Transfer of 7 Organic UV Filters from Sediment to the Ragworm Hediste diversicolor: Bioaccumulation of Benzophenone-3 and Further Proof of Octocrylene Metabolism

Fanny Clergeaud, S. Fagervold, A. Rodrigues, Evane Thorel, D. Stien, P. Lebaron
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引用次数: 7

Abstract

Organic UV filters are continuously released in aquatic ecosystems due to their widespread use, especially in touristic coastal environments. Generally, organic UV filters are poorly soluble in water and tend to accumulate in the sediment compartment. This represents a conceivable risk for sediment-dwelling organisms and a potential for transfer of the UV filters up the food chain. This study aimed to assess the potential transfer of seven UV filters including benzophenone-3 (BP3), bis-ethylhexyloxyphenol methoxyphenyl triazine (BEMT), butyl methoxydibenzoylmethane (BM), methylene bis-benzotriazolyl tetramethylbutylphenol (MBBT), 2-ethylhexyl salicylate (ES), diethylhexyl butamido triazone (DBT), and octocrylene (OC) from artificial spiked sediment (10 µg·g−1 dry weight) to sediment-dwelling worms. All UV filters were detected in the worms after 28 days of exposure, but only BP3 was apparently bioaccumulated, with a biota sediment accumulation factor (BSAF) of 12.38 ± 4.65. However, metabolomic profiling revealed that OC was metabolized by the worms into 11 fatty acid conjugates, demonstrating that OC did also accumulate in the worms in the form of OC–fatty acid conjugates. Here, the sole quantification of the parent organic UV filter underestimated the accumulation factor and the exposure of organisms. In general, it is therefore important to pair the conventional method (BSAF calculus) with other techniques, such as metabolomics, to assess the actual potential for bioaccumulation of xenobiotics including transformed xenobiotics.
7种有机紫外线过滤器从沉积物到杂色沙蚕的转移:二苯甲酮-3的生物积累和八烯代谢的进一步证明
有机紫外线过滤器由于其广泛使用,在水生生态系统中不断释放,特别是在沿海旅游环境中。一般来说,有机紫外线过滤器很难溶于水,容易积聚在沉淀物中。这对生活在沉积物中的生物来说是一种可能的风险,而且紫外线过滤器可能会在食物链中向上转移。本研究旨在评估二苯甲酮-3 (BP3)、二乙基己基氧基苯酚甲氧基苯基三嗪(BEMT)、丁基甲氧基二苯甲酰甲烷(BM)、亚甲基二苯并三唑四甲基丁基苯酚(MBBT)、2-乙基己基水杨酸酯(ES)、二乙基己基丁基三嗪酮(DBT)和八烯(OC)等7种紫外线过滤器从人工加钉沉积物(10µg·g−1干重)中转移到生活在沉积物中的蠕虫体内的可能性。暴露28 d后,线虫体内检测到所有的紫外线过滤器,但只有BP3有明显的生物积累,其生物群沉积物积累因子(BSAF)为12.38±4.65。然而,代谢组学分析显示,OC被蠕虫代谢成11种脂肪酸偶联物,这表明OC也以OC -脂肪酸偶联物的形式在蠕虫体内积累。在这里,对母体有机紫外线过滤器的单一量化低估了积累因子和生物体的暴露。因此,一般来说,重要的是将传统方法(BSAF演算)与其他技术(如代谢组学)相结合,以评估包括转化的外源物在内的外源物生物积累的实际潜力。
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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