Predator traits influence uptake and trophic transfer of nanoplastics in aquatic systems-a mechanistic study.

Microplastics and nanoplastics Pub Date : 2024-01-01 Epub Date: 2024-10-09 DOI:10.1186/s43591-024-00096-4

Amy Ockenden, Denise M Mitrano, Melanie Kah, Louis A Tremblay, Kevin S Simon

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Abstract

Predicting the response of aquatic species to environmental contaminants is challenging, in part because of the diverse biological traits within communities that influence their uptake and transfer of contaminants. Nanoplastics are a contaminant of growing concern, and previous research has documented their uptake and transfer in aquatic food webs. Employing an established method of nanoplastic tracking using metal-doped plastics, we studied the influence of biological traits on the uptake of nanoplastic from water and diet in freshwater predators through two exposure assays. We focused on backswimmers (Anisops wakefieldi) and damselfly larvae (Xanthocnemis zealandica) - two freshwater macroinvertebrates with contrasting physiological and morphological traits related to feeding and respiration strategies. Our findings reveal striking differences in nanoplastic transfer dynamics: damselfly larvae accumulated nanoplastics from water and diet and then efficiently eliminated 92% of nanoplastic after five days of depuration. In contrast, backswimmers did not accumulate nanoplastic from either source. Differences in nanoplastic transfer dynamics may be explained by the contrasting physiological and morphological traits of these organisms. Overall, our results highlight the importance and potential of considering biological traits in predicting transfer of nanoplastics through aquatic food webs.

Supplementary information: The online version contains supplementary material available at 10.1186/s43591-024-00096-4.

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捕食者特征影响纳米塑料在水生系统中的吸收和营养转移--一项机理研究。

预测水生物种对环境污染物的反应具有挑战性，部分原因是生物群落中的生物特征各不相同，影响着它们对污染物的吸收和转移。纳米塑料是一种日益受到关注的污染物，以前的研究已经记录了它们在水生食物网中的吸收和转移。利用掺金属塑料追踪纳米塑料的成熟方法，我们通过两种暴露试验研究了生物特征对淡水捕食者从水中吸收纳米塑料和饮食的影响。我们重点研究了仰泳鱼（Anisops wakefieldi）和豆娘幼虫（Xanthocnemis zealandica）--这两种淡水大型无脊椎动物，它们的生理和形态特征与摄食和呼吸策略截然不同。我们的发现揭示了纳米塑料转移动态的显著差异：豆娘幼虫从水中和食物中积累纳米塑料，然后在五天的净化后有效地消除了 92% 的纳米塑料。与此相反，仰泳动物没有从任何一种来源积累纳米塑料。纳米塑料转移动态的差异可能是由于这些生物的生理和形态特征截然不同造成的。总之，我们的研究结果突显了在预测纳米塑料通过水生食物网转移时考虑生物特征的重要性和潜力：在线版本包含补充材料，可查阅 10.1186/s43591-024-00096-4。

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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Microplastics and nanoplastics

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