常用水产饲料及其原料中微塑料的污染特征研究OA
Characteristics of Microplastics and Feed Raw Material Contamination in Common Aquatic Feeds
微塑料污染目前为全球性环境问题,水生生物对微塑料的摄食已被广泛报道,其中养殖水环境中的生物也受到威胁.由于水产饲料的使用也是养殖过程中外部输入微塑料的潜在途径,因此,确定微塑料在水产饲料中的含量是评估微塑料对养殖环境安全及产品质量的关键.本研究基于5种典型的水产养殖动物包括鱼类和甲壳类,选取10款水产饲料和9种饲料原料进行分析.研究采用化学消解、显微镜计数和傅里叶红外光谱定性确定样品中微塑料的浓度.研究结果显示,所有分析的饲料和原料样本微塑料检出率均为100%,饲料中微塑料平均丰度为(0.77±0.21)个/g,原料中微塑料平均丰度为(1.09±0.24)个/g.与全球数据相比,我国水产饲料及原料中微塑料的污染处于中等偏低水平.纤维是饲料和原料中微塑料最主要的形状,微塑料粒径高峰在500~1 500 μm之间.饲料样品的聚合物中聚丙烯(PP)和聚对苯二甲酸乙二醇酯(PET)含量较高,原料样品的聚合物中人造纤维丝含量最高,二者聚合物种类有部分重叠.本研究发现,饲料和原料中螃蟹饲料和麸皮的微塑料污染最为显著,受关注较多的鱼饲料和鱼粉相比污染反而较少,原料的污染是饲料受微塑料污染的重要原因,但饲料加工过程可能会去除原料携带的部分微塑料.研究结果为评估我国水产饲料微塑料污染状况提供了科学依据,也是评估水产养殖系统的微塑料污染来源的基础,为最终改善提高水产品质量提供了参考.
Microplastic pollution has become a pressing global environmental issue in recent years.Extensive research has documented the ingestion of microplastics by various aquatic organisms,including those raised in aquaculture systems.The use of aquafeeds has emerged as a potential pathway for increased input of microplastics into aquaculture systems.Therefore,accurately determining the content of microplastics in aquafeeds is of crucial importance for accurately assessing the potential risks that microplastics may pose to the safety of aquaculture environments and the quality of aquaculture products.Previous studies have provided some insights into the status of microplastic pollution in certain types of aquafeeds and fishmeal;however,there are still gaps in this research area,particularly with respect to aquaculture in China.Data on aquafeed ingredients other than fishmeal—such as plant-based raw materials and novel alternative raw materials for fishmeal—remain scarce.To address these limitations,we designed the present study with a focus on aquafeeds(including the raw material)commonly used in the aquaculture industry in China. The aquafeeds selected in this study are formulated for five typical aquaculture species,including fish and crustaceans.A total of 10 aquafeed samples and nine feed ingredient samples were collected and subjected to detailed analysis,including microplastic detection and analysis.These methods included chemical digestion,which was used to remove organic matter from the samples and isolate microplastics;microscopic counting,which enabled the quantification of microplastics to determine their abundance;and Fourier transform infrared spectroscopy,which was applied for the qualitative identification of the polymer types of the detected microplastics. The results of our analysis confirmed that all the collected aquafeed samples and feed ingredient samples were contaminated with microplastics.The average abundance of microplastics in the aquafeed samples was(0.77±0.21)ind./g,and the average abundance of microplastics in the feed ingredient samples was(1.09±0.24)ind./g.When compared with global research data on microplastic pollution in aquafeeds and their ingredients,microplastic concentrations in the samples from this study were found to be moderately low compared to global data.In terms of the morphological characteristics of microplastics in the samples,fibers were identified as the most dominant shape in both aquafeeds and feed ingredients.Specifically,fibers accounted for 69.57%of the total microplastics in aquafeeds and 59.32%in feed ingredients.However,a notable difference was observed in specific types of feed ingredients:Film-shaped microplastics were the most abundant type in U.S.-sourced chicken meal,Australian-sourced beef bone meal,and domestically produced fishmeal.Regarding the particle size distribution,the peak particle size range was between 500 and 1,500 μm.Additionally,the particle size ranges in aquafeed samples and feed ingredient samples were relatively similar,indicating a potential connection between microplastics in ingredients and those in the final aquafeeds.Polymer,polypropylene,and polyethylene terephthalate have relatively high contents in the aquafeed samples.In contrast,man-made fiber filaments were the most abundant polymer type in the feed ingredient samples.This difference in polymer composition is most likely attributed to the widespread application of these polymers in industrial production processes,which may lead to their incorporation into feed ingredients and subsequent presence in aquafeeds.An in-depth analysis of microplastic pollution sources in aquafeeds revealed that contamination of feed ingredients is a key contributor.Beyond ingredient contamination,aquafeeds can also be contaminated with microplastics during the processing stages(such as mixing,granulation,and drying)and packaging process(such as contact with plastic packaging materials).Accordingly,greater attention should be directed toward addressing microplastic pollution in aquafeeds.Supervision and control measures can be strengthened throughout the entire process of aquafeed and feed ingredient production,including processing,packaging,and transportation,to minimize the release of microplastics into the environment.For example,avoiding the use of plastics in packaging and storage of aquafeeds and feed ingredients can help reduce the risk of microplastic contamination,thereby ensuring aquafeed safety and promoting the development of sustainable aquaculture practices.In addition,based on the specific conditions of the production environments where feed ingredients are sourced(such as water quality,soil conditions,and existing pollution levels),appropriate physical,chemical,or biological degradation methods can be selected to reduce the amount of microplastics in the environment.This,in turn,can help decrease microplastic contamination in feed ingredients. Overall,our findings confirm that microplastics are prevalent in aquafeeds used in Chinese aquaculture as well as the raw materials of these aquafeeds.Contamination of feed ingredients is an important cause of microplastic pollution in aquafeeds;thus,measures to improve aquafeed processing may potentially reduce contamination.The results of this study provide a solid scientific basis for clarifying the current status of microplastic pollution in aquafeeds in China,including identifying the main microplastic pollution sources in aquaculture systems,with the ultimate goal of improving the quality and safety of aquaculture products.
李姝婷;施瀚阳;李娟英;王茜;苏磊
上海海洋大学海洋科学与生态环境学院 上海 201306上海海洋大学水产与生命学院 上海 201306上海海洋大学海洋科学与生态环境学院 上海 201306上海海洋大学海洋科学与生态环境学院 上海 201306上海海洋大学海洋科学与生态环境学院 上海 201306
资源环境
微塑料水产养殖饲料鱼粉
MicroplasticsAquacultureFeedFishmeal
《渔业科学进展》 2026 (3)
212-224,13
上海市农业科技创新项目(I2024003)和上海海洋大学青年教师科研启动经费共同资助.
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