Transfer of lead through different trophic levels: Microalgae (Nannochloropsis oculata), rotifer (Brachionus plicatilis), and prawn (Macrobrachium rosenbergii)

Pub Date : 2023-09-07 DOI:10.20937/rica.54233
Nayeli Carmen Benítez-Fernández, I. A. Pérez-Legaspi, I. Rubio-Franchini
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Abstract

Aquatic ecosystems suffer alterations by the input of several pollutants as potentially toxic elements which interact with the planktonic community with likelihood of bioconcentration, bioaccumulation, and biomagnification through the trophic chains despite the fact of being in low concentrations. The goal of this study involves assessing the toxicity, bioaccumulation, and transfer of the lead under controlled laboratory conditions by estimating the bioconcentration factor (BCF) and bioaccumulation factor (BAF) in organisms usually used in aquaculture, as Nannochloropsis oculata microalgae, Brachionus plicatilis rotifer, and the Malaysian prawn Macrobrachium rosenbergii. We assessed toxicity, bioconcentration, and transfer of the lead from the microalgae to higher trophic levels, the rotifer, and the prawn larvae. We performed three bioassays: (1) lead-exposed microalgae, (2) rotifer fed with lead-exposed microalgae, and (3) prawn larvae fed with either lead-exposed microalgae or rotifers fed with these microalgae. The toxicity endpoints were obtained for microalgae. The concentration of the lead in all organisms was analyzed by atomic absorption spectrophotometry for estimating BCF and BAF values. The endpoints No Observed Effect Concentration (NOEC) and Effective Concentration 50 (EC50) are 1 and 5.42 mg/L, respectively, for N. oculata. The BCF in the microalgae decreases as lead concentration increases. A BAF of 2948 in rotifers, and a BAF of 42.1 in prawns were obtained. In conclusion, lead can concentrate in microalgae, transfer, and accumulate through consumption toward the consecutive trophic levels, but not among invertebrates due to their detoxification mechanisms.
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通过不同营养水平的铅转移:微藻(眼无氯虫)、轮虫(褶皱臂尾虫)和对虾(罗氏沼虾)
水生生态系统因几种污染物的输入而遭受改变,这些污染物作为潜在的有毒元素与浮游生物群落相互作用,尽管其浓度很低,但仍可能通过营养链进行生物浓缩、生物积累和生物放大。本研究的目的是通过估算水产养殖中常用的生物,如微藻纳米绿藻、轮虫臂尾轮虫和马来西亚罗氏沼虾的生物浓缩因子(BCF)和生物积累因子(BAF),在受控的实验室条件下评估铅的毒性、生物积累和转移。我们评估了毒性、生物浓度和铅从微藻到更高营养水平、轮虫和对虾幼虫的转移。我们进行了三种生物测定:(1)铅暴露微藻,(2)喂食铅暴露微藻的轮虫,以及(3)喂食铅暴露微藻或喂食这些微藻的轮虫的对虾幼虫。得到了微藻的毒性终点。采用原子吸收分光光度法测定铅在所有生物体中的浓度,以估计BCF和BAF值。无观察效应浓度(NOEC)和有效浓度50 (EC50)分别为1和5.42 mg/L。微藻中的BCF随铅浓度的增加而降低。轮虫的BAF为2948,对虾的BAF为42.1。综上所述,铅可以在微藻中集中,通过向连续营养水平的消耗而转移和积累,但由于无脊椎动物的解毒机制,铅不会在无脊椎动物中积累。
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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