Methods used in the identification and quantification of micro(nano)plastics from water environments

Q1 Social Sciences

South African Journal of Chemical Engineering Pub Date : 2024-10-01 DOI:10.1016/j.sajce.2024.09.010

Caglar Berkel, Oguz Özbek

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引用次数: 0

Abstract

Micro(nano)plastics (MNPs) pollution, which has currently become a serious environmental problem, poses a great risk to ecosystem health and biodiversity. The adverse effects of MNPs in different characteristics on organismal homeostasis are intensively studied due to their considerable threats to ecology and human/public health, since they have been identified in human blood, placenta and breast milk. To date, many studies have been carried out on MNPs, and remarkable results have been reported on their diversity, distribution, origins and their influences at the cellular level, to name a few. The literature suggests that the extent of the risk caused by MNPs is increasing significantly every year, making it even more critical and urgent to combat MNPs pollution in the environment including aquatic environments. Therefore, it is highly important to identify, quantify and monitor MNPs, especially in the water environments since it represents one of the main transportation routes of MNPs. In this review, we provide a broad and critical overview of the different methods, such as Fourier transform infrared spectroscopy (FT–IR), Raman spectroscopy, transmission/scanning electron microscopy (TEM/SEM), and gas chromatography–mass spectrometry (GC–MS), currently used in the identification and quantification of MNPs, especially in aquatic environments such as seawater and marine sediments. Each of these previous methodologies has its own unique advantages and limitations; besides, there is no validated and standardized analytical method for MNPs determination, implying that more than one method or the combinations of different methodologies are required to obtain accurate data at the current state. Moreover, considering the presence of high variability of data among different methods, more research is needed to develop a universal analytical protocol to increase reproducibility and robustness of the findings on MNPs contamination in the environment, in order to increase the credibility and impact of the field.

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用于识别和量化水环境中的微型（纳米）塑料的方法

微（纳米）塑料（MNPs）污染目前已成为一个严重的环境问题，对生态系统健康和生物多样性构成了巨大风险。由于在人体血液、胎盘和母乳中发现了不同特性的 MNPs，它们对生态学和人类/公众健康造成了巨大威胁，因此人们正在深入研究 MNPs 对生物体平衡的不利影响。迄今为止，已对 MNPs 进行了大量研究，并在其多样性、分布、起源及其在细胞水平的影响等方面取得了显著成果。文献表明，MNPs 所造成的风险程度每年都在显著增加，因此，应对环境（包括水生环境）中的 MNPs 污染变得更加重要和紧迫。因此，识别、量化和监测 MNPs 非常重要，尤其是在水环境中，因为水是 MNPs 的主要运输途径之一。在本综述中，我们对目前用于识别和定量 MNPs（尤其是海水和海洋沉积物等水生环境中的 MNPs）的不同方法（如傅立叶变换红外光谱法 (FT-IR)、拉曼光谱法、透射/扫描电子显微镜 (TEM/SEM) 和气相色谱-质谱法 (GC-MS)）进行了广泛而严谨的概述。以往的这些方法各有其独特的优势和局限性；此外，目前还没有经过验证和标准化的 MNPs 测定分析方法，这意味着目前需要一种以上的方法或不同方法的组合才能获得准确的数据。此外，考虑到不同方法之间的数据存在很大差异，因此需要开展更多研究来制定通用分析规程，以提高环境中 MNPs 污染研究结果的可重复性和稳健性，从而增强该领域的可信度和影响力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

South African Journal of Chemical Engineering Social Sciences-Education

CiteScore

8.40

自引率

0.00%

发文量

100

审稿时长

33 weeks

期刊介绍： The journal has a particular interest in publishing papers on the unique issues facing chemical engineering taking place in countries that are rich in resources but face specific technical and societal challenges, which require detailed knowledge of local conditions to address. Core topic areas are: Environmental process engineering • treatment and handling of waste and pollutants • the abatement of pollution, environmental process control • cleaner technologies • waste minimization • environmental chemical engineering • water treatment Reaction Engineering • modelling and simulation of reactors • transport phenomena within reacting systems • fluidization technology • reactor design Separation technologies • classic separations • novel separations Process and materials synthesis • novel synthesis of materials or processes, including but not limited to nanotechnology, ceramics, etc. Metallurgical process engineering and coal technology • novel developments related to the minerals beneficiation industry • coal technology Chemical engineering education • guides to good practice • novel approaches to learning • education beyond university.