glyceric

简明释义

英[ɡlɪˈserɪk]美[ɡlɪˈserɪk]

adj. 甘油的

英英释义

单词用法

同义词

反义词

例句

1.The prefix “glyc,” is used in a generic sense to designate sugars and their derivatives; e.g., glycoses, glycosides, glycosans, glyconic glyceric, and glycuronic acids.

前缀“glyc”（甘、糖）在一般意义上用来表示糖及其衍生物。 例如：glycoses（单糖）、glycosides（糖苷）、glycosans（聚糖）、glyconicacids (糖酸) 、glyconic acids（甘油酸）、glycuronic acids（糖醛酸）。

2.The prefix “glyc,” is used in a generic sense to designate sugars and their derivatives; e.g., glycoses, glycosides, glycosans, glyconic glyceric, and glycuronic acids.

前缀“glyc”（甘、糖）在一般意义上用来表示糖及其衍生物。 例如：glycoses（单糖）、glycosides（糖苷）、glycosans（聚糖）、glyconicacids (糖酸) 、glyconic acids（甘油酸）、glycuronic acids（糖醛酸）。

3.He wants glyceric acids.

他想要甘油酸。

4.The researcher studied the effects of glyceric 甘油的 acid on cellular metabolism.

研究人员研究了甘油的酸对细胞代谢的影响。

5.In cosmetic formulations, glyceric 甘油的 compounds are often used for their moisturizing properties.

在化妆品配方中，常使用甘油的化合物来增加保湿效果。

6.The production of glyceric 甘油的 acid can be achieved through various biochemical processes.

可以通过多种生化过程生产甘油的酸。

7.During the fermentation process, glyceric 甘油的 byproducts can influence the flavor of the final product.

在发酵过程中，甘油的副产品会影响最终产品的风味。

8.The glyceric 甘油的 pathway is crucial for energy production in certain microorganisms.

在某些微生物中，甘油的途径对能量生产至关重要。

作文

In the realm of biochemistry, various compounds play crucial roles in the metabolic processes that sustain life. One such compound is glyceric acid, which is often referred to as glyceric acid. This organic compound is a product of the metabolism of carbohydrates and fats and is essential for several biochemical pathways. Understanding glyceric acid not only helps us appreciate the complexity of biological systems but also sheds light on potential applications in medicine and nutrition. Glyceric acid, or glyceric acid, has the chemical formula C3H6O3. It is a colorless, viscous liquid that is soluble in water. This compound is a three-carbon molecule that contains both hydroxyl (-OH) groups and a carboxylic acid (-COOH) group. The presence of these functional groups allows glyceric acid to participate in a variety of chemical reactions, making it a versatile building block in organic chemistry. One of the significant roles of glyceric acid in human metabolism is its involvement in the glycolytic pathway. During glycolysis, glucose is broken down to produce energy, and glyceric acid can be formed as an intermediate. This process is vital for generating adenosine triphosphate (ATP), the energy currency of cells. Without glyceric acid and its derivatives, our bodies would struggle to produce the energy required for daily functions. Moreover, glyceric acid is also a precursor in the synthesis of other important biomolecules. For instance, it can be converted into glycerol, which is a crucial component of triglycerides and phospholipids. These lipids are fundamental for maintaining cellular structures and providing energy reserves. The conversion of glyceric acid into glycerol highlights its importance in lipid metabolism and storage, further emphasizing its role in overall health. In addition to its metabolic functions, glyceric acid has potential therapeutic applications. Research has shown that glyceric acid may have antioxidant properties, which can help protect cells from oxidative stress. Oxidative stress is linked to various diseases, including cancer, cardiovascular diseases, and neurodegenerative disorders. By understanding the mechanisms through which glyceric acid exerts its effects, scientists aim to develop new strategies for disease prevention and treatment. Furthermore, glyceric acid could play a role in sports nutrition. Athletes often seek ways to enhance their performance and recovery, and compounds like glyceric acid may contribute to improved endurance and reduced muscle soreness. Some studies suggest that supplementation with glyceric acid could help maintain hydration and electrolyte balance during intense physical activity, leading to better overall performance. In conclusion, the compound glyceric acid is a fascinating example of how a simple organic molecule can have profound implications for biology and health. From its critical role in energy metabolism to its potential therapeutic benefits, glyceric acid exemplifies the interconnectedness of biochemical processes. As research continues to unveil the mysteries of this compound, we may discover even more ways to harness its properties for the betterment of human health and performance. Understanding glyceric acid is not just an academic pursuit; it holds the key to unlocking new avenues in nutrition and medicine.

在生物化学领域，各种化合物在维持生命的代谢过程中发挥着至关重要的作用。其中一种化合物是甘油酸，通常被称为甘油酸。这种有机化合物是碳水化合物和脂肪代谢的产物，对于几条生化途径至关重要。理解甘油酸不仅有助于我们欣赏生物系统的复杂性，还揭示了其在医学和营养学中的潜在应用。 甘油酸或甘油酸的化学式为C3H6O3。它是一种无色、粘稠的液体，易溶于水。这种化合物是一个三碳分子，含有羟基（-OH）和羧酸（-COOH）基团。这些官能团的存在使得甘油酸能够参与多种化学反应，使其成为有机化学中一种多用途的构件。 甘油酸在人类代谢中的重要角色之一是参与糖酵解途径。在糖酵解过程中，葡萄糖被分解以产生能量，而甘油酸可以作为中间产物形成。这个过程对于生成三磷酸腺苷（ATP）至关重要，ATP是细胞的能量货币。没有甘油酸及其衍生物，我们的身体将难以产生日常功能所需的能量。 此外，甘油酸也是合成其他重要生物分子的前体。例如，它可以转化为甘油，甘油是甘油三酯和磷脂的重要组成部分。这些脂质对于维持细胞结构和提供能量储备至关重要。甘油酸转化为甘油的过程突显了其在脂质代谢和储存中的重要性，进一步强调了其在整体健康中的作用。 除了其代谢功能外，甘油酸还具有潜在的治疗应用。研究表明，甘油酸可能具有抗氧化特性，有助于保护细胞免受氧化压力的影响。氧化压力与多种疾病相关，包括癌症、心血管疾病和神经退行性疾病。通过理解甘油酸施加其效应的机制，科学家旨在开发新的疾病预防和治疗策略。 此外，甘油酸可能在运动营养中发挥作用。运动员常常寻求增强表现和恢复的方法，而像甘油酸这样的化合物可能有助于改善耐力和减少肌肉酸痛。一些研究表明，补充甘油酸可能有助于在剧烈身体活动期间保持水分和电解质平衡，从而提高整体表现。 总之，化合物甘油酸是一个迷人的例子，展示了简单有机分子如何对生物学和健康产生深远影响。从其在能量代谢中的关键角色到其潜在的治疗益处，甘油酸体现了生化过程的相互联系。随着研究的不断深入，我们可能会发现更多利用其特性的方式，以改善人类健康和表现。理解甘油酸不仅仅是一项学术追求；它掌握着开启营养和医学新领域的钥匙。