We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Comparative Assessment of Protocols for Microplastic Quantification in Wastewater
Summary
This study compared three protocols for detecting and quantifying microplastics in water, evaluating efficiency, degradation risk, staining performance, and cost. Protocol A (Rhodamine B staining with NaCl density separation) performed best overall, with costs as low as €0.45 per sample after optimization.
Microplastics are an increasing concern due to their widespread occurrence in aquatic environments worldwide. The lack of a harmonised protocol for their reliable quantification remains a major challenge in current scientific efforts. This study presents a comparative evaluation of three protocols for the detection and quantification of microplastics in aqueous samples. The protocols were assessed based on quantification efficiency, risk of particle degradation, staining performance, operational complexity, and cost per sample. Protocol A combined Rhodamine B and ethanol staining with NaCl-based density separation, demonstrating strong isolation performance while maintaining minimal chemical hazards and moderate cost (2.45€ per sample) that could be further reduced to 0.45€ per sample by substituting reagent-grade NaCl with table salt. Protocol B offered moderate isolation capacity and presented the highest risk of particle fragmentation, likely due to the use of acetone and high-temperature digestion. Protocol C, based on the combined use of Nile Red and ZnCl2, also presented a risk of particle fragmentation, resulting in the highest MP count for small and hydrophobic particles. In addition, its high cost (15.23€ per sample) limits its suitability for routine application.
Sign in to start a discussion.
More Papers Like This
Development of an Inexpensive and Comparable Microplastic Detection Method Using Fluorescent Staining with Novel Nile Red Derivatives
Researchers developed an inexpensive fluorescent staining method using novel Nile Red derivatives for microplastic detection, validating it by measuring microplastics in German wastewater treatment plant effluent over one year with improved precision and selectivity.
Exploring the Efficacy of Nile Red in Microplastic Quantification: A Costaining Approach
This study assessed the effectiveness of Nile Red, a fluorescent dye commonly used to detect microplastics, by comparing it with other staining approaches and evaluating detection accuracy. The research found that costaining strategies and careful protocol standardization can improve the reliability of Nile Red-based microplastic quantification.
Comparision protocols for extraction of microplastics in water samples
Researchers compared four different extraction protocols for isolating microplastics from water samples and found significant differences in efficiency and accuracy across methods. Standardized extraction protocols are critical for producing comparable microplastic abundance data across studies. Without consistent methodology, it is difficult to build a reliable global picture of microplastic contamination levels in water.
Nile Red Staining as a Subsidiary Method for Microplastic Quantifica-tion: A Comparison of Three Solvents and Factors Influencing Application Reliability
This study evaluated Nile Red fluorescent staining as a method for quantifying microplastics in environmental samples, comparing it to traditional identification techniques. The approach can help distinguish microplastics from organic particles more quickly and cost-effectively, supporting higher-throughput microplastic analysis in environmental monitoring programs.
Microplastic analysis—are we measuring the same? Results on the first global comparative study for microplastic analysis in a water sample
Researchers conducted the first international comparative study of analytical methods for microplastic analysis in a water sample and found that comparability between methods was highly limited, underscoring the urgent need for standardized protocols in microplastic research.