Design and microfabrication of fluidic device for separation of organelles

机译：细胞器分离流体装置的设计与微生物

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In proteomics and signal transduction studies, the demand to identify the location and amount of proteins poses challenges to subcellular separation and sample preparations. Current technologies involve laborious and time-consuming procedures that require large sample volumes (＞10{sup}6 cells). For protein profiling, the organelle separation needs to be fast, parallel, and automated to match the great number of experiments needed. In this study, we devise a scheme for using isoelectric focusing in micro scale to achieve the isolation of organelles much faster than in conventional methods. The device was modeled and microfabricated, and mitochondria from cultured human epithelial cells were shown to be isolated.

机译：在蛋白质组学和信号转导研究中，要求识别蛋白质的位置和数量对亚细胞分离和样品制剂构成挑战。目前的技术涉及需要大样本量（> 10 {Sup} 6细胞）的费力和耗时的程序。对于蛋白质分析，细胞器分离需要快速，平行，自动化，以匹配所需的大量实验。在这项研究中，我们设计了一种使用等电聚焦在微尺度中使用的方案，以实现细胞器的分离比传统方法更快。该装置是模拟的，并显示微制成的，并且来自培养的人上皮细胞的线粒体被分离出来。

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《Annual International IEEE-EMBS Special Topic Conference on Microtechnologies in Medicine Biology》|2002年||共4页
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作者
H. Lu; M. A. Schmidt; K. F. Jensen;
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中图分类 R-53;
关键词
Cellular analysis; Mitochondria; Isoelectric focusing; Numerical simulation;

机译：细胞分析;线粒体;等电聚焦;数值模拟;

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专利

1. In-channel integration of designable microoptical devices using flat scaffold-supported femtosecond-laser microfabrication for coupling-free optofluidic cell counting [J] . Dong Wu, Jian Xu, Li-Gang Niu, Light: Science & Applications . 2015,第1期

机译：使用扁平支架支撑的飞秒激光微加工技术对可设计微光学器件进行通道内集成，以实现无耦合的光流细胞计数
2. Corrigendum: In-channel integration of designable microoptical devices using flat scaffold-supported femtosecond-laser microfabrication for coupling-free optofluidic cell counting [J] . Dong Wu, Jian Xu, Li-Gang Niu, Light: Science & Applications . 2015,第2期

机译：更正：使用平面支架支撑的飞秒激光微加工技术对可设计微光学器件进行通道内集成，以实现无耦合的光流细胞计数
3. Design and evaluation of microfluidic devices for two-dimensional spatial separations [J] . Davydova Ekaterina, Wouters Sam, Deridder Sander, Journal of chromatography, A: Including electrophoresis and other separation methods . 2016,第Null期

机译：二维空间分离微流控装置的设计与评估
4. Design and microfabrication of fluidic device for separation of organelles [C] . Lu, H., Schmidt, . 2002

机译：用于分离细胞器的流体装置的设计和微加工
5. Towards multidimensional separations of cerebrospinal fluid proteins in microfluidic devices. [D] . Li, Chen. 2005

机译：迈向微流体装置中脑脊液蛋白质的多维分离。
6. Milling Positive Master for Polydimethylsiloxane Microfluidic Devices: The Microfabrication and Roughness Issues [O] . Zhizhi Zhou, Dong Chen, Xiang Wang, 2017

机译：聚二甲基硅氧烷微流控设备的正铣削母版：微加工和粗糙度问题
7. Erratum: Corrigendum: In-channel integration of designable microoptical devices using flat scaffold-supported femtosecond-laser microfabrication for coupling-free optofluidic cell counting [O] . Dong Wu, Jian Xu, Li-Gang Niu, 2015

机译：错误：勘误：使用平衡支架支持的FemtoSecond-Laser微制造的可设计微光学器件的通道集成，用于无耦合的Optiof流体电池计数
8. Conditions for Fluid Separations in Microchannels, Capillary-Driven Fluid Separations, and Laminated Devices Capable of Separating Fluids. [R] . TeGrotenhius, W. E., Stenkamp, V. S. 2005

机译：微通道，毛细管驱动的流体分离和能够分离流体的层压装置中的流体分离条件。

Design and microfabrication of fluidic device for separation of organelles

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