Spinning magnetic trap for automated microfluidic assay systems

微通道 微流控 有孔小珠 样品(材料) 旋转(数学) 纺纱 磁铁 材料科学 混合(物理) 存水弯(水管) 转速 炸薯条 纳米技术 样品制备 机械工程 计算机科学 色谱法 化学 工程类 电气工程 物理 复合材料 人工智能 环境工程 量子力学
作者
Jasenka Verbarg,Kian Kamgar‐Parsi,Adam R. Shields,Peter B. Howell,Frances S. Ligler
出处
期刊:Lab on a Chip [Royal Society of Chemistry]
卷期号:12 (10): 1793-1793 被引量:39
标识
DOI:10.1039/c2lc21189k
摘要

While sophisticated analyses have been performed using lab-on-chip devices, in most cases the sample preparation is still performed off chip. The global need for easy-to-use, disposable testing devices necessitates that sample processing is automated and that transport complexity between the processing and analytical components is minimal. We describe a complete sample manipulation unit for performing automated target capture, efficient mixing with reagents, and controlled target release in a microfluidic channel, using an array of spinning magnets. The "MagTrap" device consists of 6 pairs of magnets in a rotating wheel, situated immediately beneath the microchannel. Rotation of the wheel in the direction opposite to the continuous flow entraps and concentrates the bead-target complexes and separates them from the original sample matrix. As the wheel rotates and the active pair of magnets moves away from the microchannel, the beads are released and briefly flow downstream before being trapped and pulled upstream by the next pair of magnets. This dynamic and continuous movement of the beads ensures that the full surface area of each bead is exposed to reagents and prevents aggregation. The release of the target-bead complexes for further analysis is facilitated by reversing the rotational direction of the wheel to sweep the beads downstream. Sample processing with the MagTrap was demonstrated for the detection of E. coli in a range of concentrations (1 × 10(3), 1 × 10(4) and 1 × 10(6) cells ml(-1)). Results show that sample processing with the MagTrap outperformed the standard manual protocols, improving the detection capability while simultaneously reducing the processing time.
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