球形和圆柱形纳米粒子上蛋白质冠形成的硬球模型。
A hard-sphere model of protein corona formation on spherical and cylindrical nanoparticles.
机构信息
School of Physics, University College Dublin, Belfield, Dublin, Ireland.
School of Physics, University College Dublin, Belfield, Dublin, Ireland.
出版信息
Biophys J. 2021 Oct 19;120(20):4457-4471. doi: 10.1016/j.bpj.2021.09.002. Epub 2021 Sep 8.
Abstract
A nanoparticle (NP) immersed in biological media rapidly forms a corona of adsorbed proteins, which later controls the eventual fate of the particle and the route through which adverse outcomes may occur. The composition and timescale for the formation of this corona are both highly dependent on both the NP and its environment. The deposition of proteins on the surface of the NP can be imitated by a process of random sequential adsorption, and, based on this model, we develop a rate-equation treatment for the formation of a corona represented by hard spheres on spherical and cylindrical NPs. We find that the geometry of the NP significantly alters the composition of the corona through a process independent of the rate constants assumed for adsorption and desorption of proteins, with the radius and shape of the NP both influencing the corona. We further investigate the roles of protein mobility on the surface of the NP and changes in the concentration of proteins.
摘要
纳米粒子(NP)浸入生物介质中会迅速形成吸附蛋白质的冠层,随后控制粒子的最终命运以及可能发生不良后果的途径。这种冠层的组成和形成时间都高度依赖于 NP 和其所处的环境。NP 表面上蛋白质的沉积可以通过随机顺序吸附的过程来模拟,并且基于该模型,我们为通过硬球在球形和圆柱形 NP 上形成的冠层开发了一个速率方程处理方法。我们发现,NP 的几何形状通过一个与吸附和蛋白质解吸的速率常数无关的过程显著改变了冠层的组成,NP 的半径和形状都对冠层有影响。我们进一步研究了 NP 表面上蛋白质的流动性和蛋白质浓度变化的作用。
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