Neurotoxicological mechanisms of carbon quantum dots in a new animal model Dugesia japonica.

IF 2.4 4区环境科学与生态学 Q2 ECOLOGY

Ecotoxicology Pub Date : 2023-08-01 DOI:10.1007/s10646-023-02671-6

Jing Kang, Qing Ai, Ang Zhao, Haijiao Wang, Xiangpeng Zhang, Yanli Liu, Lingke Zhang, Yuqing Liu

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Abstract

As luminescent nanomaterials, the carbon quantum dots (CQDs) research focused on emerging applications since their discovery. However, their toxicological effects on the natural environment are still unclear. The freshwater planarian Dugesia japonica is distributed extensively in aquatic ecosystems and can regenerate a new brain in 5 days after amputation. Therefore it can be used as a new model organism in the field of neuroregeneration toxicology. In our study, D. japonica was cut and incubated in medium treated with CQDs. The results showed that the injured planarian lost the neuronal ability of brain regeneration after treatment with CQDs. Its Hh signalling system was interfered with at Day 5, and all cultured pieces died on or before Day 10 due to head lysis. Our work reveals that CQDs might affect the nerve regeneration of freshwater planarians via the Hh signalling pathway. The results of this study improve our understanding of CQD neuronal development toxicology and can aid in the development of warning systems for aquatic ecosystem damage.

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碳量子点在一种新型动物模型中的神经毒理学机制。

碳量子点作为一种发光纳米材料，自发现以来一直是研究热点。然而，它们对自然环境的毒理学影响尚不清楚。淡水涡虫日本Dugesia japonica广泛分布于水生生态系统中，在截肢后5天内可再生新脑。因此，它可以作为神经再生毒理学领域的一种新的模式生物。在我们的研究中，粳稻被切割并在CQDs处理的培养基中培养。结果表明，经CQDs处理后，损伤涡虫丧失了脑再生的神经元能力。其Hh信号系统在第5天受到干扰，所有培养片段在第10天或之前因头部裂解而死亡。我们的研究表明，CQDs可能通过Hh信号通路影响淡水涡虫的神经再生。本研究结果提高了我们对CQD神经元发育毒理学的认识，并有助于开发水生生态系统损害预警系统。

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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来源期刊

Ecotoxicology 环境科学-毒理学

CiteScore

5.30

自引率

3.70%

发文量

107

审稿时长

4.7 months

期刊介绍： Ecotoxicology is an international journal devoted to the publication of fundamental research on the effects of toxic chemicals on populations, communities and terrestrial, freshwater and marine ecosystems. It aims to elucidate mechanisms and processes whereby chemicals exert their effects on ecosystems and the impact caused at the population or community level. The journal is not biased with respect to taxon or biome, and papers that indicate possible new approaches to regulation and control of toxic chemicals and those aiding in formulating ways of conserving threatened species are particularly welcome. Studies on individuals should demonstrate linkage to population effects in clear and quantitative ways. Laboratory studies must show a clear linkage to specific field situations. The journal includes not only original research papers but technical notes and review articles, both invited and submitted. A strong, broadly based editorial board ensures as wide an international coverage as possible.