化学实验室室内空气中的可吸入微塑料和塑料添加剂。
Inhalable microplastics and plastic additives in the indoor air of chemical laboratories.
作者信息
Rindelaub Joel D, Miskelly Gordon M
机构信息
School of Chemical Sciences, University of Auckland, Private Bag 92019, Auckland, 1142, New Zealand.
出版信息
J Expo Sci Environ Epidemiol. 2025 Mar 29. doi: 10.1038/s41370-025-00768-0.
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.
背景
虽然对空气中微塑料的认识在不断增加,但关于与人类吸入最相关的气溶胶粒径范围内(PM 和 PM)的微塑料数据仍然有限。此外,人们担心塑料配方中使用的许多添加剂具有内分泌干扰特性,这可能会增加与微塑料接触相关的危害。
目的
为了更好地了解与空气中微塑料相关的毒理学风险,迫切需要更多关于我们呼吸的空气中微塑料及其相关化学添加剂质量浓度的数据。目前,化学实验室工作场所中吸入塑料相关物质的暴露情况尚不确定。
方法
使用基于热解气相色谱 - 质谱联用(Pyr - GC/MS)的方法,测定了两个室内地点可吸入空气中聚合物材料和小分子塑料添加剂的空气传播质量浓度。该方法是一种快速、直接的技术,可用于更好地规范空气中微塑料的测量。
结果
测定了七种不同聚合物的 PM 和 PM 浓度,PM 样品的平均塑料浓度为 0.51 μg m,PM 样品为 1.14 μg m。聚碳酸酯、聚氯乙烯和聚乙烯在空气可吸入部分中的空气传播浓度最高。同时,测定了塑料添加剂的空气传播浓度,所有空气样品中基于邻苯二甲酸酯的增塑剂平均浓度为 334 ng m。
影响
使用一种简单的质谱技术,在最少样品制备的情况下,对室内空气可吸入部分(PM)中的微塑料及其化学添加剂进行了定量。这些信息进一步加深了我们对室内空气暴露相关危害的认识,并为塑料相关空气传播污染物的质量定量提供了一种有用的方法。
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