基于电渗流驱动的带有微井阵列的微流控芯片上的单细胞电裂解。

Single-cell electric lysis on an electroosmotic-driven microfluidic chip with arrays of microwells.

机构信息

Department of Mechanical Engineering, Advanced Institute of Manufacturing with High-Tech Innovation, National Chung Cheng University, Chia Yi, Taiwan.

出版信息

Sensors (Basel). 2012;12(6):6967-77. doi: 10.3390/s120606967. Epub 2012 May 25.

DOI:10.3390/s120606967

PMID:22969331

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3435960/

Abstract

Accurate analysis at the single-cell level has become a highly attractive tool for investigating cellular content. An electroosmotic-driven microfluidic chip with arrays of 30-μm-diameter microwells was developed for single-cell electric lysis in the present study. The cellular occupancy in the microwells when the applied voltage was 5 V (82.4%) was slightly higher than that at an applied voltage of 10 V (81.8%). When the applied voltage was increased to 15 V, the cellular occupancy in the microwells dropped to 64.3%. More than 50% of the occupied microwells contain individual cells. The results of electric lysis experiments at the single-cell level indicate that the cells were gradually lysed as the DC voltage of 30 V was applied; the cell was fully lysed after 25 s. Single-cell electric lysis was demonstrated in the proposed microfluidic chip, which is suitable for high-throughput cell lysis.

摘要

单细胞水平的精确分析已成为研究细胞内容的极具吸引力的工具。本研究开发了一种电渗流驱动的微流控芯片，其带有 30μm 直径微孔的阵列。当施加的电压为 5 V（82.4%）时，微孔中的细胞占有率略高于施加 10 V（81.8%）时的细胞占有率。当施加的电压增加到 15 V 时，微孔中的细胞占有率下降到 64.3%。超过 50%的占用微孔包含单个细胞。单细胞电裂解实验的结果表明，随着施加的直流电压 30 V 的增加，细胞逐渐被裂解；25 秒后细胞完全裂解。在提出的微流控芯片中证明了单细胞电裂解，该芯片适用于高通量细胞裂解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/70aa/3435960/45bcbc7e7d69/sensors-12-06967f1.jpg

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基于电渗流驱动的带有微井阵列的微流控芯片上的单细胞电裂解。

Single-cell electric lysis on an electroosmotic-driven microfluidic chip with arrays of microwells.

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