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Publication
Fluorescence sensing of microplastics on surfaces
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Advisor(s)
Abstract(s)
Microplastics, nanoplastics and related products have been recently found in marine ecosystems worldwide, calling for new
analytical methods for rapid detection and risk assessment. Fluorescence is a sensitive technique that when used with polarity
probes can potentially detect low-polarity plastic particles in environments. Here, we evaluated the fuorescence technique
to sense polystyrene microparticles directly on salt, silica and sand surfaces, using Nile Red and pyrene as polarity probes.
Results show that all probes displayed fuorescence on silica and sand, whereas strong fuorescence quenching was observed
on NaCl. Polystyrene particles increase the fuorescence intensity due to probe migration into their nonpolar microenvironment. In the presence of polystyrene, the spectra of Nile Red are shifted to shorter wavelengths, while the ratio of vibronic
bands I1/I3 of fuorescence of pyrene decreases to about 1. Pyrene showed similar sensitivity toward surface-modifed carboxyl
polystyrene particles. On NaCl, the emission of pyrene increases linearly with polystyrene content for concentrations from
0.5 to 20 µg/g. The detection limit of polystyrene microparticles on natural sea salt using pyrene as probe is about 0.2 µg/g,
while on sand, the sensitivity is about one order of magnitude lower. Overall, although being of relatively low selectivity,
the fuorescence technique can be used to determine a maximum content of plastic particles of few micrometers size with
little sample preparation. Fluorescence, when used in conjunction with pyrene probe, allows for detection and quantifcation
of microplastic particles in the sub-ppm range.
Description
Keywords
Microplastics Fluorescent polarity probes Pyrene Surfaces Salt Sand
Citation
Publisher
Springer