Optimising H2O2 digestion and quantifying microplastics in sediment and pacific oyster (Crassostrea gigas) samples
Optimising H2O2 digestion and quantifying microplastics in sediment and pacific oyster (Crassostrea gigas) samples
Microplastic pollution continues to threaten marine environments across the world, yet there is inadequate understanding regarding the sources, distribution and impacts of these particles. Marine microplastic pollution is commonly investigated with the use of biomonitors, such as bivalves. However, published methods on chemical tissue digestion lack clarification regarding reagent volumes for small tissue samples <5 g. Therefore, this study aimed to improve H2O2 digestion methods and quantify and categorise the microplastics found within sediment and Crassostrea gigas samples collected from Weston Shore, Southampton. Tissue samples of 1 g were digested in varying quantities of 30 % H2O2. 20 ml of 30 % H2O2 per gram of tissue was sufficient in digesting samples of 2 g or more; 1 g samples require further experimentation. Sediment samples were visually inspected under a light microscope, along with the oyster samples once the microplastics had been extracted using H2O2 digestion, followed by density separation using NaCl. For tissue samples ≤5 g, 20 ml H2O2 per g of tissue should be used for digestion. For tissue samples >6 g, 6 mass of the sample should be used for digestion. Sediment microplastic concentrations were found to decrease moving south east along the shore, with varying significance, whereas C. gigas microplastic loads did not show any significant spatial differentiation (p = 0.3). Both sediment and C. gigas samples were dominated by fibres (96 % and 97 %, respectively), which is consistent with similar studies worldwide. The new digestion method gives 50 % cost reduction and lessened environmental impacts.
Microplastics, Sediment, Biomonitoring, Crassostrea gigas, Analytical methods
Brown, H.
6317e7d5-d8ce-4eb9-8317-f120a8a52b86
Williams, I.D.
c9d674ac-ee69-4937-ab43-17e716266e22
2 July 2025
Brown, H.
6317e7d5-d8ce-4eb9-8317-f120a8a52b86
Williams, I.D.
c9d674ac-ee69-4937-ab43-17e716266e22
Brown, H. and Williams, I.D.
(2025)
Optimising H2O2 digestion and quantifying microplastics in sediment and pacific oyster (Crassostrea gigas) samples.
Marine Pollution Bulletin, 220, [118353].
(doi:10.1016/j.marpolbul.2025.118353).
Abstract
Microplastic pollution continues to threaten marine environments across the world, yet there is inadequate understanding regarding the sources, distribution and impacts of these particles. Marine microplastic pollution is commonly investigated with the use of biomonitors, such as bivalves. However, published methods on chemical tissue digestion lack clarification regarding reagent volumes for small tissue samples <5 g. Therefore, this study aimed to improve H2O2 digestion methods and quantify and categorise the microplastics found within sediment and Crassostrea gigas samples collected from Weston Shore, Southampton. Tissue samples of 1 g were digested in varying quantities of 30 % H2O2. 20 ml of 30 % H2O2 per gram of tissue was sufficient in digesting samples of 2 g or more; 1 g samples require further experimentation. Sediment samples were visually inspected under a light microscope, along with the oyster samples once the microplastics had been extracted using H2O2 digestion, followed by density separation using NaCl. For tissue samples ≤5 g, 20 ml H2O2 per g of tissue should be used for digestion. For tissue samples >6 g, 6 mass of the sample should be used for digestion. Sediment microplastic concentrations were found to decrease moving south east along the shore, with varying significance, whereas C. gigas microplastic loads did not show any significant spatial differentiation (p = 0.3). Both sediment and C. gigas samples were dominated by fibres (96 % and 97 %, respectively), which is consistent with similar studies worldwide. The new digestion method gives 50 % cost reduction and lessened environmental impacts.
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Accepted/In Press date: 23 June 2025
e-pub ahead of print date: 2 July 2025
Published date: 2 July 2025
Keywords:
Microplastics, Sediment, Biomonitoring, Crassostrea gigas, Analytical methods
Identifiers
Local EPrints ID: 504093
URI: http://eprints.soton.ac.uk/id/eprint/504093
ISSN: 0025-326X
PURE UUID: 07230260-dd67-4fc1-84a1-eeddf84fdc58
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Date deposited: 26 Aug 2025 16:34
Last modified: 27 Aug 2025 01:41
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Author:
H. Brown
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