Two chemistries on a single lab-on-chip: Nitrate and orthophosphate sensing underwater with inlaid microfluidics

Frontiers in sensors Pub Date : 2022-12-07 DOI:10.3389/fsens.2022.1080020

Edward Luy, James Smith, Iain Grundke, C. Sonnichsen, A. Furlong, V. Sieben

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Abstract

Autonomous in situ sensors are required to monitor high-frequency nutrient fluctuations in marine environments on a mass-scale. We present a submersible, dual-chemistry sensor that performs multiple colourimetric assays simultaneously on a fluid sample for multi-parameter in situ analysis. Based on a highly configurable architecture that has been successfully deployed for several multi-month periods, the sensor utilizes 10 solenoid valves, 4 syringes, 3 stepper motors, 2 LEDs, 4 photodiodes, and “inlaid” microfluidics to permit optical measurements of microliter fluid volumes. Fluid pathways are machined into a modular two-layer microfluidic lab-on-chip (LOC) fabricated from poly (methyl methacrylate) (PMMA) with two parallel inlaid optical cells of 10.4 mm and 25.4 mm path lengths (1.7 µl and 4 μl, respectively). Different LOC designs can be used to implement a wide variety of colorimetric assays. We demonstrate application of our dual-chemistry sensor towards simultaneous measurement of nitrate and dissolved orthophosphate: two nutrients fundamental to primary production. The performance of the dual-species nitrate and phosphate “NP Sensor” is characterized first in a controlled laboratory environment. Combined nutrient standards containing nitrate and phosphate concentrations ranging from 2.5 µM–100 µM N O 3 − and 0.25 µM–10 µM P O 4 3 − were analyzed, reporting detection limits of 97 nM N O 3 − and 15 nM P O 4 3 − . Calibrations were repeated under 3 fixed temperature conditions, T = 5°C, 10°C, 15°C, to determine the temperature-dependent sensitivity relations for both species needed to calculate concentrations during field deployments. Finally, an 8-day field deployment in Fish Hatchery Park, NS, Canada followed, acquiring a total of 592 nitrate and dissolved orthophosphate measurements. An on-board combined nutrient standard was measured periodically to assess the in situ accuracy of the sensor, with an average relative uncertainty of 15% across the deployment. Measured nitrate and dissolved orthophosphate levels in the river reached as high as 10 µM and 3.6 µM, respectively. Fast Fourier transform analysis suggests a strong out-of-phase relationship between measured phosphate and water level, with a shared frequency peak in both data agreeing within a 3.2% difference. This trend is due to conventional mixing at the river mouth to neighboring Bedford Basin. A spike in the measured nitrate to phosphate (N:P) ratio was also observed, synchronized to a precipitation event and indicative of runoff. The novel sensor will enable high-frequency dual-nutrient monitoring in many aquatic environments. Graphical Abstract

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芯片上单个实验室的两种化学物质：嵌入微流体的水下硝酸盐和正磷酸盐传感

需要自主的原位传感器来大规模监测海洋环境中的高频营养物质波动。我们提出了一种潜水式双化学传感器，它可以对流体样品同时进行多种色度测定，用于多参数原位分析。基于已成功部署数个月的高度可配置架构，该传感器利用10个电磁阀、4个注射器、3个步进电机、2个LED、4个光电二极管和“嵌入式”微流体，实现微升流体体积的光学测量。流体通道被加工成模块化的两层微流体芯片实验室（LOC），该实验室由聚甲基丙烯酸甲酯（PMMA）制成，具有两个平行镶嵌的光学单元，路径长度分别为10.4 mm和25.4 mm（分别为1.7µl和4μl）。不同的LOC设计可用于实施各种各样的比色测定。我们展示了我们的双化学传感器在同时测量硝酸盐和溶解的正磷酸盐方面的应用：这两种营养素是初级生产的基础。硝酸盐和磷酸盐双物种“NP传感器”的性能首先在受控的实验室环境中进行了表征。分析了硝酸盐和磷酸盐浓度范围为2.5µM–100µM N O 3−和0.25µM–10µM P O 4 3−的联合营养标准品，报告检测限为97 nM N O 3–和15 nM P O 3−。在T=5°C、10°C、15°C的3个固定温度条件下重复校准，以确定两种物种在野外部署期间计算浓度所需的温度相关灵敏度关系。最后，在加拿大NS的Fish Hatchery Park进行了为期8天的实地部署，共获得592份硝酸盐和溶解正磷酸盐测量结果。定期测量机载组合营养素标准，以评估传感器的原位精度，整个部署的平均相对不确定度为15%。河流中的硝酸盐和溶解正磷酸盐含量分别高达10µM和3.6µM。快速傅立叶变换分析表明，测得的磷酸盐和水位之间存在强烈的异相关系，两个数据中的共享频率峰值相差3.2%。这一趋势是由于河口到邻近贝德福德盆地的传统混合造成的。还观察到测得的硝酸盐与磷酸盐（N:P）的比值出现峰值，与降水事件同步，表明径流。这种新型传感器将能够在许多水生环境中进行高频双营养监测。图形摘要

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Frontiers in sensors

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