Aggregation and aging of nanoparticle–protein complexes at interfaces studied by evanescent-light scattering microscopy

IF 13.9 Q1 CHEMISTRY, MULTIDISCIPLINARY
Wei Liu, Yuwei Zhu, Hang Jiang, Lidan Zhou, Yinan Li, Jiahao Wu, Jie Han, Cheng Yang, Jianzhong Jiang, To Ngai
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Abstract

Plasma protein-induced aggregation of nanoparticles (NPs) is a crucial issue in many applications, such as drug delivery. Although great efforts have been made to investigate the protein adsorption kinetics or protein-induced NPs coalescence in bulk solutions, limited evidence has been uncovered for interfacial circumstances. Diet, disease, medicine, or senility could thoroughly change interfacial physicochemical properties of the inner lining of blood vessels. Implants including stents and artificial heart valves also have varied and evolutionary interfaces. Hence, there is an urgent need to understand the mechanism behind the non-specific protein adsorption and NP-protein aggregation in such interfacial cases. Here, we use evanescent light scattering to observe polystyrene NPs‒fibrinogen aggregation at substrates with varying surface properties. A density-fluctuation correlation function is utilized to reveal the relaxation dynamics of the aggregates. Both time-resolved and spatial-correlated evidence shows that the aging process of such soft materials is out-of-equilibrium, where the dynamics faster and slower than exponential can coexist in one single relaxation process. Besides, corona formation, inner stress, and interconnection together determine the microstructure, local adhesion, and structural relaxation of the aggregates, which can further correspond to the protein-to-NP ratio as well as the surface chemistry of NPs and substrates.

Abstract Image

Abstract Image

用闪烁光散射显微镜研究纳米粒子-蛋白质复合物在界面上的聚集和老化现象
等离子体蛋白质诱导的纳米粒子(NPs)聚集是药物输送等许多应用中的一个关键问题。尽管人们已经做出了巨大努力来研究蛋白质吸附动力学或蛋白质诱导 NPs 在大量溶液中的凝聚,但在界面情况下发现的证据却很有限。饮食、疾病、药物或衰老会彻底改变血管内壁的界面理化特性。包括支架和人工心脏瓣膜在内的植入物的界面也会发生变化和演变。因此,迫切需要了解此类界面非特异性蛋白质吸附和 NP 蛋白聚集背后的机制。在这里,我们利用 evanescent 光散射来观察聚苯乙烯 NPs-纤溶酶原在不同表面性质基底上的聚集。我们利用密度波动相关函数来揭示聚集体的弛豫动力学。时间分辨和空间相关的证据都表明,这类软材料的老化过程是失衡的,比指数更快和更慢的动力学可以共存于一个单一的弛豫过程中。此外,电晕形成、内应力和相互连接共同决定了聚集体的微观结构、局部粘附和结构松弛,而这又进一步对应于蛋白质与 NP 的比例以及 NPs 和基底的表面化学性质。
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来源期刊
CiteScore
17.40
自引率
0.00%
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审稿时长
7 weeks
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