Discrimination of microplastics and phytoplankton using impedance cytometry
Discrimination of microplastics and phytoplankton using impedance cytometry
Both microplastics and phytoplankton are found together in the ocean as suspended microparticles. There is a need for deployable technologies that can identify, size, and count these particles at high throughput to monitor plankton community structure and microplastic pollution levels. In situ analysis is particularly desirable as it avoids the problems associated with sample storage, processing, and degradation. Current technologies for phytoplankton and microplastic analysis are limited in their capability by specificity, throughput, or lack of deployability. Little attention has been paid to the smallest size fraction of microplastics and phytoplankton below 10 μm in diameter, which are in high abundance. Impedance cytometry is a technique that uses microfluidic chips with integrated microelectrodes to measure the electrical impedance of individual particles. Here, we present an impedance cytometer that can discriminate and count microplastics sampled directly from a mixture of phytoplankton in a seawater-like medium in the 1.5-10 μm size range. A simple machine learning algorithm was used to classify microplastic particles based on dual-frequency impedance measurements of particle size (at 1 MHz) and cell internal electrical composition (at 500 MHz). The technique shows promise for marine deployment, as the chip is sensitive, rugged, and mass producible.
impedance cytometry, impedance spectroscopy, lab-on-a-chip, machine learning, microplastics, phytoplankton
Butement, Jonathan T.
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Wang, Xiang
cef27194-0a48-4675-bad8-c9a0942e6637
Siracusa, Fabrizio
182e0f35-d7bd-49c0-a034-3b019abf59f9
Miller, Emily
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Pabortsava, Katsiaryna
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Mowlem, Matthew
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Spencer, Daniel
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Morgan, Hywel
de00d59f-a5a2-48c4-a99a-1d5dd7854174
14 August 2024
Butement, Jonathan T.
581ce321-f1af-4a2f-870a-9d8d45133586
Wang, Xiang
cef27194-0a48-4675-bad8-c9a0942e6637
Siracusa, Fabrizio
182e0f35-d7bd-49c0-a034-3b019abf59f9
Miller, Emily
3b722b0a-4931-4d87-bf44-4e56bce1e5b4
Pabortsava, Katsiaryna
bb9c573c-918c-4bc5-ad41-f85e47a6a580
Mowlem, Matthew
6f633ca2-298f-48ee-a025-ce52dd62124f
Spencer, Daniel
4affe9f6-353a-4507-8066-0180b8dc9eaf
Morgan, Hywel
de00d59f-a5a2-48c4-a99a-1d5dd7854174
Butement, Jonathan T., Wang, Xiang, Siracusa, Fabrizio, Miller, Emily, Pabortsava, Katsiaryna, Mowlem, Matthew, Spencer, Daniel and Morgan, Hywel
(2024)
Discrimination of microplastics and phytoplankton using impedance cytometry.
ACS Sensors.
(doi:10.1021/acssensors.4c01353).
Abstract
Both microplastics and phytoplankton are found together in the ocean as suspended microparticles. There is a need for deployable technologies that can identify, size, and count these particles at high throughput to monitor plankton community structure and microplastic pollution levels. In situ analysis is particularly desirable as it avoids the problems associated with sample storage, processing, and degradation. Current technologies for phytoplankton and microplastic analysis are limited in their capability by specificity, throughput, or lack of deployability. Little attention has been paid to the smallest size fraction of microplastics and phytoplankton below 10 μm in diameter, which are in high abundance. Impedance cytometry is a technique that uses microfluidic chips with integrated microelectrodes to measure the electrical impedance of individual particles. Here, we present an impedance cytometer that can discriminate and count microplastics sampled directly from a mixture of phytoplankton in a seawater-like medium in the 1.5-10 μm size range. A simple machine learning algorithm was used to classify microplastic particles based on dual-frequency impedance measurements of particle size (at 1 MHz) and cell internal electrical composition (at 500 MHz). The technique shows promise for marine deployment, as the chip is sensitive, rugged, and mass producible.
Text
butement-et-al-2024-discrimination-of-microplastics-and-phytoplankton-using-impedance-cytometry
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More information
Accepted/In Press date: 2 August 2024
Published date: 14 August 2024
Keywords:
impedance cytometry, impedance spectroscopy, lab-on-a-chip, machine learning, microplastics, phytoplankton
Identifiers
Local EPrints ID: 493649
URI: http://eprints.soton.ac.uk/id/eprint/493649
ISSN: 2379-3694
PURE UUID: 6d1f817d-54fa-4a9a-92ce-339a3ee5a17b
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Date deposited: 10 Sep 2024 16:35
Last modified: 11 Sep 2024 01:42
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Contributors
Author:
Jonathan T. Butement
Author:
Xiang Wang
Author:
Fabrizio Siracusa
Author:
Emily Miller
Author:
Katsiaryna Pabortsava
Author:
Matthew Mowlem
Author:
Daniel Spencer
Author:
Hywel Morgan
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