Abstract
Abstract Aiming at the problem of poor construction accuracy of the cellular three-dimensional (3D) mechanical microenvironment, this article studies the cellular 3D mechanical microenvironment based on machine vision. The gelatin methacrylate microgel column was prepared by NIH/3T3 mouse fibroblast and precursor solution of gelatin methacrylate microgel. The gelatin methacrylate microgel array with magnetic end was adopted. The external magnetic field was used to load microgel array and build 3D mechanics microenvironment model. The deformed pictures of hydrogel under magnetic field were obtained by fluorescence microscope. The scanning electron microscope was used to characterize the pore structure of gelatin methacrylate hydrogel. The pictures obtained by machine vision method were used to calculate the deformed parameters of sample. The machine vision method adopted the discrete cosine transform for autofocus, and then used the image analysis and processing technology to identify and estimate the cell motion parameters. After getting the cell motion parameters, Comsol multiphysics (COMSOL) multiphysics multifield coupling finite element analysis software was adopted. The correlative numerical simulation method and gel deformed simulation method were used to obtain the mechanical changes of cells in the 3D mechanical microenvironment. Experimental results show that the modulus of gelatin methacrylate microgel is changed significantly during the tensile loading. The tensile strain and the cell spreading area are nonlinearly related. The increase in stiffness of the hydrogel substrate helps to promote cell proliferation to a certain extent.
Highlights
Somatic cells are in a complex microenvironment
It is significant to carry out an interdisciplinary research on the three-dimensional (3D) mechanical microenvironment of cells and clarify the interaction between the mechanical stimulation signal and life activities [1]
SensoPart V20C-CO-A2-C camera, CX-2000 ultraviolet cross linker made in UVP Company (USA), ShanShi SS-150 scanning electron microscope (SEM), NanoFocus laser confocal microscope, Olympus X81 fluorescence microscope made in Japan, Thermo Scientific cell incubator, Beckman flow cytometer, Beckman Coulter high-speed centrifuge, freeze desiccant, electric displacement platform made in Beijing Weina optical automation equipment Co., Ltd., IKA constant temperature magnetic force agitator, and baking oven of Tianjin Taist Instrument Co., Ltd
Summary
Somatic cells are in a complex microenvironment. The dynamic balance of microenvironment is the basis of maintaining the normal behavior of cell. More researches show that mechanical stimulation signals exist widely in the cell microenvironment and play an important role in regulating the cell behavior. It is significant to carry out an interdisciplinary research on the three-dimensional (3D) mechanical microenvironment of cells and clarify the interaction between the mechanical stimulation signal and life activities [1]. A set of algebraic equations, which takes the node displacement as unknown quantity, can be obtained. The existing calculation methods can be used to get the approximate value of unknown quantity at the node [2]. According to the relationship between node force and displacement, the algebraic equations taking node displacement as unknown quantities are established, so that the problem is simplified into a structural problem, which is suitable for a numerical solution [3]
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