Quantitative assessment of visual microscopy as a tool for microplastic research: Recommendations for improving methods and reporting

Syd Kotar; Rae McNeish; Clare Murphy-Hagan; Violet Renick; Chih Fen T. Lee; Clare Steele; Amy Lusher; Charles Moore; Elizabeth Minor; Joseph Schroeder; Paul Helm; Keith Rickabaugh; Hannah De Frond; Kristine Gesulga; Wenjian Lao; Keenan Munno; Leah M. Thornton Hampton; Stephen B. Weisberg; Charles S. Wong; Gaurav Amarpuri; Robert C. Andrews; Steven M. Barnett; Silke Christiansen; Win Cowger; Kévin Crampond; Fangni Du; Andrew B. Gray; Jeanne Hankett; Kay Ho; Julia Jaeger; Claire Lilley; Lei Mai; Odette Mina; Eunah Lee; Sebastian Primpke; Samiksha Singh; Joakim Skovly; Theresa Slifko; Suja Sukumaran; Bert van Bavel; Jennifer Van Brocklin; Florian Vollnhals; Chenxi Wu; Chelsea M. Rochman

doi:10.1016/j.chemosphere.2022.136449

Quantitative assessment of visual microscopy as a tool for microplastic research: Recommendations for improving methods and reporting

Syd Kotar, Rae McNeish, Clare Murphy-Hagan, Violet Renick, Chih Fen T. Lee, Clare Steele, Amy Lusher, Charles Moore, Elizabeth Minor, Joseph Schroeder, Paul Helm, Keith Rickabaugh, Hannah De Frond, Kristine Gesulga, Wenjian Lao, Keenan Munno, Leah M. Thornton Hampton, Stephen B. Weisberg, Charles S. Wong, Gaurav AmarpuriRobert C. Andrews, Steven M. Barnett, Silke Christiansen, Win Cowger, Kévin Crampond, Fangni Du, Andrew B. Gray, Jeanne Hankett, Kay Ho, Julia Jaeger, Claire Lilley, Lei Mai, Odette Mina, Eunah Lee, Sebastian Primpke, Samiksha Singh, Joakim Skovly, Theresa Slifko, Suja Sukumaran, Bert van Bavel, Jennifer Van Brocklin, Florian Vollnhals, Chenxi Wu, Chelsea M. Rochman

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Abstract

Microscopy is often the first step in microplastic analysis and is generally followed by spectroscopy to confirm material type. The value of microscopy lies in its ability to provide count, size, color, and morphological information to inform toxicity and source apportionment. To assess the accuracy and precision of microscopy, we conducted a method evaluation study. Twenty-two laboratories from six countries were provided three blind spiked clean water samples and asked to follow a standard operating procedure. The samples contained a known number of microplastics with different morphologies (fiber, fragment, sphere), colors (clear, white, green, blue, red, and orange), polymer types (PE, PS, PVC, and PET), and sizes (ranging from roughly 3–2000 μm), and natural materials (natural hair, fibers, and shells; 100–7000 μm) that could be mistaken for microplastics (i.e., false positives). Particle recovery was poor for the smallest size fraction (3–20 μm). Average recovery (±StDev) for all reported particles >50 μm was 94.5 ± 56.3%. After quality checks, recovery for >50 μm spiked particles was 51.3 ± 21.7%. Recovery varied based on morphology and color, with poorest recovery for fibers and the largest deviations for clear and white particles. Experience mattered; less experienced laboratories tended to report higher concentration and had a higher variance among replicates. Participants identified opportunity for increased accuracy and precision through training, improved color and morphology keys, and method alterations relevant to size fractionation. The resulting data informs future work, constraining and highlighting the value of microscopy for microplastics.

Original language	English (US)
Article number	136449
Journal	Chemosphere
Volume	308
DOIs	https://doi.org/10.1016/j.chemosphere.2022.136449
State	Published - Dec 2022
Externally published	Yes

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Publisher Copyright:
© 2022 Elsevier Ltd

Keywords

Accuracy
Color
Experience
Morphology
Recovery
Size
Standardized methods

PubMed: MeSH publication types

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10.1016/j.chemosphere.2022.136449

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Kotar, S., McNeish, R., Murphy-Hagan, C., Renick, V., Lee, C. F. T., Steele, C., Lusher, A., Moore, C., Minor, E., Schroeder, J., Helm, P., Rickabaugh, K., De Frond, H., Gesulga, K., Lao, W., Munno, K., Thornton Hampton, L. M., Weisberg, S. B., Wong, C. S., ... Rochman, C. M. (2022). Quantitative assessment of visual microscopy as a tool for microplastic research: Recommendations for improving methods and reporting. Chemosphere, 308, Article 136449. https://doi.org/10.1016/j.chemosphere.2022.136449

Kotar, S, McNeish, R, Murphy-Hagan, C, Renick, V, Lee, CFT, Steele, C, Lusher, A, Moore, C, Minor, E, Schroeder, J, Helm, P, Rickabaugh, K, De Frond, H, Gesulga, K, Lao, W, Munno, K, Thornton Hampton, LM, Weisberg, SB, Wong, CS, Amarpuri, G, Andrews, RC, Barnett, SM, Christiansen, S, Cowger, W, Crampond, K, Du, F, Gray, AB, Hankett, J, Ho, K, Jaeger, J, Lilley, C, Mai, L, Mina, O, Lee, E, Primpke, S, Singh, S, Skovly, J, Slifko, T, Sukumaran, S, van Bavel, B, Van Brocklin, J, Vollnhals, F, Wu, C & Rochman, CM 2022, 'Quantitative assessment of visual microscopy as a tool for microplastic research: Recommendations for improving methods and reporting', Chemosphere, vol. 308, 136449. https://doi.org/10.1016/j.chemosphere.2022.136449

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title = "Quantitative assessment of visual microscopy as a tool for microplastic research: Recommendations for improving methods and reporting",

abstract = "Microscopy is often the first step in microplastic analysis and is generally followed by spectroscopy to confirm material type. The value of microscopy lies in its ability to provide count, size, color, and morphological information to inform toxicity and source apportionment. To assess the accuracy and precision of microscopy, we conducted a method evaluation study. Twenty-two laboratories from six countries were provided three blind spiked clean water samples and asked to follow a standard operating procedure. The samples contained a known number of microplastics with different morphologies (fiber, fragment, sphere), colors (clear, white, green, blue, red, and orange), polymer types (PE, PS, PVC, and PET), and sizes (ranging from roughly 3–2000 μm), and natural materials (natural hair, fibers, and shells; 100–7000 μm) that could be mistaken for microplastics (i.e., false positives). Particle recovery was poor for the smallest size fraction (3–20 μm). Average recovery (±StDev) for all reported particles >50 μm was 94.5 ± 56.3%. After quality checks, recovery for >50 μm spiked particles was 51.3 ± 21.7%. Recovery varied based on morphology and color, with poorest recovery for fibers and the largest deviations for clear and white particles. Experience mattered; less experienced laboratories tended to report higher concentration and had a higher variance among replicates. Participants identified opportunity for increased accuracy and precision through training, improved color and morphology keys, and method alterations relevant to size fractionation. The resulting data informs future work, constraining and highlighting the value of microscopy for microplastics.",

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author = "Syd Kotar and Rae McNeish and Clare Murphy-Hagan and Violet Renick and Lee, {Chih Fen T.} and Clare Steele and Amy Lusher and Charles Moore and Elizabeth Minor and Joseph Schroeder and Paul Helm and Keith Rickabaugh and {De Frond}, Hannah and Kristine Gesulga and Wenjian Lao and Keenan Munno and {Thornton Hampton}, {Leah M.} and Weisberg, {Stephen B.} and Wong, {Charles S.} and Gaurav Amarpuri and Andrews, {Robert C.} and Barnett, {Steven M.} and Silke Christiansen and Win Cowger and K{\'e}vin Crampond and Fangni Du and Gray, {Andrew B.} and Jeanne Hankett and Kay Ho and Julia Jaeger and Claire Lilley and Lei Mai and Odette Mina and Eunah Lee and Sebastian Primpke and Samiksha Singh and Joakim Skovly and Theresa Slifko and Suja Sukumaran and {van Bavel}, Bert and {Van Brocklin}, Jennifer and Florian Vollnhals and Chenxi Wu and Rochman, {Chelsea M.}",

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doi = "10.1016/j.chemosphere.2022.136449",

language = "English (US)",

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AU - Kotar, Syd

AU - McNeish, Rae

AU - Murphy-Hagan, Clare

AU - Renick, Violet

AU - Lee, Chih Fen T.

AU - Steele, Clare

AU - Lusher, Amy

AU - Moore, Charles

AU - Minor, Elizabeth

AU - Schroeder, Joseph

AU - Helm, Paul

AU - Rickabaugh, Keith

AU - De Frond, Hannah

AU - Gesulga, Kristine

AU - Lao, Wenjian

AU - Munno, Keenan

AU - Thornton Hampton, Leah M.

AU - Weisberg, Stephen B.

AU - Wong, Charles S.

AU - Amarpuri, Gaurav

AU - Andrews, Robert C.

AU - Barnett, Steven M.

AU - Christiansen, Silke

AU - Cowger, Win

AU - Crampond, Kévin

AU - Du, Fangni

AU - Gray, Andrew B.

AU - Hankett, Jeanne

AU - Ho, Kay

AU - Jaeger, Julia

AU - Lilley, Claire

AU - Mai, Lei

AU - Mina, Odette

AU - Lee, Eunah

AU - Primpke, Sebastian

AU - Singh, Samiksha

AU - Skovly, Joakim

AU - Slifko, Theresa

AU - Sukumaran, Suja

AU - van Bavel, Bert

AU - Van Brocklin, Jennifer

AU - Vollnhals, Florian

AU - Wu, Chenxi

AU - Rochman, Chelsea M.

PY - 2022/12

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N2 - Microscopy is often the first step in microplastic analysis and is generally followed by spectroscopy to confirm material type. The value of microscopy lies in its ability to provide count, size, color, and morphological information to inform toxicity and source apportionment. To assess the accuracy and precision of microscopy, we conducted a method evaluation study. Twenty-two laboratories from six countries were provided three blind spiked clean water samples and asked to follow a standard operating procedure. The samples contained a known number of microplastics with different morphologies (fiber, fragment, sphere), colors (clear, white, green, blue, red, and orange), polymer types (PE, PS, PVC, and PET), and sizes (ranging from roughly 3–2000 μm), and natural materials (natural hair, fibers, and shells; 100–7000 μm) that could be mistaken for microplastics (i.e., false positives). Particle recovery was poor for the smallest size fraction (3–20 μm). Average recovery (±StDev) for all reported particles >50 μm was 94.5 ± 56.3%. After quality checks, recovery for >50 μm spiked particles was 51.3 ± 21.7%. Recovery varied based on morphology and color, with poorest recovery for fibers and the largest deviations for clear and white particles. Experience mattered; less experienced laboratories tended to report higher concentration and had a higher variance among replicates. Participants identified opportunity for increased accuracy and precision through training, improved color and morphology keys, and method alterations relevant to size fractionation. The resulting data informs future work, constraining and highlighting the value of microscopy for microplastics.

AB - Microscopy is often the first step in microplastic analysis and is generally followed by spectroscopy to confirm material type. The value of microscopy lies in its ability to provide count, size, color, and morphological information to inform toxicity and source apportionment. To assess the accuracy and precision of microscopy, we conducted a method evaluation study. Twenty-two laboratories from six countries were provided three blind spiked clean water samples and asked to follow a standard operating procedure. The samples contained a known number of microplastics with different morphologies (fiber, fragment, sphere), colors (clear, white, green, blue, red, and orange), polymer types (PE, PS, PVC, and PET), and sizes (ranging from roughly 3–2000 μm), and natural materials (natural hair, fibers, and shells; 100–7000 μm) that could be mistaken for microplastics (i.e., false positives). Particle recovery was poor for the smallest size fraction (3–20 μm). Average recovery (±StDev) for all reported particles >50 μm was 94.5 ± 56.3%. After quality checks, recovery for >50 μm spiked particles was 51.3 ± 21.7%. Recovery varied based on morphology and color, with poorest recovery for fibers and the largest deviations for clear and white particles. Experience mattered; less experienced laboratories tended to report higher concentration and had a higher variance among replicates. Participants identified opportunity for increased accuracy and precision through training, improved color and morphology keys, and method alterations relevant to size fractionation. The resulting data informs future work, constraining and highlighting the value of microscopy for microplastics.

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KW - Color

KW - Experience

KW - Morphology

KW - Recovery

KW - Size

KW - Standardized methods

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DO - 10.1016/j.chemosphere.2022.136449

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SN - 0045-6535

VL - 308

JO - Chemosphere

JF - Chemosphere

M1 - 136449

ER -

Quantitative assessment of visual microscopy as a tool for microplastic research: Recommendations for improving methods and reporting

Abstract

Bibliographical note

Keywords

PubMed: MeSH publication types

Access

OpenUrl availability

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