Three-dimensional ready-to-pick reservoir-based preconcentrator with a pillar-structured channel for miRNA applications

Frontiers in sensors Pub Date : 2022-11-22 DOI:10.3389/fsens.2022.1066974

Seungmin Lee, Jinhwan Kim, Nalae Lee, Kang-Hyeon Kim, Seong Jun Park, J. Park, Cheonjung Kim, Ji Hye Hong, D. Yoon, Y. Yoo, Jeong-Hoon Lee

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引用次数: 1

Abstract

A sample preconcentration technique that exceeds a microfluidic device’s limited processing volume (up to microliters) is critical for real sample pretreatment applications. Here, we have developed a 3D-printed preconcentrator with a pillar structure (3DP2) to enrich the biological samples up to hundreds of microliter scales (700 μL) within 20 min by utilizing ion concentration polarization (ICP). We designed three-dimensional ready-to-pick reservoirs serially connected with a pillar-structured channel to enable large-volume preconcentration by balancing the preconcentrating forces (depletion, electrophoretic, and electroosmotic force) generated by ICP. Using the I-t and I-V curves, we confirmed that ICP performance was enhanced due to a pillar structure’s suppression of the vortex. Finally, we preconcentrated bovine serum albumin (BSA) and micro ribonucleic acid-21 (miRNA-21) two-fold. Moreover, depending on their size and charge, these were concentrated at different locations and could be extracted easily using pipettes. We believe that this study provides a novel strategy for downstream applications.

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具有柱状结构通道的miRNA应用的三维蓄水池预选器

超过微流体设备有限处理体积（高达微升）的样品预浓缩技术对于实际样品预处理应用至关重要。在这里，我们开发了一种具有柱状结构的3D打印预浓缩器（3DP2），通过利用离子浓度极化（ICP）在20分钟内富集数百微升级（700μL）的生物样品。我们设计了与柱状结构通道串联的三维即采储层，通过平衡ICP产生的预浓缩力（耗尽力、电泳力和电渗力）实现大体积预浓缩。使用I-t和I-V曲线，我们证实了由于柱状结构对涡流的抑制，ICP性能得到了增强。最后，我们将牛血清白蛋白（BSA）和微小核糖核酸-21（miRNA-21）预浓缩两倍。此外，根据它们的大小和电荷，这些物质被集中在不同的位置，可以使用移液管轻松提取。我们相信，这项研究为下游应用提供了一种新的策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Frontiers in sensors

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