thiazole

简明释义

英[ˈθaɪəˌzəʊl]美[ˈθaɪəˌzoʊl]

n. 噻唑

英英释义

单词用法

同义词

反义词

例句

1.Root exudation of wheat, corn, broad bean and pigeon pea mainly include organic acid, phenol, hydrocarbon, grease, ketone, mellow, amide, benzene, aldehyde and thiazole et al.

小麦、玉米、蚕豆和鹰咀豆根分泌的主要类型有有机酸、酚、烃、脂、酮、酰胺、醇、苯、醛和噻唑。

2.At the same time, many newly developed compounds containing imidazole ring or thiazole ring also have bioactivity.

同时，含有咪唑环或噻唑环的新研制的众多化合物也具有生物活性。

3.Root exudation of wheat, corn, broad bean and pigeon pea mainly include organic acid, phenol, hydrocarbon, grease, ketone, mellow, amide, benzene, aldehyde and thiazole et al.

小麦、玉米、蚕豆和鹰咀豆根分泌的主要类型有有机酸、酚、烃、脂、酮、酰胺、醇、苯、醛和噻唑。

4.The reactions of thiazole ethiodide with aromatic aldehydes in the presence of pipcridine as catalyst were investigated. It is found that the reaction is of second order.

研究在碱性催化剂存在下，噻唑碘乙烷盐与芳香醛的反应动力学，实验结果表明此类反应符合二级反应。

5.Due to being short of time, the in vitro antibacterial activity assay of thiazole containing compounds is under doing.

由于时间原因，含噻唑环的化合物虽然已经合成完毕，相应的体外抑菌试验正在进行中。

6.Therefore, it can be concluded that both imidazole ring and thiazole ring have bioactivity.

因而我们可以确信咪唑环和噻唑环是具有生物活性的。

7.A rapid micromethod for the determination of nitrogen in organic compounds, such as pyridine, pyrimidine, purine, thiazole, alkaloids and amino acids, is described.

本文提出嘌呤、嘧啶、呲啶、噻唑、生物碱和氨基酸等类有机化合物中氮的快速微量测定法。

8.A kind of morpholine derivative was synthesized by morpholine, trioxane and dibutylamines, and a thiazole derivative was synthesized by morpholine, ammonia and sulfur.

以吗啉、三聚甲醛、二正丁胺为原料合成了一种吗啉衍生物，以异丁醛、氨水和硫为原料合成了一种噻唑衍生物。

9.The synthesis of thiazole 噻唑 compounds often involves a reaction between a thioketone and an aldehyde.

thiazole 噻唑 化合物的合成通常涉及硫酮和醛之间的反应。

10.Researchers are exploring the potential of thiazole 噻唑 derivatives in developing new antibiotics.

研究人员正在探索thiazole 噻唑 衍生物在开发新抗生素方面的潜力。

11.The presence of a thiazole 噻唑 ring can enhance the lipophilicity of pharmaceutical compounds.

一个thiazole 噻唑 环的存在可以增强药物化合物的亲脂性。

12.In agricultural chemistry, thiazole 噻唑 fungicides are used to protect crops from fungal infections.

在农业化学中，thiazole 噻唑 杀真菌剂用于保护作物免受真菌感染。

13.The compound contains a ring structure that includes a thiazole 噻唑 moiety, which is crucial for its biological activity.

该化合物包含一个环状结构，其中含有一个thiazole 噻唑 基团，这对其生物活性至关重要。

作文

Thiazole is a five-membered heterocyclic compound containing both sulfur and nitrogen atoms. This unique structure makes thiazole (噻唑) an essential building block in various chemical syntheses and pharmaceutical applications. The significance of thiazole cannot be overstated, as it plays a crucial role in the development of numerous bioactive compounds. In recent years, research has shown that thiazole derivatives exhibit a wide range of biological activities, including antimicrobial, antifungal, and anticancer properties.The versatility of thiazole can be attributed to its ability to form stable complexes with metal ions, which enhances its reactivity and biological efficacy. For example, many drugs that contain thiazole have been developed to target specific diseases, showcasing the compound's importance in medicinal chemistry. One notable example is the antibiotic class known as thiazole antibiotics, which are effective against various bacterial infections.In addition to its medicinal uses, thiazole also finds applications in agricultural chemistry. Certain thiazole derivatives are utilized as fungicides and herbicides, helping to protect crops from pests and diseases. This aspect of thiazole highlights its role not only in human health but also in food security and sustainable agriculture.The synthesis of thiazole and its derivatives is a significant area of research in organic chemistry. Various methods for synthesizing thiazole have been developed, including cyclization reactions involving thiourea and α-halo ketones. These synthetic routes allow chemists to create a wide array of thiazole compounds tailored for specific applications.Furthermore, the study of thiazole is not limited to its chemical properties; it also extends to its role in biological systems. Research has indicated that thiazole can influence various metabolic pathways, making it a compound of interest in biochemistry. Understanding how thiazole interacts with biological molecules can lead to the discovery of new therapeutic targets and strategies.In conclusion, thiazole (噻唑) is a remarkable compound with diverse applications in medicine, agriculture, and chemistry. Its unique structure and properties make it a valuable tool for scientists aiming to develop innovative solutions to pressing health and environmental challenges. As research continues to unveil the potential of thiazole, it is likely that we will see even more exciting developments in the coming years, further solidifying its place as a key player in the fields of chemistry and pharmacology.