解析靶向和非靶向活细胞膜相互作用中单纳米结构的动力学。
Resolving Single-Nanoconstruct Dynamics during Targeting and Nontargeting Live-Cell Membrane Interactions.
出版信息
ACS Nano. 2019 Dec 24;13(12):13637-13644. doi: 10.1021/acsnano.9b03144. Epub 2019 Aug 9.
Abstract
This paper describes how differences in the dynamics of targeting and nontargeting constructs can provide information on nanoparticle (NP)-cell interactions. We probed translational and rotational dynamics of functionalized Au nanostar (AuNS) nanoconstructs interacting with cells in serum-containing medium. We found that AuNS with targeting ligands had a larger dynamical footprint and faster rotational speed on cell membranes expressing human epidermal growth factor receptor 2 (HER-2) receptors compared to that of AuNS with nontargeting ligands. Targeting and nontargeting nanoconstructs displayed distinct membrane dynamics despite their similar protein adsorption profiles, which suggests that targeted interactions are preserved even in the presence of a protein corona. The high sensitivity of single-NP dynamics can be used to compare different nanoconstruct properties (such as NP size, shape, and surface chemistry) to improve their design as delivery vehicles.
摘要
本文描述了靶向和非靶向结构的动力学差异如何提供有关纳米颗粒(NP)-细胞相互作用的信息。我们研究了在含血清的培养基中与细胞相互作用的功能化 Au 纳米星(AuNS)纳米结构的平移和旋转动力学。我们发现,与具有非靶向配体的 AuNS 相比,具有靶向配体的 AuNS 在表达人表皮生长因子受体 2(HER-2)受体的细胞膜上具有更大的动力学足迹和更快的旋转速度。尽管靶向和非靶向纳米结构具有相似的蛋白质吸附特性,但它们表现出不同的膜动力学,这表明即使存在蛋白质冠,靶向相互作用也能得到保留。单个 NP 动力学的高灵敏度可用于比较不同纳米结构的特性(如 NP 尺寸、形状和表面化学),以改进其作为递药载体的设计。
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