Lab-on-Chip for In Situ Analysis of Nutrients in the Deep Sea

Alexander D Beaton,Christopher L Cardwell,Andrew Morris,Urska Martincic,Matthew C Mowlem,Susan E Hartman,Kevin Saw,Robin Pascal,Allison M Schaap,Geraldine Clinton-Bailey,Rudolf Hanz

doi:10.1021/acssensors.1c01685

Alexander D Beaton, Christopher L Cardwell + Show 9 more

Open Access

https://doi.org/10.1021/acssensors.1c01685

Copy DOI

Journal: ACS Sensors	Publication Date: Jan 12, 2022
Citations: 15	License type: CC BY 4.0

Affiliation: National Oceanography Centre

Abstract

Microfluidic reagent-based nutrient sensors offer a promising technology to address the global undersampling of ocean chemistry but have so far not been shown to operate in the deep sea (>200 m). We report a new family of miniaturized lab-on-chip (LOC) colorimetric analyzers making in situ nitrate and phosphate measurements from the surface ocean to the deep sea (>4800 m). This new technology gives users a new low-cost, high-performance tool for measuring chemistry in hyperbaric environments. Using a combination of laboratory verification and field-based tests, we demonstrate that the analyzers are capable of in situ measurements during profiling that are comparable to laboratory-based analyses. The sensors feature a novel and efficient inertial-flow mixer that increases the mixing efficiency and reduces the back pressure and flushing time compared to a previously used serpentine mixing channel. Four separate replicate units of the nitrate and phosphate sensor were calibrated in the laboratory and showed an average limit of detection of 0.03 μM for nitrate and 0.016 μM for phosphate. Three on-chip optical absorption cell lengths provide a large linear range (to >750 μM (10.5 mg/L-N) for nitrate and >15 μM (0.47 mg/L-P) for phosphate), making the instruments suitable for typical concentrations in both ocean and freshwater aquatic environments. The LOC systems automatically collected a series of deep-sea nitrate and phosphate profiles in the northeast Atlantic while attached to a conductivity temperature depth (CTD) rosette, and the LOC nitrate sensor was attached to a PROVOR profiling float to conduct automated nitrate profiles in the Mediterranean Sea.

Highlights

Microfluidic reagent-based nutrient sensors offer a promising technology to address the global undersampling of ocean chemistry but have so far not been shown to operate in the deep sea (>200 m)
Atlantic while attached to a conductivity temperature depth (CTD) rosette, and the LOC nitrate sensor was attached to a PROVOR profiling float to conduct automated nitrate profiles in the Mediterranean Sea
This work describes miniaturized chemical analyzers that are capable of nutrient analysis in the deep sea (field proven to 4800 m and 2100 m)

Summary

Introduction

Atlantic while attached to a conductivity temperature depth (CTD) rosette, and the LOC nitrate sensor was attached to a PROVOR profiling float to conduct automated nitrate profiles in the Mediterranean Sea. T here have been major advances in the development of in situ oceanographic chemical sensors,[1] but it is still the case that the vast majority of ocean chemistry data are obtained using research ships to collect individual seawater samples that are either analyzed in shipboard laboratories or preserved and transported for later analysis on land. T here have been major advances in the development of in situ oceanographic chemical sensors,[1] but it is still the case that the vast majority of ocean chemistry data are obtained using research ships to collect individual seawater samples that are either analyzed in shipboard laboratories or preserved and transported for later analysis on land This approach is expensive and time consuming but results in low-resolution data sets, meaning that the world’s ocean chemistry is heavily undersampled.

Methods

Results

Conclusion