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Journal
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Bioengineering
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细胞电微环境的有限元素建模
JoVE Journal
Bioengineering
This content is Free Access.
JoVE Journal
Bioengineering
Finite Element Modelling of a Cellular Electric Microenvironment
Please note that all translations are automatically generated.
Click here for the English version.
细胞电微环境的有限元素建模
DOI:
10.3791/61928-v
•
08:23 min
•
May 18, 2021
•
Miruna Verdes
,
Catherine Disney
,
Chinnawich Phamornnak
,
Lee Margetts
,
Sarah Cartmell
3
1
Department of Materials, Faculty of Science and Engineering
,
The University of Manchester
,
2
Department of Mechanical, Aerospace and Civil Engineering, Faculty of Science and Engineering
,
The University of Manchester
,
3
The Henry Royce Institute, Royce Hub Building
,
The University of Manchester
Chapters
00:04
Introduction
00:44
Build the Model in COMSOL
03:57
Perform Simulation
05:12
Analysis
06:38
Results: Influence of Fiber Alignment on Electric Field
07:42
Conclusion
Summary
Automatic Translation
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Automatic Translation
本文提出了构建暴露在电场 (EF) 中的纤维导电材料的有限元素模型的策略。这些模型可用于估计在此类材料中播种的细胞接收到的电气输入,并评估改变脚手架的成分材料属性、结构或方向的影响。
Tags
Finite Element Modeling
Cellular Electric Microenvironment
Extracellular Matrix
Electrical Stimulation
COMSOL
Material Properties
Electrical Conductivity
Relative Permittivity
3D Modeling
Parameter Optimization
Electric Current Module
Boundary Conditions
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