Rachel Hurley scite author profile

Complex and organic-rich solid substrates such as sludge and soil have been shown to be contaminated by microplastics; however, methods for extracting plastic particles have not yet been systemically tested or standardized. This study investigated four main protocols for the removal of organic material during analysis of microplastics from complex solid matrices: oxidation using HO, Fenton's reagent, and alkaline digestion with NaOH and KOH. Eight common polymer types were used to assess the influence of reagent exposure on particle integrity. Organic matter removal efficiencies were established for test sludge and soil samples. Fenton's reagent was identified as the optimum protocol. All other methods showed signs of particle degradation or resulted in an insufficient reduction in organic matter content. A further validation procedure revealed high microplastic extraction efficiencies for particles with different morphologies. This confirmed the suitability of Fenton's reagent for use in conjunction with density separation for extracting microplastics. This approach affords greater comparability with existing studies that utilize a density-based technique. Recommendations for further method optimization were also identified to improve the recovery of microplastic from complex, organic-rich environmental samples.

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Fate and occurrence of micro(nano)plastics in soils: Knowledge gaps and possible risks

Hurley

Nizzetto

2018

Current Opinion in Environmental Science & Health

479

166

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Ingestion of Microplastics by Freshwater Tubifex Worms

Hurley

Woodward

Rothwell

2017

Environ. Sci. Technol.

228

116

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Microplastic contamination of the aquatic environment is a global issue. Microplastics can be ingested by organisms leading to negative physiological impacts. The ingestion of microplastics by freshwater invertebrates has not been reported outside the laboratory. Here we demonstrate the ingestion of microplastic particles by Tubifex tubifex from bottom sediments in a major urban waterbody fed by the River Irwell, Manchester, UK. The host sediments had microplastic concentrations ranging from 56 to 2543 particles kg. 87% of the Tubifex-ingested microplastic particles were microfibers (55-4100 μm in length), while the remaining 13% were microplastic fragments (50-4500 μm in length). FT-IR analysis revealed ingestion of a range of polymers, including polyester and acrylic fibers. While microbeads were present in the host sediment matrix, they were not detected in Tubifex worm tissue. The mean concentration of ingested microplastics was 129 ± 65.4 particles g tissue. We also show that Tubifex worms retain microplastics for longer than they retain other particulate components of the ingested sediment matrix. Microplastic ingestion by Tubifex worms poses a significant risk for trophic transfer and biomagnification of microplastics up the aquatic food chain.

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Transfer and transport of microplastics from biosolids to agricultural soils and the wider environment

Crossman

Hurley

Bishop

et al. 2020

Science of The Total Environment

275

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Rachel Hurley

Microplastic contamination of river beds significantly reduced by catchment-wide flooding

Validation of a Method for Extracting Microplastics from Complex, Organic-Rich, Environmental Matrices

Fate and occurrence of micro(nano)plastics in soils: Knowledge gaps and possible risks

Ingestion of Microplastics by Freshwater Tubifex Worms

Transfer and transport of microplastics from biosolids to agricultural soils and the wider environment

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