Importance of Elemental Chemical Speciation Studies in Enriched Food: Nutritional Quality, Toxicity, and Economic Improvement

IF 1.1 Q4 CHEMISTRY, ANALYTICAL
J. Naozuka
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The choice of the compound to be added, as well as the transport vehicle (foods), must be very well evaluated since the cost, long-term consumption, and bioavailability of the added chemical species are imperative to ensure the nutritional quality of enriched food.1 Another alternative to produce enriched foods is cultivating an enriched medium (Figure 1), adding essential elements to soil or in nutritive solution (hydroponic procedure), irrigating leaves, or immersing seeds.2 In this case, the chemical species used to the enrich food must be absorbed, translocated, and accumulated in the edible part.2 Studies have shown that the iron enrichment of adzuki beans using iron nitrate or iron chloride was unsuccessful since iron inorganic species interact strongly with the antinutrients (tannins or phytates) present in the roots, forming insoluble complexes and preventing their translocation.3 Alternatives found to overcome this obstacle were enrichment by applying iron complexes with EDTA (ethylenediaminetetra-acetic acid)3 or iron nanoparticles, mainly encapsulated.4 The nanoparticle application has been gaining prominence in agriculture, aiming to carry fertilizer, pesticides, and nutrients to stimulate plant growth and increase macro and micronutrient availability and absorption efficiency.5,6 Besides the interaction between essential elements with antinutrients, evaluating the competition between elemental species is important, because synergistic or antagonistic effects can be observed. In both cases, chemical species must interact with other components present in food or cultivation medium, altering its chemical composition when compared to food cultivated in conventional conditions. The antagonistic effect between selenium and mercury was observed in edible mushrooms, while the synergistic effect was observed with lead and selenium.7,8 Finally, it must be evaluated if the enrichment promotes the production of non-bioavailable or toxic species. Regardless of the food enrichment strategy, it is important to highlight the need to identify and quantify the elemental chemical species in the enriched foods by chemical speciation analysis. In the Figure 1 is shown examples of elemental chemical species; they can differ according to their oxidation states, inorganic forms, and organometallic or isotopic composition.9 For chemical speciation studies, initial fractionation steps (e.g., extraction procedures) are carried out; subsequently, chromatographic, or non-chromatographic methods can be used to identify/determine the chemical species. The hyphenation (Figure 1) between separation techniques, mainly chromatography, with high sensitivity detectors, such as inductively coupled plasma mass spectrometry (ICP-MS), is commonly applied.9-11 Nonetheless, extremely creative procedures used in non-chromatographic chemical speciation, working only with chemical reactions and solubility differences, can also be applied to determine chemical species. 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Abstract

For several reasons, mainly cost and local productivity, the world population does not have access to a balanced diet that contains all the macro and micronutrients necessary to maintain physiological functions for a healthy life. Nutritional education, supplementation, and consuming enriched (or fortified) foods appear as alternatives to supply daily demands and minimize malnutrition. Adding essential elements as salts (e.g., iron, calcium, and zinc) to ready-to-eat processed foods, such as milk, flour, and juices is already adopted in several countries. The choice of the compound to be added, as well as the transport vehicle (foods), must be very well evaluated since the cost, long-term consumption, and bioavailability of the added chemical species are imperative to ensure the nutritional quality of enriched food.1 Another alternative to produce enriched foods is cultivating an enriched medium (Figure 1), adding essential elements to soil or in nutritive solution (hydroponic procedure), irrigating leaves, or immersing seeds.2 In this case, the chemical species used to the enrich food must be absorbed, translocated, and accumulated in the edible part.2 Studies have shown that the iron enrichment of adzuki beans using iron nitrate or iron chloride was unsuccessful since iron inorganic species interact strongly with the antinutrients (tannins or phytates) present in the roots, forming insoluble complexes and preventing their translocation.3 Alternatives found to overcome this obstacle were enrichment by applying iron complexes with EDTA (ethylenediaminetetra-acetic acid)3 or iron nanoparticles, mainly encapsulated.4 The nanoparticle application has been gaining prominence in agriculture, aiming to carry fertilizer, pesticides, and nutrients to stimulate plant growth and increase macro and micronutrient availability and absorption efficiency.5,6 Besides the interaction between essential elements with antinutrients, evaluating the competition between elemental species is important, because synergistic or antagonistic effects can be observed. In both cases, chemical species must interact with other components present in food or cultivation medium, altering its chemical composition when compared to food cultivated in conventional conditions. The antagonistic effect between selenium and mercury was observed in edible mushrooms, while the synergistic effect was observed with lead and selenium.7,8 Finally, it must be evaluated if the enrichment promotes the production of non-bioavailable or toxic species. Regardless of the food enrichment strategy, it is important to highlight the need to identify and quantify the elemental chemical species in the enriched foods by chemical speciation analysis. In the Figure 1 is shown examples of elemental chemical species; they can differ according to their oxidation states, inorganic forms, and organometallic or isotopic composition.9 For chemical speciation studies, initial fractionation steps (e.g., extraction procedures) are carried out; subsequently, chromatographic, or non-chromatographic methods can be used to identify/determine the chemical species. The hyphenation (Figure 1) between separation techniques, mainly chromatography, with high sensitivity detectors, such as inductively coupled plasma mass spectrometry (ICP-MS), is commonly applied.9-11 Nonetheless, extremely creative procedures used in non-chromatographic chemical speciation, working only with chemical reactions and solubility differences, can also be applied to determine chemical species. Non-chromatographic strategies were applied for iron (reaction with hydroxylamine and precipitation with trichloroacetic acid and HCl) and selenium (cloud point extraction) speciation in enriched adzuki sprouts.3 In summary, food enrichment success is closely associated with chemical speciation studies since there are chemical species that will be absorbed in a cultivation medium, as well as the chemical species that are formed during translocation and accumulation, which must be in bioavailable forms, in order to act on the different metabolic systems of the human body, including remedying prevalences. In this scenario, it is imperative to go beyond determining the total concentration of essential elements, since quantifying their species will provide information regarding essentiality and toxicity. Finally, the formation of bioavailable chemical species will add nutritional quality and, consequently, economic benefits that are so essential for countries with specific prevalences to combat in a predominantly agricultural economy.
富集食品中元素化学特性研究的重要性:营养质量、毒性和经济效益的提高
由于多种原因(主要是成本和当地生产力),世界人口无法获得含有维持健康生活所需生理功能的所有宏观和微观营养素的均衡饮食。营养教育、补充和食用强化(或强化)食品似乎是满足日常需求和尽量减少营养不良的替代方法。在牛奶、面粉和果汁等即食加工食品中添加盐类必需元素(如铁、钙和锌)的做法已被多个国家采用。1 生产富集食品的另一种方法是培养富集介质(图 1),在土壤或营养液(水培程序)中添加必需元素,灌溉叶片或浸泡种子。2 研究表明,使用硝酸铁或氯化铁富集赤豆中的铁元素并不成功,因为无机铁元素与根部存在的抗营养素(单宁酸或植酸盐)相互作用强烈,形成不溶性复合物,阻碍其转运。4 纳米粒子的应用在农业领域日益突出,其目的是携带肥料、农药和养分,刺激植物生长,提高宏量和微量元素的可用性和吸收效率。除了基本元素与抗营养素之间的相互作用外,评估元素种类之间的竞争也很重要, 因为可以观察到协同或拮抗作用。在这两种情况下,化学元素必须与食物或培养基中的其他成分相互作用,改变其化学成分。在食用菌中观察到硒和汞的拮抗作用,而铅和硒的协同作用。无论采用哪种食品富集策略,都必须强调有必要通过化学标样分析来确定和量化富集 食品中的化学元素种类。图 1 举例说明了元素化学种类;它们可能因氧化态、无机形式、有机金属或同位素组成而异。9 在进行化学标样研究时,首先要进行分馏步骤(如提取程序);然后可采用色谱法或非色谱法来鉴定/确定化学种类。分离技术(主要是色谱法)与高灵敏度检测器(如电感耦合等离子体质谱法 (ICP-MS))之间的联用(图 1)是常用的分离技术。在富集赤豆芽中铁(与羟胺反应,用三氯乙酸和盐酸沉淀)和硒(浊点萃取)的种类测定中,就采用了非色谱法策略。总之,食物富集的成功与否与化学物质的种类研究密切相关,因为有些化学物质会在栽培介质中被吸收,有些化学物质会在转运和积累过程中形成,而这些化学物质必须以生物可利用的形式存在,才能对人体的不同代谢系统发挥作用,包括补救流行病。在这种情况下,除了确定必需元素的总浓度外,还必须对其种类进行量化,以提供有关必需性和毒性的信息。最后,生物可利用化学物质的形成将提高营养质量,进而提高经济效益,这对于在以农业为主的经济中应对特定流行病的国家来说至关重要。
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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来源期刊
CiteScore
1.60
自引率
14.30%
发文量
46
期刊介绍: BrJAC is dedicated to the diffusion of significant and original knowledge in all branches of Analytical Chemistry, and is addressed to professionals involved in science, technology and innovation projects at universities, research centers and in industry.
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