Multidepth quantitative analysis of liver cell viscoelastic properties: Fusion of nanoindentation and finite element modeling techniques

IF 2 3区工程技术 Q2 ANATOMY & MORPHOLOGY

Microscopy Research and Technique Pub Date : 2024-09-10 DOI:10.1002/jemt.24697

Yi Zeng, Xianping Liu, Zuobin Wang, Wei Gao, Shengli Zhang, Ying Wang, Yunqing Liu, Haiyue Yu

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引用次数: 0

Abstract

Liver cells are the basic functional unit of the liver. However, repeated or sustained injury leads to structural disorders of liver lobules, proliferation of fibrous tissue and changes in structure, thus increasing scar tissue. Cellular fibrosis affects tissue stiffness, shear force, and other cellular mechanical forces. Mechanical force characteristics can serve as important indicators of cell damage and cirrhosis. Atomic force microscopy (AFM) has been widely used to study cell surface mechanics. However, characterization of the deep mechanical properties inside liver cells remains an underdeveloped field. In this work, cell nanoindentation was combined with finite element analysis to simulate and analyze the mechanical responses of liver cells at different depths in vitro and their internal responses and stress diffusion distributions after being subjected to normal stress. The sensitivities of the visco‐hyperelastic parameters of the finite element model to the effects of the peak force and equilibrium force were compared. The force curves of alcohol‐damaged liver cells at different depths were measured and compared with those of undamaged liver cells. The inverse analysis method was used to simulate the finite element model in vitro. Changes in the parameters of the cell model after injury were explored and analyzed, and their potential for characterizing hepatocellular injury and related treatments was evaluated.Research Highlights

This study aims to establish an in vitro hyperelastic model of liver cells and analyze the mechanical changes of cells in vitro.

An analysis method combining finite element analysis model and nanoindentation was used to obtain the key parameters of the model.

The multi‐depth mechanical differences and internal structural changes of injured liver cells were analyzed.

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肝细胞粘弹性特性的多深度定量分析纳米压痕和有限元建模技术的融合

肝细胞是肝脏的基本功能单位。然而，反复或持续的损伤会导致肝小叶结构紊乱、纤维组织增生和结构变化，从而增加疤痕组织。细胞纤维化会影响组织硬度、剪切力和其他细胞机械力。机械力特征可作为细胞损伤和肝硬化的重要指标。原子力显微镜（AFM）已被广泛用于研究细胞表面力学。然而，肝细胞内部深层机械特性的表征仍是一个欠发达的领域。在这项工作中，细胞纳米压痕与有限元分析相结合，模拟和分析了肝细胞在体外不同深度的力学响应，以及在受到正常应力后的内部响应和应力扩散分布。比较了有限元模型的粘弹性参数对峰值力和平衡力影响的敏感性。测量了不同深度酒精损伤肝细胞的受力曲线，并与未损伤肝细胞的受力曲线进行了比较。采用反分析方法对有限元模型进行了体外模拟。研究亮点本研究旨在建立肝细胞体外超弹性模型，分析细胞在体外的力学变化。采用有限元分析模型和纳米压痕相结合的分析方法，获得了模型的关键参数。分析了损伤肝细胞的多深度力学差异和内部结构变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microscopy Research and Technique 医学-解剖学与形态学

CiteScore

5.30

自引率

20.00%

发文量

233

审稿时长

4.7 months

期刊介绍： Microscopy Research and Technique (MRT) publishes articles on all aspects of advanced microscopy original architecture and methodologies with applications in the biological, clinical, chemical, and materials sciences. Original basic and applied research as well as technical papers dealing with the various subsets of microscopy are encouraged. MRT is the right form for those developing new microscopy methods or using the microscope to answer key questions in basic and applied research.