Alfalfa seeds biofortification with zinc for production of enriched sprouts

Journal of trace elements and minerals Pub Date : 2025-03-09 DOI:10.1016/j.jtemin.2025.100230

Marco Antonio Alves de Paula , Rafael Giovanini de Lima , Paulo Sérgio Monteiro , Fabrícia Queiroz Mendes , Hudson Wallace Pereira de Carvalho , Willian Rodrigues Macedo

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Abstract

Background

Hidden hunger is considered a dilemma, especially in developing countries. The scarcity of micronutrients causes severe health problems by weaking the population's immune system. Biofortified food can mitigate the harm of this problem by assisting specially less favored persons that cannot afford supplements.

Objective

This study aimed to evaluate the biofortification of alfalfa (Medicago sativa L.) seeds with zinc (Zn) through osmotic conditioning as a strategy to produce enriched sprouts that contribute to human mineral nutrition and adopt modern analytical tools to verify Zn absorption in seedlings.

Methods

Four rates of Zn were tested: 0 mmol l^-1, 0.005 mmol l^-1, 0.010 mmol l^-1, and 0.015 mmol l^-1 of Zn as ZnSO₄·7H₂O. Sprout mass (g), root length (cm) and shoot length (cm), germination rate (%), germination speed index, and Zn concentration in the sprouts were evaluated.

Results

No significant differences between treatments were observed for sprout mass and germination speed index. However, increases were noticed for root growth and germination rate at estimated doses of 0.0091 and 0.0099 mmol l^-1 of Zn, respectively. X-ray fluorescence analysis showed Zn concentrations as follows: 134, 176, 208, and 288 μg g^-1 for the 0, 0.005, 0.010, and 0.015 mmol l^-1 of Zn treatments, respectively. Biofortification proved a viable tool for plant shoot enrichment, with doses close to 0.010 mmol l^-1 of Zn resulting in superior plant development and adequate Zn accumulation in the sprouts.

Conclusion

Osmotic conditioning has proven to be a technological process capable of assisting in food biofortification, and X-ray fluorescence is an adequate analytical tool to measure mineral elements in plant-based food.

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用锌对苜蓿种子进行生物强化以生产富营养化芽苗菜

隐性饥饿被认为是一个难题，特别是在发展中国家。微量营养素的缺乏会削弱人们的免疫系统，从而导致严重的健康问题。生物强化食品可以通过帮助那些负担不起补充剂的弱势群体来减轻这个问题的危害。目的通过渗透调节对紫花苜蓿（Medicago sativa L.）种子进行锌（Zn）生物强化，以获得富含人体矿物质营养的芽苗菜，并利用现代分析工具验证幼苗对锌的吸收。方法测定ZnSO4·7H2O溶液中0 mmol l-1、0.005 mmol l-1、0.010 mmol l-1、0.015 mmol l-1 Zn的浓度。测定芽质量(g)、根长（cm）和芽长（cm）、发芽率（%）、发芽速度指数（萌发速率指数）和芽中锌浓度。结果不同处理间芽质量和发芽速度指数无显著差异。然而，在0.0091和0.0099 mmol l-1 Zn处理下，根系生长和发芽率均有显著提高。x射线荧光分析显示，在0、0.005、0.010和0.015 mmol -1 Zn处理下，锌浓度分别为134、176、208和288 μg -1。生物强化是植物芽部富集的一种有效手段，接近0.010 mmol l-1的锌浓度可使植株发育良好，芽部锌积累充足。结论渗透调节是一种有助于食品生物强化的技术，x射线荧光是测定植物性食品中矿物质元素的有效分析工具。

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

Journal of trace elements and minerals Medicine and Dentistry (General), Analytical Chemistry, Environmental Science (General), Toxicology, Biochemistry, Genetics and Molecular Biology (General), Nutrition, Veterinary Science and Veterinary Medicine (General)

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审稿时长

65 days