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The Challenge of Matrix Interference in Quantitative Analysis of PM2.5 Microplastics Using Pyrolysis–Gas Chromatography-Mass Spectrometry
Summary
Scientists found that a common method for detecting tiny plastic particles in air pollution can give wrong results because of chemical interference from other pollutants like salts. They developed a simple water-rinsing technique that fixes this problem and gives more accurate measurements. This matters because we need reliable ways to measure how much plastic pollution people are breathing in, which could affect our health.
We evaluated the effect of ammonium sulfate, a major component of airborne particulate matter, in the quantification of airborne micro- and nanoplastics (AMNPs) by analytical pyrolysis–gas chromatography-mass spectrometry (Py-GC/MS). Analytical pyrolysis has shown promising potential in providing mass-based information on AMNPs, which are compatible with established standard protocols to monitor airborne particulate matter. Py-GC/MS can be performed with little to no sample preparation, minimizing the risk of polymer loss or sample contamination. However, reactive components of particulate matter, such as inorganic salts, can interfere with the Py-GC/MS measurement of polymers, leading to over/underestimation of the polymer content and instrument contamination. In this study, we have shown that ammonium sulfate can generate matrix interference in the quantification of AMNPs in PM2.5. We have provided a solution to this issue based on water rinsing of the particulate matter directly inside the pyrolysis crucible, avoiding sample loss and preventing instrument contamination.
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