Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water

Louis Peperzak; Eva Maria Zetsche; Stephan Gollasch; Luis Felipe Artigas; Simon Bonato; Veronique Creach; Pieter de Vré; George B.J. Dubelaar; Joël Henneghien; Ole Kristian Hess-Erga; Roland Langelaar; Aud Larsen; Brian N. Maurer; Albert Mosselaar; Euan D. Reavie; Machteld Rijkeboer; August Tobiesen

doi:10.1080/20464177.2018.1525806

Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water

Louis Peperzak, Eva Maria Zetsche, Stephan Gollasch, Luis Felipe Artigas, Simon Bonato, Veronique Creach, Pieter de Vré, George B.J. Dubelaar, Joël Henneghien, Ole Kristian Hess-Erga, Roland Langelaar, Aud Larsen, Brian N. Maurer, Albert Mosselaar, Euan D. Reavie, Machteld Rijkeboer, August Tobiesen

Natural Resources Research Institute

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

The ability to quantify vital aquatic organisms in the 2–50 µm size range was compared between five different flow cytometers and several different microscopes. Counts of calibration beads, algal monocultures of different sizes as well as organisms in a Wadden Sea sample were compared. Flow cytometers and microscopes delivered different bead concentrations. These differences between the instruments became larger for algal monocultures and were even higher for the Wadden Sea sample. It was observed that the concentration differences were significant between flow cytometer and microscope counts, and that this difference increased with the size of the objects counted. Microscope counts were more accurate for larger (50 µm) objects because cytometers struggled with bigger particles that clogged the instruments. Contrary to microscopy, the flow cytometers were capable of accurately enumerating cultured cells in the 2–10 µm size range and cells in the lower size range of the 10–50 µm size class. Flow cytometers were also well-suited to assess low abundance samples due to their ability to process larger volumes than microscopes. The results were used to indicate which tools are suitable for ballast water monitoring: flow cytometry is a suitable technology for an indicative and real time analysis of ballast water samples whilst only microscopy would be robust enough for detailed taxonomical analyses.

Original language	English (US)
Pages (from-to)	68-77
Number of pages	10
Journal	Journal of Marine Engineering and Technology
Volume	19
Issue number	2
DOIs	https://doi.org/10.1080/20464177.2018.1525806
State	Published - May 3 2020

Bibliographical note

Funding Information:
This work was supported by the Interreg IVB funded project Ballast Water Opportunity (35-2-50-08) and NIOZ, Den Hoorn, The Netherlands. This work was also supported by the Norwegian Research Council under [grant number 208653] (BallastFlow).

Funding Information:
This work was supported by the Interreg IVB funded project Ballast Water Opportunity (35-2-50-08) and NIOZ, Den Hoorn, The Netherlands. This work was also supported by the Norwegian Research Council under [grant number 208653] (BallastFlow). We express our grateful thanks to an endless number of helping hands at NIOZ, which were essential to make this workshop a success. Especially Anna Noordeloos, Alex Blin and Josje Snoek (NIOZ, Den Hoorn, The Netherlands) are thanked for the intensive preparations of this exercise.

Publisher Copyright:
© 2018, © 2018 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access

10.1080/20464177.2018.1525806

OpenUrl availability

Full text

Cite this

Peperzak, L., Zetsche, E. M., Gollasch, S., Artigas, L. F., Bonato, S., Creach, V., de Vré, P., Dubelaar, G. B. J., Henneghien, J., Hess-Erga, O. K., Langelaar, R., Larsen, A., Maurer, B. N., Mosselaar, A., Reavie, E. D., Rijkeboer, M., & Tobiesen, A. (2020). Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water. Journal of Marine Engineering and Technology, 19(2), 68-77. https://doi.org/10.1080/20464177.2018.1525806

Peperzak, L, Zetsche, EM, Gollasch, S, Artigas, LF, Bonato, S, Creach, V, de Vré, P, Dubelaar, GBJ, Henneghien, J, Hess-Erga, OK, Langelaar, R, Larsen, A, Maurer, BN, Mosselaar, A, Reavie, ED, Rijkeboer, M & Tobiesen, A 2020, 'Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water', Journal of Marine Engineering and Technology, vol. 19, no. 2, pp. 68-77. https://doi.org/10.1080/20464177.2018.1525806

@article{9f9475f653b54643b3969b9973dfab9e,

title = "Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water",

abstract = "The ability to quantify vital aquatic organisms in the 2–50 µm size range was compared between five different flow cytometers and several different microscopes. Counts of calibration beads, algal monocultures of different sizes as well as organisms in a Wadden Sea sample were compared. Flow cytometers and microscopes delivered different bead concentrations. These differences between the instruments became larger for algal monocultures and were even higher for the Wadden Sea sample. It was observed that the concentration differences were significant between flow cytometer and microscope counts, and that this difference increased with the size of the objects counted. Microscope counts were more accurate for larger (50 µm) objects because cytometers struggled with bigger particles that clogged the instruments. Contrary to microscopy, the flow cytometers were capable of accurately enumerating cultured cells in the 2–10 µm size range and cells in the lower size range of the 10–50 µm size class. Flow cytometers were also well-suited to assess low abundance samples due to their ability to process larger volumes than microscopes. The results were used to indicate which tools are suitable for ballast water monitoring: flow cytometry is a suitable technology for an indicative and real time analysis of ballast water samples whilst only microscopy would be robust enough for detailed taxonomical analyses.",

author = "Louis Peperzak and Zetsche, {Eva Maria} and Stephan Gollasch and Artigas, {Luis Felipe} and Simon Bonato and Veronique Creach and {de Vr{\'e}}, Pieter and Dubelaar, {George B.J.} and Jo{\"e}l Henneghien and Hess-Erga, {Ole Kristian} and Roland Langelaar and Aud Larsen and Maurer, {Brian N.} and Albert Mosselaar and Reavie, {Euan D.} and Machteld Rijkeboer and August Tobiesen",

note = "Funding Information: This work was supported by the Interreg IVB funded project Ballast Water Opportunity (35-2-50-08) and NIOZ, Den Hoorn, The Netherlands. This work was also supported by the Norwegian Research Council under [grant number 208653] (BallastFlow). Funding Information: This work was supported by the Interreg IVB funded project Ballast Water Opportunity (35-2-50-08) and NIOZ, Den Hoorn, The Netherlands. This work was also supported by the Norwegian Research Council under [grant number 208653] (BallastFlow). We express our grateful thanks to an endless number of helping hands at NIOZ, which were essential to make this workshop a success. Especially Anna Noordeloos, Alex Blin and Josje Snoek (NIOZ, Den Hoorn, The Netherlands) are thanked for the intensive preparations of this exercise. Publisher Copyright: {\textcopyright} 2018, {\textcopyright} 2018 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.",

year = "2020",

month = may,

day = "3",

doi = "10.1080/20464177.2018.1525806",

language = "English (US)",

volume = "19",

pages = "68--77",

journal = "Journal of Marine Engineering and Technology",

issn = "2046-4177",

publisher = "Taylor and Francis Ltd.",

number = "2",

}

TY - JOUR

T1 - Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water

AU - Peperzak, Louis

AU - Zetsche, Eva Maria

AU - Gollasch, Stephan

AU - Artigas, Luis Felipe

AU - Bonato, Simon

AU - Creach, Veronique

AU - de Vré, Pieter

AU - Dubelaar, George B.J.

AU - Henneghien, Joël

AU - Hess-Erga, Ole Kristian

AU - Langelaar, Roland

AU - Larsen, Aud

AU - Maurer, Brian N.

AU - Mosselaar, Albert

AU - Reavie, Euan D.

AU - Rijkeboer, Machteld

AU - Tobiesen, August

N1 - Funding Information: This work was supported by the Interreg IVB funded project Ballast Water Opportunity (35-2-50-08) and NIOZ, Den Hoorn, The Netherlands. This work was also supported by the Norwegian Research Council under [grant number 208653] (BallastFlow). Funding Information: This work was supported by the Interreg IVB funded project Ballast Water Opportunity (35-2-50-08) and NIOZ, Den Hoorn, The Netherlands. This work was also supported by the Norwegian Research Council under [grant number 208653] (BallastFlow). We express our grateful thanks to an endless number of helping hands at NIOZ, which were essential to make this workshop a success. Especially Anna Noordeloos, Alex Blin and Josje Snoek (NIOZ, Den Hoorn, The Netherlands) are thanked for the intensive preparations of this exercise. Publisher Copyright: © 2018, © 2018 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.

PY - 2020/5/3

Y1 - 2020/5/3

N2 - The ability to quantify vital aquatic organisms in the 2–50 µm size range was compared between five different flow cytometers and several different microscopes. Counts of calibration beads, algal monocultures of different sizes as well as organisms in a Wadden Sea sample were compared. Flow cytometers and microscopes delivered different bead concentrations. These differences between the instruments became larger for algal monocultures and were even higher for the Wadden Sea sample. It was observed that the concentration differences were significant between flow cytometer and microscope counts, and that this difference increased with the size of the objects counted. Microscope counts were more accurate for larger (50 µm) objects because cytometers struggled with bigger particles that clogged the instruments. Contrary to microscopy, the flow cytometers were capable of accurately enumerating cultured cells in the 2–10 µm size range and cells in the lower size range of the 10–50 µm size class. Flow cytometers were also well-suited to assess low abundance samples due to their ability to process larger volumes than microscopes. The results were used to indicate which tools are suitable for ballast water monitoring: flow cytometry is a suitable technology for an indicative and real time analysis of ballast water samples whilst only microscopy would be robust enough for detailed taxonomical analyses.

AB - The ability to quantify vital aquatic organisms in the 2–50 µm size range was compared between five different flow cytometers and several different microscopes. Counts of calibration beads, algal monocultures of different sizes as well as organisms in a Wadden Sea sample were compared. Flow cytometers and microscopes delivered different bead concentrations. These differences between the instruments became larger for algal monocultures and were even higher for the Wadden Sea sample. It was observed that the concentration differences were significant between flow cytometer and microscope counts, and that this difference increased with the size of the objects counted. Microscope counts were more accurate for larger (50 µm) objects because cytometers struggled with bigger particles that clogged the instruments. Contrary to microscopy, the flow cytometers were capable of accurately enumerating cultured cells in the 2–10 µm size range and cells in the lower size range of the 10–50 µm size class. Flow cytometers were also well-suited to assess low abundance samples due to their ability to process larger volumes than microscopes. The results were used to indicate which tools are suitable for ballast water monitoring: flow cytometry is a suitable technology for an indicative and real time analysis of ballast water samples whilst only microscopy would be robust enough for detailed taxonomical analyses.

UR - http://www.scopus.com/inward/record.url?scp=85053895898&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85053895898&partnerID=8YFLogxK

U2 - 10.1080/20464177.2018.1525806

DO - 10.1080/20464177.2018.1525806

M3 - Article

AN - SCOPUS:85053895898

SN - 2046-4177

VL - 19

SP - 68

EP - 77

JO - Journal of Marine Engineering and Technology

JF - Journal of Marine Engineering and Technology

IS - 2

ER -

Comparing flow cytometry and microscopy in the quantification of vital aquatic organisms in ballast water

Abstract

Bibliographical note

UN SDGs

Access

OpenUrl availability

Other files and links

Fingerprint

Cite this