纳米载体
化学
润湿
青枯病
纳米技术
生物物理学
化学工程
沉积(地质)
粘附
材料科学
水杨酸钠
蚀刻(微加工)
接触角
控制释放
药物输送
纳米颗粒
枯草芽孢杆菌
石墨烯
作者
Ze Lv,Yu Fang,Yang Gao,Hui Li,Pengkun Yan,Zheng Zhang,L Wang,Fengyu Li,Ma Yh,Rui Zhao,Xinyu Guo,Xuemin Wu,Yong Xu
标识
DOI:10.1007/s42114-026-01790-y
摘要
Sustainable management of plant bacterial diseases calls for delivery systems that minimize reliance on conventional synthetic pesticides while improving deposition efficiency, on-demand release, and environmental compatibility. This study employs a coordination-driven hollowing strategy to construct interface-optimized hollow metal–phenolic nanocarrier (NaSA@PDA@ZIF-8), achieving synergistic loading of sodium salicylate and Zn2+. PDA-induced etching of ZIF-8 generates a well-defined hollow architecture while enhancing hydrophilicity and colloidal stability. The optimized nanocarrier, obtained via Box–Behnken response surface design, achieves a NaSA loading content of 23.90%. Regarding interfacial performance, the carrier exhibits significantly optimized wetting behavior with a contact angle reduced to 51.15°, enhanced dynamic spreading speed, and outstanding leaf adhesion and rain-wash resistance, ensuring effective retention and utilization in complex field environments. Under simulated bacterial wilt conditions in tobacco (acidic pH 5.0 and elevated temperature of 35 °C), the system exhibited enhanced release behavior. The cumulative release of NaSA reached 81.72% and 83.40%, while Zn2+ release reached 23.19% and 18.72%, indicating good responsiveness to disease-relevant microenvironmental conditions. Its antibacterial activity (EC50 = 17.80 mg·L-1) is likely associated with multiple contributing factors, including Zn2+ release, potential ROS generation mediated by PDA, and NaSA-related activation of plant defense responses. This work demonstrates a hollow metal–phenolic nanoplatform that integrates interfacial adhesion, stimuli-responsive co-delivery, and biosafety, providing a multifunctional reference model for green plant protection.
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