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An Economic Fluorescent Method for Microplastics Detection in Soil Samples
Summary
Researchers developed a low-cost fluorescent dye (Nile red) protocol for detecting microplastics in soil that uses inexpensive equipment and requires minimal technical expertise, achieving close to 100% detection accuracy when tested on spiked sand samples. Making microplastic detection accessible and affordable is key to broadening monitoring efforts, especially in schools and community settings that cannot access laboratory-grade instruments.
Microplastics from urban and industrial waste are threatening ecosystems worldwide. Quantification methods for soil samples have been proposed but typically require complex and expensive laboratory procedures, which are not accessible to the public. Therefore, we developed a simplified Nile red fluorescent dye method with low-budget materials that can be readily used as lone-standing demonstrations or implemented in environmental education modules. The method was validated on commercial coarse-grain sand spiked with microplastics (1-5 mm). Following incubation with Nile red dye, the analytes were visually inspected using blue light and orange filter glasses and counted by two independent masked assessors. Detection of particles was close to 100 percent. Four different types of environmental analytes were subsequently tested with this method: urban lake shore sediment, agricultural soil, gardening soil, and soil from a state park. Urban lake shore and garden soil samples showed the highest density of microplastic particles. Large numbers of smaller particles (<1 mm) were also identified and counted in these analytes, with very good reproducibility by the same assessor and replication of the rank order of analytes between two assessors. Visualizing microplastic pollution with this low-cost, scalable method can reach broad sections of educational settings and the broader public and thus raise awareness of the problem of microplastic pollution.
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