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Inhalable microplastics and plastic additives in the indoor air of chemical laboratories
Summary
Researchers measured inhalable microplastics and plastic additives in the air of chemical laboratories, focusing on the particle sizes most relevant to human breathing. Using pyrolysis-gas chromatography mass spectrometry, they detected various polymers and endocrine-disrupting plastic additives in both fine and coarse air fractions. The study highlights that indoor workplaces can be significant sources of airborne microplastic exposure, with potential implications for occupational health.
BACKGROUND: While recognition of airborne microplastics is increasing, there are still limited data on the microplastics within the aerosol size fractions most relevant to human inhalation (PM and PM). Additionally, there are concerns that many of the additives used in plastic formulations have endocrine-disrupting properties, which could increase the hazards associated with microplastic exposure. OBJECTIVE: To better understand the toxicological risks associated with airborne microplastics, more data are urgently needed on the mass concentrations of both microplastics and the related chemical additives in the air we breathe. Inhalation exposure to plastic-related species is currently uncertain in chemical laboratory workplaces. METHODS: Using a Pyrolysis Gas Chromatography Mass Spectrometry (Pyr-GC/MS) based method, the airborne mass concentrations of both polymeric material and small molecule plastic additives were determined in inhalable air from two indoor locations. This method represents a fast, direct technique that can be used to better standardize airborne microplastic measurements. RESULTS: The PM and PM concentrations of seven different polymers were determined, with average plastic concentrations of 0.51 μg m for the PM samples and 1.14 µg m for the PM samples. Polycarbonate, polyvinylchloride, and polyethylene had the highest airborne concentrations in the inhalable fraction of air. Simultaneously, the airborne concentrations of plastic additives were determined, with phthalate-based plasticizers having an average concentration of 334 ng m across all air samples. IMPACT: Both microplastics and their chemical additives were quantified within the inhalable fraction of indoor air (PM), using a straight forward mass spectrometry technique with minimal sample preparation. This information furthers knowledge on the hazards associated with indoor air exposure, and it presents a useful methodology for the mass quantification of plastic-related airborne pollutants.
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