微流控装置中氧梯度的产生和缺氧中的细胞分析(特别社论:ABE的五篇精选文章)

Hideyuki Uchida, Asako Sato, A. Miyayama
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引用次数: 8

摘要

缺氧相关机制在肿瘤生物学和免疫应答中具有重要意义。血液通过异常和功能失调的微血管向肿瘤组织输送氧气,导致肿瘤内组织氧合不均匀。缺氧条件在指导血管生成、引导免疫细胞、诱导肿瘤转移等方面发挥作用。在体外细胞实验中模拟这种氧梯度对于阐明参与肿瘤生物学的机制非常重要。以前的研究已经导致了产生氧梯度的细胞培养装置的发展,但不可能在细胞培养过程中监测氧梯度。在本研究中,我们设计了一种带有氧敏膜的开孔聚二甲基硅氧烷(PDMS)微流控装置,该装置可以测量细胞周围的氧气,并在细胞培养实验后进行分子分析。数学模拟和基于磷光的局部氧测量表明,根据各种生物模型的要求,可以通过改变微通道内的氧气浓度来控制梯度。单一培养的内皮细胞暴露于设备中的氧梯度显示缺氧区氧反应基因的表达增加。这些结果表明我们的微流控装置可以用于体外实验,如基因表达和迁移分析。我们相信这种新设备是肿瘤生物学和免疫学研究的有力工具。
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Generation of an Oxygen Gradient in a Microfluidic Device and Cellular Analysis in Hypoxia (Special Editorials : Five Selected Articles in ABE)
Hypoxia-related mechanisms are important in tumor biology and immune responses. Oxygen is delivered to tumor tissue by blood flowing through abnormal and dysfunctional microvessels, resulting in heterogeneity of tissue oxygenation within the tumor. Hypoxic conditions play a role in directing angiogenesis, guiding immune cells, and inducing tumor metastasis. Mimicking such oxygen gradient in in vitro cellular experiments is important to clarify the mechanisms involved in tumor biology. Previous research has led to the development of cell culture devices that generate an oxygen gradient, but it was impossible to monitor the oxygen gradient during cell culture. In this study, we designed an open-well polydimethylsiloxane (PDMS) microfluidic device integrated with an oxygen-sensitive film, which permits oxygen measurement around cells and molecular analysis after cell culture experiments. Mathematical simulation and phosphorescence-based partial oxygen measurements show that the gradient can be controlled by changing the oxygen gas concentration inside the microchannels, according to the requirements of various biological models. A monoculture of endothelial cells exposed to an oxygen gradient in the device showed increased expression of oxygen-responsive genes in the hypoxic area. These results suggest that our microfluidic device can be used for in vitro experiments such as gene expression and migration assays. We believe that this new device is a powerful tool for studies of tumor biology and immunology.
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