化学
光敏剂
叶绿素
光动力疗法
渗透(战争)
生物物理学
十二烷基苯磺酸钠
膜
镁
单线态氧
双层
纳米囊
纳米技术
小分子
脂质体
组合化学
纳米载体
生物化学
纳米颗粒
脂质双层
光热治疗
水解
光化学
苯并噻吩
作者
Lisha Zhao,Wenzi Ckurshumova,Ava Ettehadolhagh,Jun Liu,Michael Fefer,Todd Hoare
出处
期刊:Small science
[Wiley]
日期:2026-05-01
卷期号:6 (5): e202500655-e202500655
标识
DOI:10.1002/smsc.202500655
摘要
Photodynamic inactivation offers a broad‐spectrum anti‐pathogen strategy for agriculture but requires effective delivery of the photodynamic activators to enable efficacy. Herein, we demonstrate that nanovesicles based on sodium dodecylbenzenesulfonate (SDBS) and cetyltrimethylammonium bromide (CTAB), prepared with modifiers to either enhance or reduce the stability of the bilayer membrane, can encapsulate and improve the functionality of magnesium chlorophyllin (Mg‐chl). SDBS/CTAB nanovesicles with sizes as small as ∼90 nm can be fabricated with encapsulation efficiencies of >60% for Mg‐chl. The incorporation of unsaturated modifiers into nanovesicle membranes enables triggered Mg‐chl release upon re‐wetting, whereas the introduction of hydrophobic moieties substantially slows Mg‐chl release via a more diffusion‐governed mechanism. Nanovesicles enabled substantially higher light‐activated killing of the plant pathogen P. syringae in simulated field conditions, with rapid binding and/or bacterial uptake observed within five mins of nanovesicle exposure. In addition, nanovesicles facilitated improved Mg‐chl penetration into plant roots. This combination of enhanced anti‐bacterial activity and tunable photosensitizer uptake offers promise to deliver photosensitizing agents or other functional hydrophilic bioactives for improved crop protection.
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