用于仿生细胞培养支架的水凝胶微加工和图案的实用指南

Maria Tenje , Federico Cantoni , Ana María Porras Hernández , Sean S. Searle , Sofia Johansson , Laurent Barbe , Maria Antfolk , Hannah Pohlit
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引用次数: 43

摘要

这篇综述文章描述了微加工技术来定义水凝胶中的化学、机械和结构模式,以及如何将这些技术用于制备体内的细胞培养支架,即仿生支架。水凝胶是3D细胞培养的有吸引力的材料,因为它们提供了理想的培养条件,并且它们的应用越来越突出。然而,未经任何修饰的单一材料凝胶在使用上有其局限性,通过提高简单水凝胶细胞培养支架的体内相似性可以获得很多好处。这篇综述文章讨论了水凝胶培养支架最常用的交联策略,并简要介绍了微制造方法,这些方法可用于以微米分辨率定义水凝胶中的化学、机械和结构模式。综述文章还介绍了使用这些微加工技术制备具有控制细胞粘附、增殖和迁移的器官和疾病模型的文献参考。它旨在作为水凝胶微加工的介绍,并为新的跨学科研究项目提供灵感。
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A practical guide to microfabrication and patterning of hydrogels for biomimetic cell culture scaffolds

This review article describes microfabrication techniques to define chemical, mechanical and structural patterns in hydrogels and how these can be used to prepare in vivo like, i.e. biomimetic, cell culture scaffolds. Hydrogels are attractive materials for 3D cell cultures as they provide ideal culture conditions and they are becoming more prominently used. Single material gels without any modifications do however have their limitation in use and much can be gained by in improving the in vivo resemblance of simple hydrogel cell culture scaffolds. This review article discusses the most commonly used cross-linking strategies used for hydrogel-based culture scaffolds and gives a brief introduction to microfabrication methods that can be used to define chemical, mechanical and structural patterns in hydrogels with micrometre resolution. The review article also describes a selection of literature references using these microfabrication techniques to prepare organ and disease models with controlled cell adhesion, proliferation and migration. It is intended to serve as an introduction to microfabrication of hydrogels and an inspiration for novel interdisciplinary research projects.

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来源期刊
Organs-on-a-chip
Organs-on-a-chip Analytical Chemistry, Biochemistry, Genetics and Molecular Biology (General), Cell Biology, Pharmacology, Toxicology and Pharmaceutics (General)
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审稿时长
125 days
期刊最新文献
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