A novel fluoro‐electrochemical technique for classifying diverse marine nanophytoplankton

Abstract: To broaden our understanding of pelagic ecosystem responses to environmental change, it is essential that we improve the spatiotemporal resolution of in situ monitoring of phytoplankton communities. A key challenge for existing methods is in classifying and quantifying cells within the nanophytoplankton size range (2–20 μm). This is particularly difficult when there are similarities in morphology, making visual differentiation difficult for both trained taxonomists and machine learning‐based approaches. Here w… Show more

“…Please see elsewhere for a detail discussion of the response of different strains of E. huxleyi. [24] Note that, in contrast to C. braarudii cells, the coccosphere of E. huxleyi were found to be fully dissolved by the concomitantly generated acid due to the smaller calcification extent.…”

Calcifying Coccolithophore: An Evolutionary Advantage Against Extracellular Oxidative Damage

“…Please see elsewhere for a detail discussion of the response of different strains of E. huxleyi. [24] Note that, in contrast to C. braarudii cells, the coccosphere of E. huxleyi were found to be fully dissolved by the concomitantly generated acid due to the smaller calcification extent.…”

Calcifying Coccolithophore: An Evolutionary Advantage Against Extracellular Oxidative Damage

Electrochemical sensors for phytoplankton and ocean health