LA-ICP-MS连续线样分析鳕鱼耳石微化学

IF 2 4区 地球科学 Q1 GEOLOGY
K. Hüssy, Simon Serre Hansen, K. E. Nielsen, Peter Fink-Jensen, T. Thomsen
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引用次数: 9

摘要

鱼类耳石,也称为耳石或静止石,是鱼类内耳中起运动和平衡指标作用的钙化结构(图1)。从孵化到死亡,这些结构逐渐生长,每天都有新的物质堆积在蛋白质(1-8%,Degens等人,1969)和碳酸钙的连续层中(Pannella 1971)。耳石的吸积率随鱼类生长而变化,在温带物种中,吸积率通常在冬季最低(Hüssy等人,2010)。这导致了树木中类似环状结构的同心生长(图1D),使得能够使用树木年代技术来近似鱼类的年龄和生长历史。在生长过程中,某些元素被结合到耳石结构中,有些与蛋白质有关,有些与碳酸钙成分有关(Thomas等人,2017),为鱼类生命史的不同方面提供了有价值的记录,并成为潜在的环境记录。先前的研究表明,耳石的微量元素和同位素组成可以用作重建水化学、温度和盐度的替代物(Patterson等人,1993;Thorrold&Shuttleworth,2000年)。其他研究表明,元素历史可用于研究鱼类产卵和迁徙模式(例如Sturrock等人,2012年),最近的研究使用锌、铜和镁等元素作为季节性指标(Hüssy等人,2016;林堡等人,2018)。将这种元素变化的知识与激光烧蚀电感耦合等离子体质谱法(LAICPMS)的微束能力相结合,使耳石微化学成为研究重要参数的有力工具,可持续渔业管理政策(例如种群识别、迁徙、污染指标、产卵栖息地、幼虫和幼鱼阶段的持续时间以及产卵的规模和时间)。我们介绍了丹麦和格陵兰地质调查局(GEUS)与丹麦技术大学国家水生资源研究所(DTU Aqua)合作开发的一种分析方法,用于耳石中的元素丰度分析。波罗的海鳕鱼耳石的分析(Gadus morhua;图1)用作其应用的例子。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analysis of cod otolith microchemistry by continuous line transects using LA-ICP-MS
Fish otoliths, also called ear stones or statoliths, are calcified structures functioning as movement and equilibrium indicators in the inner ear of fish (Fig. 1). From hatching to death these structures grow incrementally, with new material accreted daily (Pannella 1971) in successive layers of protein (1–8%, Degens et al. 1969) and calcium carbonate. The accretion rate of otoliths varies with fish growth, and in temperate species it is usually lowest during the winter season (Hüssy et al. 2010). This results in concentric growth resembling the ringed structure in trees (Fig. 1D), enabling the use of dendrochronological techniques to approximate the age and growth history of fish. During growth, certain elements are incorporated into the otolith structure, some associated with proteins and some with the calcium carbonate component (Thomas et al. 2017), supplying a valuable record of different aspects in fish life history and serving as a potential environmental record. Previous studies show that trace element and isotopic compositions of otoliths can be used as a proxy for reconstructing water chemistry, temperature and salinity (Patterson et al. 1993; Thorrold & Shuttleworth 2000). Other studies demonstrate that elemental histories can be used to investigate fish spawning and migration patterns (e.g. Sturrock et al. 2012), and more recent studies use elements such as Zn, Cu and Mg as indicators of seasonality (Hüssy et al. 2016; Limburg et al. 2018). Combining this knowledge of elemental variation with the micro-beam capabilities of laser ablation inductively coupled plasma mass spectrometry (LAICPMS) turns otolith microchemistry into a powerful tool for studying important parameters fundamental for establishing modern, sustainable fisheries management policies (e.g. stock identification, migration, pollution indicators, spawning habitats, duration of larval and juvenile stages, and magnitude and timing of spawning). We present an analytical method developed by the Geological Survey of Denmark and Greenland (GEUS) in collaboration with the National Institute of Aquatic Resources, Technical University of Denmark (DTU Aqua), for element abundance analysis in otoliths. Analyses of otoliths from Baltic Cod (Gadus morhua; Fig. 1) are used as an example for its application.
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来源期刊
Geus Bulletin
Geus Bulletin GEOLOGY-
CiteScore
2.80
自引率
17.60%
发文量
8
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