Cui Chenglong, Shangguan Wenjie, Li Kebin, Jiang Xingfu, Wang Zhimin, Yin Jiao, Cao Lidong
State Key Laboratory for Biology of Plant Diseases and Insect Pests, Institute of Plant Protection of Chinese Academy of Agricultural Sciences, No. 2 Yuanmingyuan West Road, Haidian District, Beijing, 100193, PR China.
J Nanobiotechnology. 2025 Apr 1;23(1):259. doi: 10.1186/s12951-025-03269-2.
Chemical pesticides face significant challenges regarding their efficacy and environmental impact. Plant-based food attractants have emerged as a promising green alternative for pest control. However, their field application is limited by the short duration of effectiveness, necessitating improved carrier systems for sustained release. Electrospinning is a promising technology in this field, with core-shell fibers offering superior performance in efficient loading and sustained release compared to uniaxial fibers, highlighting their potential for further development.
In this study, core-shell micro-nano fiber mats were prepared via coaxial electrospinning using multiple environmentally friendly polymers. These mats were firstly and successfully loaded with food attractants bisexually attractive to Loxostege sticticalis adults, including 1-octen-3-ol, trans-2-hexenal, linalool, and anethole, enabling sustained release and effective trapping. The components in the core-shell spinning solution were chemically compatible, and after spinning, the poly(3-hydroxybutyrate-co-4-hydroxybutyrate)/polycaprolactone (PHB/PCL) in the shell layer and polyethylene oxide (PEO) in the core layer formed core-shell fibers with clear boundaries. The mats achieved an average encapsulation efficiency of 78% for active ingredients, with a sustained release profile that delivered over 60% of the attractants within 80 days while mitigating early burst release. Electroantennogram and behavioral studies revealed that the mats retained electrophysiological activity for at least 90 days, effectively attracting male and female adult insects even after 75 days. Field trials demonstrated that the mats significantly outperformed commercial slow-release carriers, attracting a higher number of L. sticticalis adults. Additionally, the mats exhibited strong stress resistance, biodegradability, and environmental compatibility, effectively protecting active molecules while minimizing ecological impact.
The developed fiber mats provide a highly efficient, eco-friendly carrier for plant-based food attractants, offering prolonged efficacy and improved insect trapping performance. This study highlights their potential for sustainable agriculture and pest management, paving the way for greener alternatives to chemical pesticides.
化学农药在功效和环境影响方面面临重大挑战。植物性食物引诱剂已成为一种有前景的绿色害虫防治替代品。然而,它们的田间应用受到有效性持续时间短的限制,因此需要改进载体系统以实现持续释放。静电纺丝是该领域一项有前景的技术,与单轴纤维相比,核壳纤维在有效负载和持续释放方面具有卓越性能,凸显了其进一步发展的潜力。
在本研究中,使用多种环保聚合物通过同轴静电纺丝制备了核壳微纳纤维垫。这些垫子首先成功负载了对草地螟成虫具有两性吸引力的食物引诱剂,包括1-辛烯-3-醇、反-2-己烯醛、芳樟醇和茴香脑,实现了持续释放和有效诱捕。核壳纺丝溶液中的成分具有化学相容性,纺丝后,壳层中的聚(3-羟基丁酸酯-共-4-羟基丁酸酯)/聚己内酯(PHB/PCL)和核层中的聚环氧乙烷(PEO)形成了边界清晰的核壳纤维。这些垫子对活性成分的平均包封效率达到78%,具有持续释放特性,在80天内释放了超过60%的引诱剂,同时减轻了早期突发释放。触角电位和行为研究表明,这些垫子的电生理活性至少保持90天,即使在75天后仍能有效吸引雌雄成虫。田间试验表明,这些垫子的表现明显优于商业缓释载体,吸引了更多的草地螟成虫。此外,这些垫子具有很强的抗逆性、生物降解性和环境相容性,能有效保护活性分子,同时将生态影响降至最低。
所开发的纤维垫为植物性食物引诱剂提供了一种高效、环保的载体,具有延长的功效和改进的昆虫诱捕性能。本研究突出了它们在可持续农业和害虫管理方面的潜力,为化学农药的绿色替代品铺平了道路。
