Tazawa Hidekatsu, Mawatari Kazuma
Graduate School of Information, Production and Systems, Waseda University, 2-7 Hibikino, Wakamatsu, Kitakyushu, Fukuoka, 808-0135, Japan.
Anal Sci. 2024 Dec;40(12):2175-2180. doi: 10.1007/s44211-024-00654-z. Epub 2024 Aug 30.
Highly sensitive quantitative analysis of liquids is required in various fields. Analytical instruments and devices such as chromatography, spectroscopic analysis, DNA sequencers, immunoassay, mass spectrometry, and microfluidic devices are utilized for this purpose. Typically, the sample volume is at the milliliter scale, while the analysis volume is at the microliter scale. Consequently, most of the sample is discarded. Therefore, a universal volume interface is required to quantitatively concentrate samples from milliliter to microliter volume. This study introduces a liquid quantitative function to the cyclone concentration method using a millimeter-scale channel, which is highly suitable for controlling liquids at the microliter scale due to its high fluidic resistance against cyclone flow. This method enables the effective control of liquid concentration by cyclone flow. The optimum channel structure is investigated, and a 33-fold concentration of aqueous solutions is demonstrated. Finally, the concentration device is applied to measure molybdenum ions in a river.
各个领域都需要对液体进行高灵敏度的定量分析。为此会使用各种分析仪器和设备,如色谱仪、光谱分析仪、DNA测序仪、免疫测定仪、质谱仪和微流控设备。通常,样品体积为毫升级,而分析体积为微升级。因此,大部分样品被丢弃。所以,需要一个通用的体积接口来将样品从毫升体积定量浓缩至微升体积。本研究将液体定量功能引入到使用毫米级通道的旋风浓缩法中,该通道由于对旋风流具有高流体阻力,非常适合控制微升级的液体。此方法能够通过旋风流有效地控制液体浓度。研究了最佳通道结构,并证明了对水溶液有33倍的浓缩效果。最后,将该浓缩装置应用于测量河流中的钼离子。