Implications and Practical Applications of the Chemical Speciation of Iodine in the Biological Context

A. Espino-Vázquez, Flor C. Rojas-Castro, L. M. Fajardo-Yamamoto
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引用次数: 2

Abstract

Iodine is a highly reactive element with a single natural and stable isotopic form (127I). In the biosphere, it is one of the 30 essential elements for life, and its chemical speciation defines its availability and biological activities. The most relevant chemical species are iodate (IO3−) and iodide (I−) as the major sources of iodine, with molecular iodine (I2) and hypoiodous acid (HIO) as the most reactive species, and thyroid hormones (THs) as the representative organic compounds. In human biology, THs are master regulators of metabolism, while inorganic species serve for the iodination of organic molecules and contribute to the innate immune system and the antioxidant cellular defense. Additionally, I−, I2, δ-lactone (6-IL), and α-iodohexadecanal (α-IHDA) have shown therapeutic potential in counteracting oxidative stress, cancer, and inflammation. Both inorganic and organic species have applications in the health science industry, from the manufacturing of disinfection and wound care products to supplements, medicines, and contrast media for radiography. Even after nuclear disasters, intake of high doses of iodine prevents the accumulation of radioactive iodine in the body. Conversely, the controlled production of iodine radioisotopes such as 123I, 124I, 125I, and 131I is exploited in nuclear medicine for radiotherapy and diagnostics.
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碘的化学形态在生物环境中的意义和实际应用
碘是一种高活性元素,具有单一的自然稳定同位素形式(127I)。在生物圈中,它是生命的30种基本元素之一,它的化学形态决定了它的可利用性和生物活性。与碘最相关的化学物质是碘酸盐(IO3−)和碘化物(I−),它们是碘的主要来源,其中分子碘(I2)和次碘酸(HIO)是反应最活跃的物质,甲状腺激素(THs)是有机化合物的代表。在人类生物学中,三萜类化合物是代谢的主要调节因子,而无机物种则是有机分子的碘化,参与先天免疫系统和抗氧化细胞防御。此外,I−、I2、δ-内酯(6-IL)和α-碘十六烷(α-IHDA)已显示出对抗氧化应激、癌症和炎症的治疗潜力。无机和有机物种在健康科学产业中都有应用,从消毒和伤口护理产品的制造到补充剂、药物和放射照相造影剂。即使在核灾难发生后,摄入高剂量的碘也可以防止放射性碘在体内的积累。相反,碘放射性同位素如123I、124I、125I和131I的受控生产在核医学中用于放射治疗和诊断。
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