Elemental speciation analysis, from environmental to biochemical challenge

P. Jitaru, C. Barbante
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引用次数: 1

Abstract

Information regarding the distribution of metallic/metalloid chemical species in biological compartments is required for understanding their biochemical impact on living organisms. To obtain such information implies the use of a dedicated measurement approach, namely speciation analysis. The current trend in (elemental) speciation analysis regards bioinorganic applications. New analytical methodologies are therefore necessary for identification, detection and characterization of metal(loids) complexed or incorporated into biomolecules. The established element-speciation approaches developed for the determination of low molecular mass metal(loid) species (e.g. organometallic compounds) in environmental, food, toxicological and health sciences are presently being adapted for the determination of high molecular mass metal-species, generally related to biological processes. This is one of the newest approaches in terms of element speciation and is called metallomics; this concept refers to the totality of metal species in a cell and covers the inorganic element content and the ensemble of its complexes with biomolecules, particularly proteins, participating in the organisms' response to beneficial or harmful conditions. Compared to conventional elemental speciation analysis, the approach applied to bioinorganic analysis is challenging, particularly given the difficulties in identification/characterization of the organic (e.g. protein) content of such species. In addition, quantification is not feasible with the conventional approaches, which led to the exploitation of the unique feature of (post-column) online isotope dilution-mass spectrometry for species quantification in metallomics.
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元素物种形成分析,从环境到生化挑战
关于金属/类金属化学物种在生物隔间中的分布的信息是了解它们对生物体的生化影响所必需的。要获得这样的信息,就需要使用一种专门的测量方法,即物种形成分析。目前(元素)形态分析的趋势是生物无机的应用。因此,需要新的分析方法来鉴定、检测和表征络合或纳入生物分子的金属(液体)。环境、食品、毒理学和健康科学中为确定低分子质量金属(如有机金属化合物)而制定的已确立的元素物种形成方法,目前正被用于确定通常与生物过程有关的高分子质量金属物种。这是元素形态形成的最新方法之一,被称为金属组学;这个概念是指细胞中金属种类的总和,包括无机元素含量及其与生物分子(特别是蛋白质)的复合物的集合,这些生物分子参与生物体对有益或有害条件的反应。与传统的元素物种形成分析相比,应用于生物无机分析的方法具有挑战性,特别是考虑到识别/表征这些物种的有机(例如蛋白质)含量的困难。此外,由于传统方法无法进行定量,因此利用(柱后)在线同位素稀释-质谱法进行金属组学中的物种定量。
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