实验室间比对揭示了微塑料检测与定量方法的现状。

Interlaboratory Comparison Reveals State of the Art in Microplastic Detection and Quantification Methods.

作者信息

Ciornii Dmitri, Hodoroaba Vasile-Dan, Benismail Nizar, Maltseva Alina, Ferrer Juan F, Wang Jiamin, Parra Raquel, Jézéquel Ronan, Receveur Justine, Gabriel Dina, Scheitler Andreas, van Oversteeg Christa, Roosma Jorg, van Renesse van Duivenbode Alex, Bulters Tim, Zanella Michela, Perini Alessandro, Benetti Federico, Mehn Dora, Dierkes Georg, Soll Michael, Ishimura Takahisa, Bednarz Marius, Peng Guyu, Hildebrandt Lars, Peters Mathias, Kim Seung-Kyu, Türk Jochen, Steinfeld Felix, Jung Jaehak, Hong Sanghee, Kim Eun-Ju, Yu Hye-Weon, Klockmann Sven, Krafft Christoph, Süssmann Julia, Zou Shan, Ter Halle Alexandra, Giovannozzi Andrea M, Sacco Alessio, Fadda Marta, Putzu Mara, Im Dong-Hoon, Nhlapo Nontete, Carrillo-Barragán Priscilla, Schmidt Natascha, Herzke Dorte, Gomiero Alessio, Jaén-Gil Adrián, Cabanes Damien J E, Doedt Martin, Cardoso Vitor, Schmitz Antje, Hawly Moritz, Mo Huajuan, Jacquin Justine, Mechlinski Andy, Adediran Gbotemi A, Andrade Jose, Muniategui-Lorenzo Soledad, Ramsperger Anja, Löder Martin G J, Laforsch Christian, Cirkovic Velickovic Tanja, Fabbri Daniele, Coralli Irene, Federici Stefania, Scholz-Böttcher Barbara M, la Nasa Jacopo, Biale Greta, Rauert Cassandra, Okoffo Elvis D, Undas Anna, An Lihui, Wachtendorf Volker, Fengler Petra, Altmann Korinna

机构信息

Bundesanstalt für Materialforschung und-prüfung (BAM), Unter den Eichen 87, 12205 Berlin, Germany.

Nestlé Quality Assurance Center Vittel, 1020 Avenue Georges Clemenceau, 88804 Vittel Cedex, France.

出版信息

Anal Chem. 2025 Apr 29;97(16):8719-8728. doi: 10.1021/acs.analchem.4c05403. Epub 2025 Apr 17.

DOI:10.1021/acs.analchem.4c05403

PMID:40245083

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12044667/

Abstract

In this study, we investigate the current accuracy of widely used microplastic (MP) detection methods through an interlaboratory comparison (ILC) involving ISO-approved techniques. The ILC was organized under the prestandardization platform of VAMAS (Versailles Project on Advanced Materials and Standards) and gathered a large number (84) of analytical laboratories across the globe. The aim of this ILC was (i) to test and to compare two thermo-analytical and three spectroscopical methods with respect to their suitability to identify and quantify microplastics in a water-soluble matrix and (ii) to test the suitability of the microplastic test materials to be used in ILCs. Two reference materials (RMs), polyethylene terephthalate (PET) and polyethylene (PE) as powders with rough size ranges between 10 and 200 μm, were used to press tablets for the ILC. The following parameters had to be assessed: polymer identity, mass fraction, particle number concentration, and particle size distribution. The reproducibility, S, in thermo-analytical experiments ranged from 62%-117% (for PE) and 45.9%-62% (for PET). In spectroscopical experiments, the S varied between 121% and 129% (for PE) and 64% and 70% (for PET). Tablet dissolution turned out to be a very challenging step and should be optimized. Based on the knowledge gained, development of guidance for improved tablet filtration is in progress. Further, in this study, we discuss the main sources of uncertainties that need to be considered and minimized for preparation of standardized protocols for future measurements with higher accuracy.

摘要

在本研究中，我们通过一项涉及ISO认可技术的实验室间比对（ILC），调查了广泛使用的微塑料（MP）检测方法的当前准确性。该ILC是在先进材料与标准凡尔赛项目（VAMAS）的预标准化平台下组织开展的，汇聚了全球大量（84个）分析实验室。本次ILC的目的是：（i）测试并比较两种热分析方法和三种光谱方法，评估它们在水溶性基质中识别和量化微塑料的适用性；（ii）测试用于ILC的微塑料测试材料的适用性。使用两种参考物质（RMs），即聚对苯二甲酸乙二酯（PET）和聚乙烯（PE）粉末，其粒度大致在10至200μm之间，压制成片剂用于ILC。必须评估以下参数：聚合物种类、质量分数、颗粒数浓度和粒径分布。热分析实验中的重现性S在62% - 117%（对于PE）和45.9% - 62%（对于PET）之间。在光谱实验中，S在121%至129%（对于PE）和64%至70%（对于PET）之间变化。片剂溶解结果证明是极具挑战性的一步，需要优化。基于所获得的知识，正在开展改进片剂过滤指南的制定工作。此外，在本研究中，我们讨论了在制定未来更高精度测量的标准化方案时需要考虑并尽量减少的主要不确定来源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/194c/12044667/ef163283935b/ac4c05403_0001.jpg

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实验室间比对揭示了微塑料检测与定量方法的现状。

Interlaboratory Comparison Reveals State of the Art in Microplastic Detection and Quantification Methods.

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