of two kinds of agents was 316 and 440 nm, respectively. Fibers were in accordance with the inner and outer microstructure of core-shell, and the shell thickness was separately 71.15 and 24.84 nm. The loading capacity of two kinds of fluopyram-loaded fibers was 15.32% and 20.37%, respectively. Moreover, the thermal stability of fluopyram was significantly improved after shell coating by coaxial electrospinning. Compared with fluropyram suspension, the slow-release performance of fluopyram-loaded fibers was significantly improved, and the mortality of J2 was significantly increased with the extension of treatment time at different concentrations. The lethality rate of the two fiber agents against J2 was higher than 98% after 24 h treatment at high concentration (25 mg·L-1). After treatment with low concentration (4 mg·L-1) for 24 h, the lethality rate of the two fiber agents against J2 was 91.4% and 79.6%, respectively. The two kinds of nematicides had good inhibition effects on the hatching of nematode eggs, after 3 d treatment at high concentration (25 mg·L-1), the unhatched rate of eggs was 71.8% and 89.2%, respectively, and after 3 d treatment at low concentration (4 mg·L-1), the unhatched rate of eggs was 59.4% and 76.2%, respectively.【Conclusion】Based on coaxial electrospinning technology, the nanofibers prepared with PEG/PCL and CA as shell materials have excellent coating effect on fluopyram, and the fluopyram-loaded fibers have high biological activities on M. incognita through slow-release action, which has great potential to prevent and control root-knot nematode disease through crop root protection.

Key words: nanofiber, electrospinning, fluopyram, Meloidogyne incognita, nematicide

Fig. 1

Schematic diagram of the coaxial electrospinning device for preparing core-shell nanofibers"

Fig. 2

Morphological characteristics of fluopyram-loaded fibers and non-fluopyram-loaded fibers A: PEG/PCL-Flu@NF; B: CA-Flu@NF; C: PEG/PCL CK; D: CA CK"

Fig. 3

Diameter distribution of fluopyram-loaded fibers and non-fluopyram-loaded fibers"

Fig. 4

Core-shell microstructure characteristics of two kinds of fluopyram-loaded fibers A: PEG/PCL-Flu@NF; B: CA-Flu@NF"

Fig. 5

The EDS statistical chart of two kinds of fluopyram-loaded fibers A: PEG/PCL-Flu@NF; B: CA-Flu@NF"

Fig. 6

FTIR spectra of fluopyram-loaded fibers and their material components A: PEG/PCL CK, PEG/PCL-Flu@NF; B: CA CK, CA-Flu@NF; C: PEG; D: CA; E: PCL; F: Fluopyram"

Table 1

Data of two kinds of fluopyram-loaded fibers loading capacity"

芯材
Core material		 壳材
Shell material		 载药量
Loading capacity (%)
Flu/二氯甲烷CH2Cl2 PEG/PCL/CH2Cl2 15.32
Flu/CH2Cl2 CA/丙酮C3H6O 20.37

Fig. 7

Thermogravimetric analysis (TGA) ramp profiles for fluopyram and two types of fluopyram-loaded fibers A: Fluopyram; B: PEG/PCL-Flu@NF; C: CA-Flu@NF"

Fig. 8

Lethality rate of two kinds of fluopyram-loaded fibers to M. incognita J2s at different concentrations"

Fig. 9

Biological activity difference between fluopyram-loaded fibers and non-fluopyram-loaded fibers on M. incognita J2s"

Fig. 10

Morphological difference of two kinds of fluopyram-loaded fibers before and after water soaking treatment"

Fig. 11

Inhibitory effect of two kinds of fluopyram-loaded fibers on egg hatching of M. incognita at different concentrations"

[1]
PHANI V, KHAN M R, DUTTA T K. Plant-parasitic nematodes as a potential threat to protected agriculture: Current status and management options. Crop Protection, 2021, 144: 105573.
[2]
DEVINDRAPPA M, KAMRA A, SINGH D, GAWADE B, SIROHI A. Plant growth promoting Bacillus species elicit defense against Meloidogyne incognita infecting tomato in polyhouse. Journal of Basic Microbiology, 2023, 63: 1233-1241.
[3]
UMETSU N, SHIRAI Y. Development of novel pesticides in the 21st century. Journal of Pesticide Science, 2020, 45(2): 54-74.

doi: 10.1584/jpestics.D20-201 pmid: 33132734
[4]
中华人民共和国农业农村部农药检定所. 中国农药信息网. http://www.chinapesticide.org.cn/.
Institute for the Control of Agrochemicals, Ministry of Agriculture and Rural Affairs of the People’s Republic of China. China pesticide information network. http://www.chinapesticide.org.cn/. in Chinese)
[5]
苏少纯, 林成威, 周新华, 周红军. 硅烷化聚琥珀酰亚胺负载阿维菌素的制备与性能. 化工进展, 2022, 41(8): 4481-4490.

doi: 10.16085/j.issn.1000-6613.2021-2084
SU S C, LIN C W, ZHOU X H, ZHOU H J. Preparation and properties of silanylated polysuccinimide-loaded avermectin. Chemical Industry and Engineering Progress, 2022, 41(8): 4481-4490. (in Chinese)

doi: 10.16085/j.issn.1000-6613.2021-2084
[6]
徐晨伟, 袁玉娟, 李亚. 根结线虫病害综合防治研究进展. 黑龙江农业科学, 2023(12): 136-141.
XU C W, YUAN Y J, LI Y. Research progress on comprehensive control methods of root-knot nematode. Heilongjiang Agricultural Sciences, 2023(12): 136-141. (in Chinese)
[7]
王思威, 刘艳萍, 王潇楠, 孙海滨. 噻唑磷在甘蔗和土壤中的残留消解动态及风险评估. 农药学学报, 2018, 20(6): 790-796.
WANG S W, LIU Y P, WANG X N, SUN H B. Residual dynamics and risk assessment of fosthiazate in sugar cane and soil. Chinese Journal of Pesticide Science, 2018, 20(6): 790-796. (in Chinese)
[8]
段婷婷, 陈湘燕, 张盈, 魏进, 伍贵方. 基于HPLC-MS/MS的黄瓜、番茄和土壤中噻唑磷残留的检测. 贵州农业科学, 2014, 42(5): 109-112.
DUAN T T, CHEN X Y, ZHANG Y, WEI J, WU G F. Determination of fosthiazate residues in cucumber, tomato and soil using HPLC-MS/MS. Guizhou Agricultural Sciences, 2014, 42(5): 109-112. (in Chinese)
[9]
SELIM M, ALMUTARI M, SHEHAB H, EL-SAEID M. Risk assessment of pesticide residues by GC-MSMS and UPLC-MSMS in edible vegetables. Molecules, 2023, 28(3): 1343.
[10]
RYAN J, CASALINI R, ORLICKI J, LUNDIN J. Controlled release of the insect repellent picaridin from electrospun nylon-6,6 nanofibers. Polymers for Advanced Technologies, 2020, 31(12): 3039-3047.
[11]
GHAFOOR B, ALEEM A, ALI M N, MIR M. Review of the fabrication techniques and applications of polymeric electrospun nanofibers for drug delivery systems. Journal of Drug Delivery Science and Technology, 2018, 48: 82-87.
[12]
金琰, 蔡凡凡, 王立功, 宋超, 金文雄, 孙俊芳, 刘广青, 陈畅. 生物可降解塑料在不同环境条件下的降解研究进展. 生物工程学报, 2022, 38(5): 1784-1808.
JIN Y, CAI F F, WANG L G, SONG C, JIN W X, SUN J F, LIU G Q, CHEN C. Advance in the degradation of biodegradable plastics in different environments. Chinese Journal of Biotechnology, 2022, 38(5): 1784-1808. (in Chinese)
[13]
WU L, GU Y, LIU L, TANG J, MAO J, XI K, JIANG Z, ZHOU Y, XU Y, DENG L, CHEN L, CUI W. Hierarchical micro/nanofibrous membranes of sustained releasing VEGF for periosteal regeneration. Biomaterials, 2020, 227: 119555.
[14]
苏毛娜, 李雅芳, 夏磊, 赵义侠. 醋酸纤维素导电纤维膜的制备及其电热性能研究. 化工新型材料, 2023, 51(10): 139-144.
SU M N, LI Y F, XIA L, ZHAO Y X. Preparation of cellulose acetate conductive fiber membrane and its electrothermal performance. New Chemical Materials, 2023, 51(10): 139-144. (in Chinese)
[15]
FENG Y, WANG D, XIAO D, PEREIRA T J, XUAN Y, WANG Y, LIU X, CHEN L, DUAN Y, ZHU X. Cactodera chenopodiae (Nematoda: Heteroderidae), a new species of cyst nematode parasitizing common lambsquarter (Chenopodium album) in Liaoning, China. Zootaxa, 2018, 4407(3): 361-375.
[16]
陈歌, 曹立冬, 许春丽, 赵鹏跃, 曹冲, 李凤敏, 黄啟良. 溶剂蒸发法制备丙硫菌唑微囊及其性能研究. 中国农业科学, 2021, 54(4): 754-767. doi: 10.3864/j.issn.0578-1752.2021.04.008.
CHEN G, CAO L D, XU C L, ZHAO P Y, CAO C, LI F M, HUANG Q L. Performance study of prothioconazole microcapsules prepared by solvent evaporation method. Scientia Agricultura Sinica, 2021, 54(4): 754-767. doi: 10.3864/j.issn.0578-1752.2021.04.008. (in Chinese)
[17]
HOSSEINZADEH F, TABESH H, FARZANEH F. Nano drug delivery platform based on thermosensitive PEG-PCL hydrogel encapsulated in silver-bearing micelles and its antifungal activity investigation against vaginal candidiasis. Frontiers in Materials, 2023, 10: 1210542.
[18]
罗强, 李星, 赵燕杰, 林炳松, 李亚宁, 徐妍, 康占海. 2种聚羧酸盐类分散剂在氟吡菌酰胺颗粒表面的吸附性能. 农药, 2020, 59(7): 486-491, 501.
LUO Q, LI X, ZHAO Y J, LIN B S, LI Y N, XU Y, KANG Z H. The adsorption properties of two polycarboxylate dispersants on the surface of fluopyram particles. Agrochemicals, 2020, 59(7): 486-491, 501. (in Chinese)
[19]
林昊, 郭东毅, 吕谦, 贾惜文, 周成凤, 肖卫华. 玉米秸秆基木质素-醋酸纤维素紫外屏蔽膜的制备及其性能. 复合材料学报, 2023, 40(8): 4768-4778.
LIN H, GUO D Y, Q, JIA X W, ZHOU C F, XIAO W H. Preparation of corn stover-based lignin-cellulose acetate ultraviolet shielding film and its properties. Acta Materiae Compositae Sinica, 2023, 40(8): 4768-4778. (in Chinese)
[20]
KANNAN P, KARTHICK N, MAHENDRAPRABU A, SHANMUGAM R, ELANGOVAN A, ARIVAZHAGAN G. Red/blue shifting hydrogen bonds in acetonitrile-dimethyl sulphoxide solutions: FTIR and theoretical studies. Journal of Molecular Structure, 2017, 1139: 196-201.
[21]
迟元凯, 叶梦迪, 赵伟, 曹舜, 汪涛, 戚仁德. 氟吡菌酰胺对南方根结线虫的作用效果. 植物保护学报, 2019, 46(6): 1364-1370.
CHI Y K, YE M D, ZHAO W, CAO S, WANG T, QI R D. Effect of fluopyram on root-knot nematode Meloidogyne incognita. Journal of Plant Protection, 2019, 46(6): 1364-1370. (in Chinese)
[22]
周建宇, 袁涛, 叶姗, 黄文坤, 李忠彩, 丁中. 氟吡菌酰胺不同施药方式对水稻拟禾本科根结线虫的防治效果. 植物保护学报, 2018, 45(6): 1412-1418.
ZHOU J Y, YUAN T, YE S, HUANG W K, LI Z C, DING Z. Evaluation on the control effect of fluopyram on the root-knot nematode in rice with different spraying methods. Journal of Plant Protection, 2018, 45(6): 1412-1418. (in Chinese)
[23]
刘芮铭, 张金珊, 田强运, 林謦怡, 张正健. 静电纺丝控释材料的最新研究进展. 包装工程, 2023, 44(3): 39-51.
LIU R M, ZHANG J S, TIAN Q Y, LIN Q Y, ZHANG Z J. Recent research progress on electrospinning controlled-release materials. Packaging Engineering, 2023, 44(3): 39-51. (in Chinese)
[24]
上官文杰, 梅向东, 胡帅, 赵鹏跃, 曹冲, 李凤敏, 黄啟良, 徐洪亮, 曹立冬. 静电纺丝技术在农药领域中的应用现状及发展前景. 农药学学报, 2023, 25(2): 267-281.
SHANGGUAN W J, MEI X D, HU S, ZHAO P Y, CAO C, LI F M, HUANG Q L, XU H L, CAO L D. Application status and development prospects of electrospinning technology in the field of pesticides. Chinese Journal of Pesticide Science, 2023, 25(2): 267-281. (in Chinese)
[25]
ZHANG S, YANG X, TU Z, HUA W, HE P, LI H, ZHANG B, REN T. Influence of the hydrophilic moiety of polymeric surfactant on their surface activity and physical stability of pesticide suspension concentrate. Journal of Molecular Liquids, 2020, 317: 114136.
[26]
FARIAS B, PIRZADA T, MATHEW R, SIT T, OPPERMAN C, KHAN S. Electrospun polymer nanofibers as seed coatings for crop protection. ACS Sustainable Chemistry and Engineering, 2019, 7(24): 19848-19856.
[27]
WANG A, WANG Y, SUN C, WANG C, CUI B, ZHAO X, ZENG Z, YAO J, YANG D, LIU G, CUI H. Fabrication, characterization, and biological activity of avermectin nano-delivery systems with different particle sizes. Nanoscale Research Letters, 2018, 13(1): 2.
[28]
张矿生, 唐梅荣, 薛小佳, 李楷, 邵炎, 周健, 岳冲冲, 李壮壮, 潘鹏举. 聚乳酸/聚乙二醇共混物的结晶与降解行为. 化工学报, 2021, 72(2): 1181-1190.

doi: 10.11949/0438-1157.20200323
ZHANG K S, TANG M R, XUE X J, LI K, SHAO Y, ZHOU J, YUE C C, LI Z Z, PAN P J. Crystallization and degradation behavior of poly (lactic acid)/poly (ethylene glycol) blends. CIESC Journal, 2021, 72(2): 1181-1190. (in Chinese)
[29]
ELMAGHRABY N A, OMER A M, KENAWY E, GABER M, HASSAAN M A, RAGAB S, HOSSAIN I, EL NEMR A. Electrospun cellulose acetate/activated carbon composite modified by EDTA (rC/AC-EDTA) for efficient methylene blue dye removal. Scientific Reports, 2023, 13(1): 9919.
[30]
DETHE M, PRABAKARAN A, AHMED H, AGRAWAL M, ROY U, ALEXANDER A. PCL-PEG copolymer based injectable thermosensitive hydrogels. Journal of Controlled Release, 2022, 343: 217-236.
[1] HUANG XuePing, SONG YuFei, LUO Jian, ZHAO ShiFeng, MU Wei, LIU Feng. Sensitivity of Sclerotinia sclerotiorum to Fluopyram and Evaluation of Its Application Potential in Controlling Sclerotinia Stem Rot [J]. Scientia Agricultura Sinica, 2018, 51(14): 2711-2718.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备09089781号-30
Copyright 2018 © Editorial office of Scientia Agricultura Sinica
Tel: 86-010-82106279    E-mail: zgnykx@mail.caas.net.cn
Supported by Beijing Magtech Co.Ltd