具有多荧光微传感器的微流控芯片，用于培养环境的时空传感

2017 IEEE 30th International Conference on Micro Electro Mechanical Systems (MEMS) Pub Date : 1900-01-01 DOI:10.1109/MEMSYS.2017.7863422

H. Maruyama, Keisuke Takagi, T. Masuda, O. Suzuki, F. Arai

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引用次数: 0

摘要

我们提出了利用荧光多微传感器监测细胞与环境相互作用的片上时空传感技术。利用集成荧光多微传感器的微流控芯片，构建与体内相似的和谐环境，在体外重建高质量器官。荧光传感适用于高空间分辨率的时空传感，因为连接多个微传感器限制了传感器的数量。首先，对光学传感方法进行分类。荧光和极化传感适合于培养环境中生理和机械参数的时空传感。作为培养环境时空感知的演示，利用荧光多微传感器测量了微流控芯片内磷酸八钙(OCP)向羟基磷灰石(HA)转化过程中pH、Ca2+的时空变化。

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Microfluidic chip having multi fluorescence microsensors for spatiotemporal sensing of culture environment

We proposed on-chip spatiotemporal sensing for monitoring interactions between cells and environment using fluorescence multi-microsensors. The microfluidic chip integrating fluorescence multi-microsensor is used to construct the harmonious environment like in vivo to reconstruct high-quality organs ex vivo. Fluorescence sensing is suitable for spatiotemporal sensing with high spatial resolution because wiring to many microsensors limits the number of sensors. First, we classify optical sensing method. Fluorescence and polarization sensing are suitable for spatiotemporal sensing such as physiological and mechanical parameters in culture environment. As a demonstration of spatiotemporal sensing of culture environment, Spatiotemporal variation of pH, Ca2+ was measured and during transformation of octacalcium phosphate (OCP) to hydroxyl apatite (HA) inside the microfluidic chip using fluorescence multi-microsensors.

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2017 IEEE 30th International Conference on Micro Electro Mechanical Systems (MEMS)

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