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The potential of multispectral imaging flow cytometry for environmental monitoring

Cytometry Part A 2022 18 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 35 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Mechthild Schmitt‐Jansen, Katrin Wendt‐Potthoff Katrin Wendt‐Potthoff Susanne Dunker, Mechthild Schmitt‐Jansen, S. H. Lips, S. H. Lips, Katrin Wendt‐Potthoff Mechthild Schmitt‐Jansen, S. H. Lips, Matt Boyd, S. H. Lips, Katrin Wendt‐Potthoff S. H. Lips, S. H. Lips, S. H. Lips, Mechthild Schmitt‐Jansen, Walter Durka, Silvio Erler, Mechthild Schmitt‐Jansen, Katrin Wendt‐Potthoff Mechthild Schmitt‐Jansen, Katrin Wendt‐Potthoff Mechthild Schmitt‐Jansen, S. H. Lips, Mechthild Schmitt‐Jansen, W. Stanley Harpole, Mechthild Schmitt‐Jansen, S. H. Lips, Mechthild Schmitt‐Jansen, Katrin Wendt‐Potthoff Silvia Henning, Silvia Henning, Ulrike Herzschuh, Katrin Wendt‐Potthoff Katrin Wendt‐Potthoff Katrin Wendt‐Potthoff Mechthild Schmitt‐Jansen, Katrin Wendt‐Potthoff Katrin Wendt‐Potthoff Mechthild Schmitt‐Jansen, Thomas Hornick, Frank Stratmann, Tiffany M. Knight, Mechthild Schmitt‐Jansen, S. H. Lips, Mechthild Schmitt‐Jansen, Mechthild Schmitt‐Jansen, Mechthild Schmitt‐Jansen, Patrick Mäder, Mechthild Schmitt‐Jansen, Elena Motivans Švara, Steven Andrew Mozarowski, Katrin Wendt‐Potthoff Steven Andrew Mozarowski, S. H. Lips, Demetra Rákosy, S. H. Lips, Christine Römermann, S. H. Lips, Mechthild Schmitt‐Jansen, Kathleen R. Stoof‐Leichsenring, Mechthild Schmitt‐Jansen, Frank Stratmann, Regina Treudler, Mechthild Schmitt‐Jansen, Mechthild Schmitt‐Jansen, Risto Virtanen, Katrin Wendt‐Potthoff Mechthild Schmitt‐Jansen, Christian Wilhelm, Mechthild Schmitt‐Jansen, Katrin Wendt‐Potthoff Katrin Wendt‐Potthoff

Summary

Researchers evaluated the potential of multispectral imaging flow cytometry (MIFC) for automated environmental monitoring of microscopic particles including algae, pollen, fungal spores, and microplastics in water samples. They found that MIFC's capacity to capture up to 12 simultaneous images at 5,000 particles per second offers significant advantages over conventional microscopy for high-throughput environmental surveillance.

Environmental monitoring involves the quantification of microscopic cells and particles such as algae, plant cells, pollen, or fungal spores. Traditional methods using conventional microscopy require expert knowledge, are time-intensive and not well-suited for automated high throughput. Multispectral imaging flow cytometry (MIFC) allows measurement of up to 5000 particles per second from a fluid suspension and can simultaneously capture up to 12 images of every single particle for brightfield and different spectral ranges, with up to 60x magnification. The high throughput of MIFC has high potential for increasing the amount and accuracy of environmental monitoring, such as for plant-pollinator interactions, fossil samples, air, water or food quality that currently rely on manual microscopic methods. Automated recognition of particles and cells is also possible, when MIFC is combined with deep-learning computational techniques. Furthermore, various fluorescence dyes can be used to stain specific parts of the cell to highlight physiological and chemical features including: vitality of pollen or algae, allergen content of individual pollen, surface chemical composition (carbohydrate coating) of cells, DNA- or enzyme-activity staining. Here, we outline the great potential for MIFC in environmental research for a variety of research fields and focal organisms. In addition, we provide best practice recommendations.

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