高级搜索

不同粒径轮胎微塑料对大型溞的慢性毒性研究

downloadPDF

上一篇

下一篇

王宁, 王梅, 徐晨馨, 许心怡, 谭巧国, 罗专溪. 不同粒径轮胎微塑料对大型溞的慢性毒性研究[J]. 生态毒理学报, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
引用本文: 王宁, 王梅, 徐晨馨, 许心怡, 谭巧国, 罗专溪. 不同粒径轮胎微塑料对大型溞的慢性毒性研究[J]. 生态毒理学报, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
shu
Wang Ning, Wang Mei, Xu Chenxin, Xu Xinyi, Tan Qiaoguo, Luo Zhuanxi. Chronic Toxicity of Tire-derived Microplastics of Different Sizes to Daphnia magna[J]. Asian journal of ecotoxicology, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
Citation: Wang Ning, Wang Mei, Xu Chenxin, Xu Xinyi, Tan Qiaoguo, Luo Zhuanxi. Chronic Toxicity of Tire-derived Microplastics of Different Sizes to Daphnia magna[J]. Asian journal of ecotoxicology, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
shu

不同粒径轮胎微塑料对大型溞的慢性毒性研究

  • 1. 华侨大学化工学院,厦门 361021;

  • 2. 厦门大学环境与生态学院,厦门 361102

    • 作者简介: 王宁(1988-),女,博士,研究方向为生态毒理学,E-mail:wangning@hqu.edu.cn
    通讯作者: 罗专溪, E-mail: zxluo@hqu.edu.cn
  • 基金项目:

    福建省高校产学合作项目(2022N5002);华侨大学引进人才科研启动项目(605-50Y19047)

  • 中图分类号: X171.5

Chronic Toxicity of Tire-derived Microplastics of Different Sizes to Daphnia magna

  • 1. College of Chemical Engineering, Huaqiao University, Xiamen 361021, China;

  • 2. College of the Environment and Ecology, Xiamen University, Xiamen 361102, China

    • Corresponding author: Luo Zhuanxi, zxluo@hqu.edu.cn
  • Fund Project:

摘要

  • 摘要: 轮胎微塑料是环境中微塑料的重要来源之一,而关于环境浓度轮胎微塑料长期暴露的慢性毒性研究相对较少,其毒性机制尚不明晰。本文以大型溞为受试生物,研究不同粒径(依次过100目、150目和200目筛)轮胎微塑料对大型溞的存活、蜕皮和繁殖的影响,并通过测定大型溞体内重金属累积量及蛋白质/脂肪比值变化来分析轮胎微塑料的致毒机制。结果表明,轮胎微塑料暴露组中大型溞的死亡率均<20%,轮胎微塑料对大型溞蜕皮数和平均产幼数均无明显的不利影响,但对存活率的影响与颗粒粒径相关,在0.5 mg·L-1时存活率随粒径的减小而升高,62.5 mg·L-1时则刚好相反。此外,暴露在62.5 mg·L-1轮胎微塑料悬浮液中大型溞初次生产的时间推迟3~5 d,内禀增长率降低,这可能是由轮胎微塑料的摄入所导致的。摄入的轮胎微塑料本身对大型溞肠道造成刺激,并在其体内释放有害物质,这从暴露后大型溞体内重金属Co、Cu和Zn含量的增加可以看出。因此,环境相关浓度下轮胎微塑料的摄入对水生生物(如大型溞)造成的负面影响很小,但道路冲刷雨水的直接受纳水体可能会因为轮胎微塑料的存在而威胁水生生态系统健康。
    Abstract: Tire-derived microplastics (TMPs) are recognized as a major source of microplastic in the environment. However, studies on the toxicity of TMPs are limited, and their associated toxicity mechanism still remains unclear. Thus, we investigated the chronic toxicity effects of the presence of TMPs, by exposing Daphnia magna (D. magna) to TMPs of three different size ranges (by successively sieving through three sieves with a mesh-number of 100, 150, and 200 respectively) at two different concentrations (0.5 mg·L-1 and 62.5 mg·L-1). The mortality, molting and reproduction of D. magna were selected as toxicity endpoints, and the related toxicity mechanism was discussed based on the change of the metal concentrations and the protein-to-lipid ratios of organism tissue. The toxicity results showed that the 21-d mortality of D. magna at all exposed conditions were less than 20%, and no significant adverse effects on the molting and reproduction. Particularly, larger TMPs were more toxic to D. magna at the lower concentration of TMPs (0.5 mg·L-1), whereas smaller TMPs were more toxic at higher exposure concentration (62.5 mg·L-1). Further, higher concentration of TMPs influenced the reproduction of D. magna by delaying the time of the first brood for 3~5 d. As evidenced by elevated tissue metal concentrations, these toxic effects at the higher concentration TMPs treatment were likely attributed to ingestion of TMPs, which may irritate the physiological activity of guts in the organism and release toxic chemicals to the organism. These findings suggest that long-term exposure to environmentally-realistic levels of TMPs causes no to low level of toxicity to the aquatic organism such as D. magna, yet the health of aquatic ecosystem that receives direct input of road runoff may be influenced by the presence of high concentration of TMPs.
  • 加载中
  • Hartmann N B, Hüffer T, Thompson R C, et al. Are we speaking the same language? Recommendations for a definition and categorization framework for plastic debris[J]. Environmental Science & Technology, 2019, 53(3):1039-1047
    Redondo-Hasselerharm P E, de Ruijter V N, Mintenig S M, et al. Ingestion and chronic effects of car tire tread particles on freshwater benthic macroinvertebrates[J]. Environmental Science & Technology, 2018, 52(23):13986-13994
    Kole P J, L hr A J, Van Belleghem F G A J, et al. Wear and tear of tyres:A stealthy source of microplastics in the environment[J]. International Journal of Environmental Research and Public Health, 2017, 14(10):1265
    Wagner S, Hüffer T, Kl ckner P, et al. Tire wear particles in the aquatic environment-A review on generation, analysis, occurrence, fate and effects[J]. Water Research, 2018, 139:83-100
    Wik A, Nilsson E, Källqvist T, et al. Toxicity assessment of sequential leachates of tire powder using a battery of toxicity tests and toxicity identification evaluations[J]. Chemosphere, 2009, 77(7):922-927
    Marwood C, McAtee B, Kreider M, et al. Acute aquatic toxicity of tire and road wear particles to alga, daphnid, and fish[J]. Ecotoxicology, 2011, 20(8):2079-2089
    Li L Y, Li M M, Deng H, et al. A straight forward method for measuring the range of apparent density of microplastics[J]. The Science of the Total Environment, 2018, 639:367-373
    Romih T, Jemec A, Novak S, et al. FTIR microscopy reveals distinct biomolecular profile of crustacean digestive glands upon subtoxic exposure to ZnO nanoparticles[J]. Nanotoxicology, 2016, 10(4):462-470
    Kreider M L, Panko J M, McAtee B L, et al. Physical and chemical characterization of tire-related particles:Comparison of particles generated using different methodologies[J]. The Science of the Total Environment, 2010, 408(3):652-659
    Leads R R, Weinstein J E. Occurrence of tire wear particles and other microplastics within the tributaries of the Charleston Harbor Estuary, South Carolina, USA[J]. Marine Pollution Bulletin, 2019, 145:569-582
    Ziajahromi S, Drapper D, Hornbuckle A, et al. Microplastic pollution in a stormwater floating treatment wetland:Detection of tyre particles in sediment[J]. The Science of the Total Environment, 2020, 713:136356
    Khan F R, Halle L L, Palmqvist A. Acute and long-term toxicity of micronized car tire wear particles to Hyalella azteca[J]. Aquatic Toxicology, 2019, 213:105216
    Halle L L, Palmqvist A, Kampmann K, et al. Tire wear particle and leachate exposures from a pristine and road-worn tire to Hyalella azteca:Comparison of chemical content and biological effects[J]. Aquatic Toxicology, 2021, 232:105769
    Tian Z Y, Zhao H Q, Peter K T, et al. A ubiquitous tire rubber-derived chemical induces acute mortality in coho salmon[J]. Science, 2021, 371(6525):185-189
    Luo Z X, Zhou X Y, Su Y, et al. Environmental occurrence, fate, impact, and potential solution of tire microplastics:Similarities and differences with tire wear particles[J]. The Science of the Total Environment, 2021, 795:148902
  • 加载中
    Created with Highcharts 5.0.7访问量Chart context menu近一年内文章摘要浏览量、全文浏览量、PDF下载量统计信息摘要浏览量全文浏览量PDF下载量2024-052024-062024-072024-082024-092024-102024-112024-122025-012025-022025-032025-0401234Highcharts.com
    Created with Highcharts 5.0.7Chart context menu访问类别分布DOWNLOAD: 19.3 %DOWNLOAD: 19.3 %HTML全文: 66.3 %HTML全文: 66.3 %摘要: 14.3 %摘要: 14.3 %DOWNLOADHTML全文摘要Highcharts.com
    Created with Highcharts 5.0.7Chart context menu访问地区分布其他: 95.7 %其他: 95.7 %XX: 2.1 %XX: 2.1 %北京: 0.2 %北京: 0.2 %广州: 0.2 %广州: 0.2 %杭州: 0.2 %杭州: 0.2 %桂林: 0.2 %桂林: 0.2 %济源: 0.2 %济源: 0.2 %湘西: 0.2 %湘西: 0.2 %苏州: 0.2 %苏州: 0.2 %费城: 0.2 %费城: 0.2 %赣州: 0.2 %赣州: 0.2 %阿什本: 0.2 %阿什本: 0.2 %青岛: 0.2 %青岛: 0.2 %其他XX北京广州杭州桂林济源湘西苏州费城赣州阿什本青岛Highcharts.com
WeChat 点击查看大图
计量
  • 文章访问数:  2376
  • HTML全文浏览数:  2376
  • PDF下载数:  173
  • 施引文献:  0
出版历程
  • 收稿日期:  2022-10-14
王宁, 王梅, 徐晨馨, 许心怡, 谭巧国, 罗专溪. 不同粒径轮胎微塑料对大型溞的慢性毒性研究[J]. 生态毒理学报, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
引用本文: 王宁, 王梅, 徐晨馨, 许心怡, 谭巧国, 罗专溪. 不同粒径轮胎微塑料对大型溞的慢性毒性研究[J]. 生态毒理学报, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
shu
Wang Ning, Wang Mei, Xu Chenxin, Xu Xinyi, Tan Qiaoguo, Luo Zhuanxi. Chronic Toxicity of Tire-derived Microplastics of Different Sizes to Daphnia magna[J]. Asian journal of ecotoxicology, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
Citation: Wang Ning, Wang Mei, Xu Chenxin, Xu Xinyi, Tan Qiaoguo, Luo Zhuanxi. Chronic Toxicity of Tire-derived Microplastics of Different Sizes to Daphnia magna[J]. Asian journal of ecotoxicology, 2022, 17(6): 69-76. doi: 10.7524/AJE.1673-5897.20221014002
shu

不同粒径轮胎微塑料对大型溞的慢性毒性研究

    通讯作者: 罗专溪, E-mail: zxluo@hqu.edu.cn
    作者简介: 王宁(1988-),女,博士,研究方向为生态毒理学,E-mail:wangning@hqu.edu.cn
  • 1. 华侨大学化工学院,厦门 361021;
  • 2. 厦门大学环境与生态学院,厦门 361102
  • 收稿日期:  2022-10-14
基金项目:

福建省高校产学合作项目(2022N5002);华侨大学引进人才科研启动项目(605-50Y19047)

摘要: 轮胎微塑料是环境中微塑料的重要来源之一,而关于环境浓度轮胎微塑料长期暴露的慢性毒性研究相对较少,其毒性机制尚不明晰。本文以大型溞为受试生物,研究不同粒径(依次过100目、150目和200目筛)轮胎微塑料对大型溞的存活、蜕皮和繁殖的影响,并通过测定大型溞体内重金属累积量及蛋白质/脂肪比值变化来分析轮胎微塑料的致毒机制。结果表明,轮胎微塑料暴露组中大型溞的死亡率均<20%,轮胎微塑料对大型溞蜕皮数和平均产幼数均无明显的不利影响,但对存活率的影响与颗粒粒径相关,在0.5 mg·L-1时存活率随粒径的减小而升高,62.5 mg·L-1时则刚好相反。此外,暴露在62.5 mg·L-1轮胎微塑料悬浮液中大型溞初次生产的时间推迟3~5 d,内禀增长率降低,这可能是由轮胎微塑料的摄入所导致的。摄入的轮胎微塑料本身对大型溞肠道造成刺激,并在其体内释放有害物质,这从暴露后大型溞体内重金属Co、Cu和Zn含量的增加可以看出。因此,环境相关浓度下轮胎微塑料的摄入对水生生物(如大型溞)造成的负面影响很小,但道路冲刷雨水的直接受纳水体可能会因为轮胎微塑料的存在而威胁水生生态系统健康。

English Abstract

参考文献 (15)

返回顶部

目录

/

返回文章
返回

Copyright © 2019 中国科学院生态环境研究中心

京ICP备05002858号-9