Ehsan Hashemi , John P. Giesy , Zhuobin Liang , Omid Akhavan , Aidin Rahim Tayefeh , Morteza Daliri Joupari , Mohammad Hossein Sanati , Parvin Shariati , Mehdi Shamsara , Abbas Farmany
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Understanding the extent and impact of nanomaterial contamination on aquatic biota is crucial for effective mitigation strategies. To address this challenge, we conducted a comprehensive study evaluating the bioaccumulation effects of graphene oxide (GO), a commonly used nanomaterial, within an aquatic food chain. Using a gnotobiotic freshwater microcosm, we investigated the effects of micro- and nano-scale GO sheets on key organisms: green algae (Chlorella vulgaris), brine shrimp (Artemia salina), and zebrafish (Danio rerio). Two feeding regimes, direct ingestion and trophic transfer, were employed to assess GO uptake and transfer within the food web. Direct exposure involved individual organisms being exposed to either nano- or micro-scale GO sheets, while trophic transfer involved a sequential exposure pathway: algae exposed to GO sheets, artemias feeding on the algae, and zebrafish consuming the artemias. Our study provides critical insights into nanomaterial contamination in aquatic ecosystems. Physicochemical properties of GO sheets, including ζ-potential and dispersion, were influenced by salt culture media, resulting in aggregation under salt conditions. Microscopic imaging confirmed the bioaccumulation of GO sheets within organisms, indicating prolonged exposure and potential long-term effects. Notably, biodistribution analysis in zebrafish demonstrated the penetration of nano-sized GO into the intestinal wall, signifying direct interaction with vital organs. Exposure to GO resulted in increased zebrafish mortality and impaired reproductive performance, particularly through trophic transfer. These findings emphasize the urgent need to address nanomaterial contamination in aquatic food webs to protect ecosystem components and human consumers. Our study highlights the importance of developing effective mitigation strategies to preserve the integrity of aquatic ecosystems, ensure resource sustainability, and safeguard human well-being. In conclusion, our study provides crucial insights into the impact of nanomaterial pollution on aquatic biota. 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引用次数: 0
摘要
纳米材料对水生食物网的污染对生态和人类健康构成了重大挑战。在摄入食物的同时摄入纳米材料会扰乱消化过程并损害生理过程,从而对生物体的健康和生存造成潜在影响。纳米材料与生物群之间复杂的相互作用进一步加剧了这一问题,影响了生命史策略和生态系统动态。纳米材料在自养食物网和基于残渣的食物网中的积累引起了生物放大的担忧,尤其是对顶级消费者和依赖海产品的人类而言。了解纳米材料污染的程度及其对水生生物群的影响对于制定有效的缓解策略至关重要。为了应对这一挑战,我们开展了一项综合研究,评估常用纳米材料氧化石墨烯(GO)在水生食物链中的生物累积效应。我们利用一个非生物淡水微观世界,研究了微米级和纳米级 GO 片材对主要生物的影响:绿藻(Chlorella vulgaris)、盐水虾(Artemia salina)和斑马鱼(Danio rerio)。为了评估食物网中对 GO 的吸收和转移情况,采用了两种喂养方式,即直接摄取和营养转移。直接接触是指生物个体接触纳米级或微米级的 GO 片材,而营养转移则是指生物个体依次接触 GO 片材:藻类接触 GO 片材、蓟马以藻类为食、斑马鱼食用蓟马。我们的研究为了解水生生态系统中的纳米材料污染提供了重要依据。GO 片的物理化学特性(包括ζ电位和分散性)受到盐培养基的影响,导致其在盐条件下聚集。显微成像证实了 GO 片在生物体内的生物累积性,表明生物体长期接触 GO 片,可能会受到长期影响。值得注意的是,对斑马鱼进行的生物分布分析表明,纳米级的 GO 可渗透到肠壁,这表明 GO 可与重要器官直接相互作用。暴露于 GO 会导致斑马鱼死亡率上升,生殖能力受损,特别是通过营养传递。这些发现强调,迫切需要解决水生食物网中的纳米材料污染问题,以保护生态系统组成部分和人类消费者。我们的研究强调了制定有效的缓解策略以保护水生生态系统完整性、确保资源可持续性和保障人类福祉的重要性。总之,我们的研究提供了纳米材料污染对水生生物群影响的重要见解。通过认识纳米材料污染带来的挑战并实施有针对性的干预措施,我们可以减轻其不利影响,保护水生生态系统的完整性并保障人类健康。
Impacts of graphene oxide contamination on a food web: Threats to somatic and reproductive health of organisms
Contamination of aquatic food webs with nanomaterials poses a significant ecological and human health challenge. Ingestion of nanomaterials alongside food disrupts digestion and impairs physiological processes, with potential consequences for organism fitness and survival. Complex interactions between nanomaterials and biota further exacerbate the issue, influencing life-history strategies and ecosystem dynamics. Accumulation of nanomaterials within autotrophic and detritus-based food webs raises concerns about biomagnification, especially for top-level consumers and seafood-dependent human populations. Understanding the extent and impact of nanomaterial contamination on aquatic biota is crucial for effective mitigation strategies. To address this challenge, we conducted a comprehensive study evaluating the bioaccumulation effects of graphene oxide (GO), a commonly used nanomaterial, within an aquatic food chain. Using a gnotobiotic freshwater microcosm, we investigated the effects of micro- and nano-scale GO sheets on key organisms: green algae (Chlorella vulgaris), brine shrimp (Artemia salina), and zebrafish (Danio rerio). Two feeding regimes, direct ingestion and trophic transfer, were employed to assess GO uptake and transfer within the food web. Direct exposure involved individual organisms being exposed to either nano- or micro-scale GO sheets, while trophic transfer involved a sequential exposure pathway: algae exposed to GO sheets, artemias feeding on the algae, and zebrafish consuming the artemias. Our study provides critical insights into nanomaterial contamination in aquatic ecosystems. Physicochemical properties of GO sheets, including ζ-potential and dispersion, were influenced by salt culture media, resulting in aggregation under salt conditions. Microscopic imaging confirmed the bioaccumulation of GO sheets within organisms, indicating prolonged exposure and potential long-term effects. Notably, biodistribution analysis in zebrafish demonstrated the penetration of nano-sized GO into the intestinal wall, signifying direct interaction with vital organs. Exposure to GO resulted in increased zebrafish mortality and impaired reproductive performance, particularly through trophic transfer. These findings emphasize the urgent need to address nanomaterial contamination in aquatic food webs to protect ecosystem components and human consumers. Our study highlights the importance of developing effective mitigation strategies to preserve the integrity of aquatic ecosystems, ensure resource sustainability, and safeguard human well-being. In conclusion, our study provides crucial insights into the impact of nanomaterial pollution on aquatic biota. By recognizing the challenges posed by nanomaterial contamination and implementing targeted interventions, we can mitigate the adverse effects, preserving the integrity of aquatic ecosystems and safeguarding human health.
期刊介绍:
Ecotoxicology and Environmental Safety is a multi-disciplinary journal that focuses on understanding the exposure and effects of environmental contamination on organisms including human health. The scope of the journal covers three main themes. The topics within these themes, indicated below, include (but are not limited to) the following: Ecotoxicology、Environmental Chemistry、Environmental Safety etc.