纳米笼
膜
脂质体
生物物理学
脂质双层
透皮
分子动力学
化学
渗透(战争)
肺表面活性物质
材料科学
膜生物物理学
纳米囊
纳米技术
双层
结构稳定性
纳米壳
细胞膜
膜曲率
脂筏
化学工程
合理设计
POPC公司
生物膜
黄原胶
三萜皂苷
分子模型
作者
Seong‐Bae Min,Bong Soo Pi,Suil Kim,Sujin Park,Seunghan Kang,Eun-Soo Lee,Joonho Choi,Somi Lee,Youngkyu Han,Chaeyeon Song,Siyoung Q. Choi
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-03-18
卷期号:20 (17): 12878-12889
标识
DOI:10.1021/acsnano.5c20519
摘要
Achieving a small size without compromising structural stability remains a key challenge in liposome design. Liposomes below 50 nm penetrate barriers more effectively but suffer from curvature-driven instabilities. Here, we introduce a plant-derived triterpenoid as a dual-function molecular modulator that enables the formation of ultrasmall (≈20 nm), thermochemically stable lipid nanocages. Mechanistically, it induces positive membrane curvature to accommodate a small size while reinforcing bilayer cohesion through interlipid hydrogen bonding. This molecular 'glue' effect stabilizes the membrane under extreme curvature, decoupling the classical size-stability trade-off. Molecular dynamics simulations and experiments confirm that this structural remodeling imparts enhanced resistance to heat, pH, and surfactant disruption─conditions that typically destabilize conventional liposomes. These insights suggest potential therapeutic applications, including improved transdermal penetration and preliminary indications of enhanced epidermal regeneration.
科研通智能强力驱动
Strongly Powered by AbleSci AI