Biomechanics of Macrophages on Disordered Surface Nanotopography

纳米地形 材料科学 生物力学 纳米技术 曲面(拓扑) 复合材料 生物物理学 几何学 解剖 生物 数学
作者
Zixin Huo,Wenjie Yang,Javad Harati,Ajinkya Nene,Francesca Borghi,Claudio Piazzoni,P. Milani,Shifeng Guo,Massimiliano Galluzzi,Diana Boraschi
出处
期刊:ACS Applied Materials & Interfaces [American Chemical Society]
卷期号:16 (21): 27164-27176 被引量:22
标识
DOI:10.1021/acsami.4c04330
摘要

Macrophages are involved in every stage of the innate/inflammatory immune responses in the body tissues, including the resolution of the reaction, and they do so in close collaboration with the extracellular matrix (ECM). Simplified substrates with nanotopographical features attempt to mimic the structural properties of the ECM to clarify the functional features of the interaction of the ECM with macrophages. We still have a limited understanding of the macrophage behavior upon interaction with disordered nanotopography, especially with features smaller than 10 nm. Here, we combine atomic force microscopy (AFM), finite element modeling (FEM), and quantitative biochemical approaches in order to understand the mechanotransduction from the nanostructured surface into cellular responses. AFM experiments show a decrease of macrophage stiffness, measured with the Young’s modulus, as a biomechanical response to a nanostructured (ns-) ZrOx surface. FEM experiments suggest that ZrOx surfaces with increasing roughness represent weaker mechanical boundary conditions. The mechanical cues from the substrate are transduced into the cell through the formation of integrin-regulated focal adhesions and cytoskeletal reorganization, which, in turn, modulate cell biomechanics by downregulating cell stiffness. Surface nanotopography and consequent biomechanical response impact the overall behavior of macrophages by increasing movement and phagocytic ability without significantly influencing their inflammatory behavior. Our study suggests a strong potential of surface nanotopography for the regulation of macrophage functions, which implies a prospective application relative to coating technology for biomedical devices.
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