Abstract
Microplastics are globally recognized as contaminants in freshwater and marine aquatic systems. To date there is no universally accepted protocol for isolation and quantification of microplastics from aqueous media. Various methodologies exist, many of which are time consuming and have the potential to introduce contaminants into samples, thereby obscuring characterization of the environmental microplastic load. Here we present a novel approach for in-situ detection of microplastics, based on their fluorescent staining followed by high throughput analysis and quantification using Flow Cytometry. Using controlled laboratory settings nine polymer types (Polystyrene – PS; Polyethylene – PE; Polyethylene terephthalate – PET/PETE; High density polyethylene – HDPE; Low density polyethylene – LDPE; Polyvinyl chloride – PVC; Polypropylene –PP; Nylon – PA; and Polycarbonate - PC) were tested for identification and quantification in freshwater. All nine plastic types were stained with 10 µg/mL Nile Red in 10% dimethyl sulfoxide with a 10 minutes incubation time. The lowest spatial detectable limit for plastic particles was 200 nm. Out of the nine polymer types chosen for the study PS, PE, PET, and PC were well identified; however, results for other plastic types (PVC, PP, PA, LDPE, and HDPE) were masked to certain extent by Nile Red aggregation and precipitation. The methodology presented here permits identification of a range of particle sizes and types. It represents a significant step in the quantification of microplastics by replacing visual data interpretation with a sensitive and automated method.
Highlights
Plastics are extensively used in a wide range of industrial sectors due to their versatile, durable, and lightweight nature
We have developed a two-stages protocol using staining of microplastics by Nile Red, followed by rapid identification and quantification of microplastic particles in freshwater using flow cytometry (FC)
Since Nile Red (NR) in dimethyl sulfoxide (DMSO) and in ethanol/methanol, showed equivalently good staining results when evaluated using microscopy for PA plastic type, DMSO was selected as the standard solvent for later experiments as it has been used previously on the Attune NxT FC (Perelman et al, 2012; Satpati and Pal, 2015; Olsen et al, 2016)
Summary
Plastics are extensively used in a wide range of industrial sectors due to their versatile, durable, and lightweight nature. More than 150 million tons of plastic has accumulated in the world’s oceans, and about 4.6–12.7 million metric tons of plastics are added every year (Jambeck et al, 2015). Their presence ranges from soil, air, oceans, estuaries, freshwater (Andrady, 2017) to the remote arctic ice (Lusher et al, 2015) and the Antarctic waters (Li et al, 2018). Microplastics can be divided into primary and secondary types Primary microplastics are those released directly into the environment in micrometer dimensions.
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