A green procedure for the determination of bioavailable forms of aluminum in natural waters by electrothermal atomic absorption spectroscopy combined with microextraction technique.

IF 3.2 3区环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL

Environmental Geochemistry and Health Pub Date : 2024-09-24 DOI:10.1007/s10653-024-02230-w

Ruslan Mariychuk, Sergii Sukharev, Oksana Sukhareva, Liudmyla Roman, Tetiana Babilia

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Abstract

Aluminum is a prevalent element in nature, but bioavailable forms of aluminum are toxic to plants, animals, and humans. The present study is dedicated to the development of an ecologically friendly, fast, simple, reliable, sensitive, and accurate improved procedure for the determination of subtrace concentrations of bioavailable forms of aluminum in natural waters. The procedure includes the separation and pre-concentration of bioavailable forms of aluminum using vortex-assisted liquid-liquid microextraction (VALLME) of ionic associates with salicylaldehyde 4-picolinhydrazone (SAPH) and sodium dodecyl sulfate (DDSNa) by isoamylacetate (200 μl) and direct electrothermal atomic absorption spectroscopy (ET AAS). The SAPH reagent interacts only with water-soluble forms of aluminum. SAPH is used for the pre-concentration of bioavailable forms of aluminum as well as a chemical modifier; it increases the absorbance and the precision of the analytical signal of aluminum. The calibration curve shows the linear dependence in the range of 0.05-86 μg⋅L^-1 of the aluminum concentration (R² = 0.992), with the limit of detection at 0.015 μg⋅L^-1 and the limit of quantification at 0.05 μg⋅L^-1. The accuracy of the proposed procedure for bioavailable forms of aluminum determination was verified on model solutions and against a reference method on natural samples of river and lake waters (RSD 3.2-5.2%, recovery 97.1-103.4%).

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利用电热原子吸收光谱法结合微萃取技术测定天然水体中生物可利用形式铝的绿色程序。

铝是自然界中普遍存在的元素，但生物可利用形式的铝对植物、动物和人类具有毒性。本研究致力于开发一种生态友好、快速、简单、可靠、灵敏和准确的改进程序，用于测定天然水体中生物可利用形式铝的亚痕量浓度。该程序包括利用涡流辅助液液微萃取（VALLME）技术，通过异戊基乙酸乙酯（200 μl）和直接电热原子吸收光谱（ET AAS），分离和预浓缩与水杨醛-4-匹克林腙（SAPH）和十二烷基硫酸钠（DDSNa）离子联营体的生物可利用形式的铝。SAPH 试剂只与水溶性铝发生作用。SAPH 用于预浓缩生物可利用形式的铝，同时也是一种化学改性剂；它能提高铝的吸光度和分析信号的精度。校准曲线显示，铝浓度在 0.05-86 μg⋅L-1 范围内呈线性关系（R2 = 0.992），检出限为 0.015 μg⋅L-1，定量限为 0.05 μg⋅L-1。在模型溶液上以及在河水和湖水的天然样本上与参考方法对比，验证了所建议的生物可利用型铝测定程序的准确性（RSD 为 3.2-5.2%，回收率为 97.1-103.4%）。

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来源期刊

Environmental Geochemistry and Health 环境科学-工程：环境

CiteScore

8.00

自引率

4.80%

发文量

279

审稿时长

4.2 months

期刊介绍： Environmental Geochemistry and Health publishes original research papers and review papers across the broad field of environmental geochemistry. Environmental geochemistry and health establishes and explains links between the natural or disturbed chemical composition of the earth’s surface and the health of plants, animals and people. Beneficial elements regulate or promote enzymatic and hormonal activity whereas other elements may be toxic. Bedrock geochemistry controls the composition of soil and hence that of water and vegetation. Environmental issues, such as pollution, arising from the extraction and use of mineral resources, are discussed. The effects of contaminants introduced into the earth’s geochemical systems are examined. Geochemical surveys of soil, water and plants show how major and trace elements are distributed geographically. Associated epidemiological studies reveal the possibility of causal links between the natural or disturbed geochemical environment and disease. Experimental research illuminates the nature or consequences of natural or disturbed geochemical processes. The journal particularly welcomes novel research linking environmental geochemistry and health issues on such topics as: heavy metals (including mercury), persistent organic pollutants (POPs), and mixed chemicals emitted through human activities, such as uncontrolled recycling of electronic-waste; waste recycling; surface-atmospheric interaction processes (natural and anthropogenic emissions, vertical transport, deposition, and physical-chemical interaction) of gases and aerosols; phytoremediation/restoration of contaminated sites; food contamination and safety; environmental effects of medicines; effects and toxicity of mixed pollutants; speciation of heavy metals/metalloids; effects of mining; disturbed geochemistry from human behavior, natural or man-made hazards; particle and nanoparticle toxicology; risk and the vulnerability of populations, etc.