基于微通道选通的靶向细胞检测。
Targeted cell detection based on microchannel gating.
机构信息
Electrical Engineering Department, Stanford University, Stanford, California 94305, USA and Stanford Genome Technology Center, Palo Alto, California 94304, USA.
出版信息
Biomicrofluidics. 2007 Nov 30;1(4):44103. doi: 10.1063/1.2815760.
Abstract
Currently, microbiological techniques such as culture enrichment and various plating techniques are used for detection of pathogens. These expensive and time consuming methods can take several days. Described below is the design, fabrication, and testing of a rapid and inexpensive sensor, involving the use of microelectrodes in a microchannel, which can be used to detect single bacterial cells electrically (label-free format) in real time. As a proof of principle, we have successfully demonstrated real-time detection of target yeast cells by measuring instantaneous changes in ionic impedance. We have also demonstrated the selectivity of our sensors in responding to target cells while remaining irresponsive to nontarget cells. Using this technique, it can be possible to multiplex an array of these sensors onto a chip and probe a complex mixture for various types of bacterial cells.
摘要
目前,微生物学技术(如培养富集和各种平板技术)用于检测病原体。这些昂贵且耗时的方法可能需要数天时间。下面描述了一种快速且廉价的传感器的设计、制造和测试,该传感器涉及在微通道中使用微电极,可以实时(无标记格式)电检测单个细菌细胞。作为原理验证,我们通过测量离子阻抗的瞬时变化成功地演示了实时检测目标酵母细胞。我们还证明了我们的传感器在响应目标细胞的同时对非目标细胞不响应的选择性。使用这种技术,可以将这些传感器的阵列多路复用到芯片上,并探测复杂混合物中各种类型的细菌细胞。
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