indoxyl

简明释义

英[ɪnˈdɒksɪl]美[ɪnˈdɑːksɪl]

n. 吲哚酚，羟基吲哚；吲羟

英英释义

单词用法

同义词

反义词

例句

1.Indoxyl causes appendicitis, typhoid fever and other enteric fevers and answers 90% of the questions asked by people who seek to improve their health.

吲哚酚能引起阑尾炎，伤寒和其他肠性发烧，并且能回答90%人们寻求改善他们健康的问题。

2.Indoxyl causes appendicitis, typhoid fever and other enteric fevers and answers 90% of the questions asked by people who seek to improve their health.

吲哚酚能引起阑尾炎，伤寒和其他肠性发烧，并且能回答90%人们寻求改善他们健康的问题。

3.Oxindole, 3 methyloxindole, and indoxyl were identified as degradation metabolites of indole, 3 methylindole, and 3 indolyl acetate, respectively.

氧化吲哚，3 甲基氧化吲哚和羰基吲哚分别为吲哚、3 甲基吲哚和3 吲哚醋酸酯的代谢产物。

4.Do these people test their urine for indoxyl?

这些人测试他们的尿中的吲哚酚吗？

5.The compound indoxyl is often studied for its role in the metabolism of tryptophan.

化合物indoxyl常被研究其在色氨酸代谢中的作用。

6.Researchers found that indoxyl can be converted into indigo, a natural dye.

研究人员发现indoxyl可以转化为靛蓝，这是一种天然染料。

7.The presence of indoxyl in urine can indicate certain metabolic disorders.

尿液中存在indoxyl可能表明某些代谢紊乱。

8.In the lab, we synthesized indoxyl to explore its potential pharmaceutical applications.

在实验室中，我们合成了indoxyl以探索其潜在的药用应用。

9.The reaction involving indoxyl and oxygen produces a fluorescent compound.

涉及indoxyl和氧气的反应产生一种荧光化合物。

作文

Indoxyl is a compound that plays a significant role in various biochemical processes. It is primarily known for its association with the metabolism of tryptophan, an essential amino acid found in many protein-rich foods. When tryptophan is metabolized in the body, it can be converted into several different compounds, one of which is indole. Indole can further be transformed into indoxyl, which is then involved in the production of other important molecules. Understanding the biochemical pathways involving indoxyl is crucial for researchers studying metabolic disorders and the overall functioning of the human body. In the context of human health, indoxyl has garnered attention due to its potential implications in kidney function. Studies have shown that elevated levels of indoxyl in the bloodstream can be indicative of impaired kidney function. This is because the kidneys are responsible for filtering out waste products, including indoxyl. When the kidneys are not functioning properly, the levels of this compound can rise, leading to various health complications. Moreover, indoxyl is also recognized for its role in the gut microbiome. The gut microbiota, which consists of trillions of microorganisms living in our intestines, can influence the metabolism of dietary substances. Certain bacteria in the gut can convert tryptophan into indoxyl, highlighting the interplay between diet, gut health, and metabolic processes. Researchers are increasingly interested in how manipulating gut bacteria could potentially regulate the levels of indoxyl and other metabolites, thereby influencing health outcomes. In addition to its biological significance, indoxyl has applications in various scientific fields. For instance, it can be used as a biomarker in clinical studies to assess kidney function or monitor metabolic diseases. Furthermore, understanding the properties of indoxyl can aid in the development of new therapeutic strategies aimed at managing conditions related to metabolic dysfunction. The study of indoxyl and its effects is still an evolving field, with ongoing research exploring its various roles in health and disease. As scientists continue to uncover the complexities of metabolic pathways, the importance of compounds like indoxyl will undoubtedly become clearer. By delving deeper into the functions and implications of indoxyl, we can enhance our understanding of human biology and improve health outcomes through targeted interventions. In conclusion, indoxyl is more than just a chemical compound; it is a vital player in the intricate web of metabolic processes that sustain life. Its connections to kidney function, gut health, and potential therapeutic applications highlight the importance of studying such compounds in the quest for better health. As research progresses, the insights gained from examining indoxyl will contribute to our overall knowledge of biochemistry and its impact on human health.

吲哚醇是一种在多种生化过程中发挥重要作用的化合物。它主要因与色氨酸的代谢相关而闻名，色氨酸是一种在许多富含蛋白质的食物中发现的必需氨基酸。当色氨酸在体内被代谢时，可以转化为几种不同的化合物，其中之一是吲哚。吲哚可以进一步转化为吲哚醇，然后参与其他重要分子的生成。理解涉及吲哚醇的生化途径对于研究代谢紊乱和人体整体功能的研究者至关重要。 在人体健康的背景下，吲哚醇因其对肾功能的潜在影响而引起了关注。研究表明，血液中吲哚醇水平升高可能表明肾功能受损。这是因为肾脏负责过滤废物，包括吲哚醇。当肾脏功能不正常时，这种化合物的水平可能会上升，从而导致各种健康并发症。 此外，吲哚醇还因其在肠道微生物组中的作用而受到认可。肠道微生物群由生活在我们肠道中的数万亿微生物组成，可以影响饮食物质的代谢。肠道中的某些细菌可以将色氨酸转化为吲哚醇，突显了饮食、肠道健康与代谢过程之间的相互作用。研究人员越来越感兴趣于如何操控肠道细菌，以潜在地调节吲哚醇和其他代谢物的水平，从而影响健康结果。 除了生物学意义外，吲哚醇在多个科学领域也有应用。例如，它可以作为临床研究中的生物标志物，用于评估肾功能或监测代谢疾病。此外，理解吲哚醇的性质可以帮助开发新的治疗策略，旨在管理与代谢功能障碍相关的条件。 对吲哚醇及其影响的研究仍然是一个不断发展的领域，正在进行的研究探索其在健康和疾病中的各种角色。随着科学家们继续揭示代谢途径的复杂性，像吲哚醇这样的化合物的重要性无疑会变得更加清晰。通过深入研究吲哚醇的功能和影响，我们可以增强对人类生物学的理解，并通过针对性的干预改善健康结果。 总之，吲哚醇不仅仅是一种化学化合物；它是维持生命的复杂代谢过程中的关键参与者。它与肾功能、肠道健康以及潜在治疗应用的联系突显了在追求更好健康的过程中研究此类化合物的重要性。随着研究的进展，从研究吲哚醇中获得的见解将有助于我们对生物化学及其对人类健康影响的整体认识。