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巴基斯坦斯瓦特河河水、沉积物和鱼类中微塑料污染的探索,特别关注来源识别和空间格局。

Exploration of microplastic pollution with particular focus on source identification and spatial patterns in riverine water, sediment and fish of the Swat River, Pakistan.

作者信息

Khan Luqman, Ghias Sidra, Zafar Mazhar Iqbal, Alhodaib Aiyeshah, Fatima Humaria, Ur-Rehman Tofeeq, Waseem Amir, Howari Haidar

机构信息

Department of Environmental Sciences, Faculty of Biological Sciences, Quaid-i-Azam University Islamabad 45320 Pakistan

Department of Physics, College of Science, Qassim University Buraydah 51452 Saudi Arabia

出版信息

RSC Adv. 2022 Mar 28;12(16):9556-9566. doi: 10.1039/d2ra00319h. eCollection 2022 Mar 25.

DOI:10.1039/d2ra00319h
PMID:35424907
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8985192/
Abstract

Microplastics (MPs) have been reported as an emerging xenobiotic organic pollutant in freshwater ecosystems and a universal hazard for ecosystems because of the rapid increase in global demand. The present study was conducted to explore MPs' occurrence, abundance and spatial distribution in sediment, water and samples, collected from the Swat River. ATR-FTIR spectroscopy was used for chemical characterization of visually identified MPs by using standard protocols such as digestion using HO, density separation using ZnCl, vacuum filtration with borosilicate glass micro filter papers and digital microscopy using a stereomicroscope connected with a camera. Range of mass abundance of identified MPs in river sediments, river water, tributaries sediment and tributary water was found to be 0.6-2.5 mg kg, 0.7-3.8 mg L, 0.9-4.5 mg kg and 0.6-1.1 mg L respectively. Meanwhile, in digestive tracts samples, it was 0.6-1.9 mg per fish. Numeric abundance of MPs in all matrices was found to be tributary sediment (202 items per kg) > river water (192 items per L) > river sediment (182 items per kg) > fish (153 items per fish) > tributary water (92 items per L). MPs identified on the basis of morphology in all matrices were found to be fragments > fibers > pellets > films > foams. MPs were dominant in all urban stations while their spatial distribution along with the study site was heterogeneous due to the surroundings such as tourist spots, hydrodynamic conditions, and proximity to urban areas, plastic industries and due to recharge by the highly contaminated tributaries. The MPs identified on the basis of size dimensions show that S1 (0.5-1 mm) in all matrices was highest while S2 (1-5 mm) was the lowest. Primary source MPs identified were fibers, films, fragments and foams particles while secondary sources were pellets. Results of ATR-FTIR showed that PE was the most common plastic type identified in all samples followed by PVC, PET, PP and PS. This is the first study exploring the MPs' occurrence, numeric and mass abundance and spatial distribution in the SR ecosystem. The present study may be a valuable reference for better understanding the MPs' pollution in Pakistan. The findings of the present study can help to identify the potential sources (, primary and secondary) of MPs to improve waste management in the Swat District and model the transport fluxes of these microplastics in other rivers using water quality parameters and basin characteristics.

摘要

微塑料(MPs)已被报道为淡水生态系统中一种新兴的外源性有机污染物,由于全球需求的快速增长,它对生态系统构成了普遍危害。本研究旨在探索从斯瓦特河采集的沉积物、水和样本中微塑料的存在情况、丰度及空间分布。采用衰减全反射傅里叶变换红外光谱(ATR-FTIR)对通过目视识别的微塑料进行化学表征,使用的标准方法包括用双氧水消化、用氯化锌进行密度分离、用硼硅酸盐玻璃微滤纸进行真空过滤以及使用与相机相连的体视显微镜进行数字显微镜观察。在河流沉积物、河水、支流沉积物和支流水体中,已识别出的微塑料的质量丰度范围分别为0.6 - 2.5毫克/千克、0.7 - 3.8毫克/升、0.9 - 4.5毫克/千克和0.6 - 1.1毫克/升。同时,在消化道样本中,每条鱼体内的微塑料含量为0.6 - 1.9毫克。在所有基质中,微塑料的数量丰度为:支流沉积物(每千克202个)>河水(每升192个)>河流沉积物(每千克182个)>鱼类(每条鱼153个)>支流水体(每升92个)。基于形态学在所有基质中识别出的微塑料为:碎片>纤维>颗粒>薄膜>泡沫。微塑料在所有城市站点中占主导地位,但其在研究区域的空间分布因周边环境(如旅游景点、水动力条件以及与城市地区、塑料工业的距离)以及受高度污染支流的补给而呈现出异质性。基于尺寸大小识别出的微塑料表明,在所有基质中S1(0.5 - 1毫米)的含量最高,而S2(1 - 5毫米)的含量最低。已识别出的主要来源微塑料为纤维、薄膜、碎片和泡沫颗粒,次要来源为颗粒。ATR-FTIR的结果表明,聚乙烯(PE)是在所有样本中识别出的最常见塑料类型,其次是聚氯乙烯(PVC)、聚对苯二甲酸乙二酯(PET)、聚丙烯(PP)和聚苯乙烯(PS)。这是首次探索斯瓦特河生态系统中微塑料的存在情况、数量和质量丰度以及空间分布的研究。本研究可能为更好地了解巴基斯坦的微塑料污染提供有价值的参考。本研究结果有助于识别微塑料的潜在来源(主要和次要),以改善斯瓦特地区的废物管理,并利用水质参数和流域特征对其他河流中这些微塑料的输运通量进行建模。

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