A single-cell 3D dynamic volume control system for chondrocytes.

IF 2.2 4区 工程技术 Q3 BIOCHEMICAL RESEARCH METHODS BioTechniques Pub Date : 2024-10-15 DOI:10.1080/07366205.2024.2412414
Qiang Zhang, Yiyao Wang, Yanjun Zhang, Xiaochun Wei, Weiyi Chen, Quanyou Zhang
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Abstract

In articular cartilage, zone-specific cellular morphology is a typical characteristic of cartilage tissue, which is related with chondrocyte function, inflammation and osteoarthritis (OA). Chondrocyte hypertrophic phenotype is a criticle physiological process which indicates a hallmark of chondrocyte terminal differentiation and bone formation. Thus, developing a in vitro cell culture system for dynamic regulation of single chondrocyte volume at a three-dimensional (3D) level is particularly necessary for understanding how physical cues of matrix microenvironment regulate chondrocyte fate and the degeneration of articular cartilage. Here, based on the soft lithography techniques, we have constructed well-defined single-cell 3D dynamic volume control system to recapitulate the physiological matrix microenvironment of single chondrocyte niche. The results of finite element analysis indicated that the stress and strain distribution in the cell culture region is homogeneous during the stretching process. Additionally, 3D dynamic volume expansion and compression of single cells in physiological or hyperphysiological can be realized in this cell culture system. Our device for single-cell 3D dynamic culture provides a microphysiological culture system for chondrocytes to explore the mechanisms of cartilage hypertrophy, as well as develops a new paradigm for functional cartilage tissue engineering and regenerative medicine.

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软骨细胞单细胞三维动态体积控制系统
在关节软骨中,区域特异性细胞形态是软骨组织的典型特征,与软骨细胞功能、炎症和骨关节炎(OA)有关。软骨细胞肥大表型是一个关键的生理过程,是软骨细胞末端分化和骨形成的标志。因此,开发一种可在三维(3D)水平上动态调节单个软骨细胞体积的体外细胞培养系统,对于了解基质微环境的物理线索如何调控软骨细胞的命运和关节软骨的退化尤为必要。在此,我们基于软光刻技术构建了定义明确的单细胞三维动态体积控制系统,以再现单个软骨细胞龛的生理基质微环境。有限元分析结果表明,在拉伸过程中,细胞培养区域的应力和应变分布是均匀的。此外,该细胞培养系统还能实现单细胞在生理或超生理状态下的三维动态体积膨胀和压缩。我们的单细胞三维动态培养装置为软骨细胞提供了一个微生理学培养系统,用于探索软骨肥大的机制,并为功能性软骨组织工程和再生医学开发了一种新的范例。
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来源期刊
BioTechniques
BioTechniques 工程技术-生化研究方法
CiteScore
4.40
自引率
0.00%
发文量
68
审稿时长
3.3 months
期刊介绍: BioTechniques is a peer-reviewed, open-access journal dedicated to publishing original laboratory methods, related technical and software tools, and methods-oriented review articles that are of broad interest to professional life scientists, as well as to scientists from other disciplines (e.g., chemistry, physics, computer science, plant and agricultural science and climate science) interested in life science applications for their technologies. Since 1983, BioTechniques has been a leading peer-reviewed journal for methods-related research. The journal considers: Reports describing innovative new methods, platforms and software, substantive modifications to existing methods, or innovative applications of existing methods, techniques & tools to new models or scientific questions Descriptions of technical tools that facilitate the design or performance of experiments or data analysis, such as software and simple laboratory devices Surveys of technical approaches related to broad fields of research Reviews discussing advancements in techniques and methods related to broad fields of research Letters to the Editor and Expert Opinions highlighting interesting observations or cautionary tales concerning experimental design, methodology or analysis.
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