benzimidazole

简明释义

英[ˌbenzɪˈmaɪdəˌzəʊl]美[ˌbenzəmɪˈdæzˌol;ˌbenzəmˈmɪdə

n. [有化] 苯并咪唑

英英释义

单词用法

同义词

反义词

例句

1.Aim to design and synthesize the novel aniline-type derivatives of benzimidazole, and to assay their activities of inhibiting secretion of gastric juice and gastric acids.

目的设计合成新型苯胺类苯并咪唑衍生物，并评价其对大白鼠胃液分泌和胃酸分泌的作用。

2.The present invention consists of ulcer activeness resisting benzimidazole compound and water soluble amide medicinal composite.

本发明包括含有具有抗溃疡活性的苯并咪唑化合物和水溶性酰胺的药用组合物。

3.The present invention belongs to the field of medicine preparation, in the concrete, it relates to a composition of substituted benzimidazole proton pump inhibitor and its preparation method.

本发明涉及药物制剂领域，具体涉及含取代苯并咪唑质子泵抑制剂的组合物及其制备方法。

4.New benzimidazole molecules with excellent corrosion inhibition properties were designed by 3d-qsar contour maps.

通过3d - QSAR等势图设计出了几种具有较好缓蚀性能的苯并咪唑化合物。

5.And a super high contrast was obtained when 6 nitro benzimidazole and thiosalicylic acid were used together.

而硫代水杨酸与6硝基苯并咪唑配合使用时，得到了超高反差效果。

6.The invention provides an organic luminescent material, i. e. a terphenyl bridged-bis-benzimidazole quaternary ammonium compound, a preparation method and application thereof.

本发明提供一种三联苯桥联双苯并咪唑季铵盐类化合物有机发光材料、制备方法及应用。

7.The drug contains a benzimidazole structure that enhances its efficacy.

该药物含有苯并咪唑结构，增强了其疗效。

8.The compound benzimidazole is widely used in the synthesis of various pharmaceuticals.

化合物苯并咪唑广泛用于各种药物的合成。

9.Researchers discovered that benzimidazole derivatives have antifungal properties.

研究人员发现苯并咪唑衍生物具有抗真菌特性。

10.Studies show that benzimidazole can inhibit certain types of cancer cell growth.

研究表明苯并咪唑可以抑制某些类型癌细胞的生长。

11.In the laboratory, we tested the reactivity of benzimidazole with different reagents.

在实验室中，我们测试了苯并咪唑与不同试剂的反应性。

作文

Benzimidazole is an important organic compound that plays a crucial role in various fields, particularly in pharmaceuticals and agriculture. This heterocyclic compound consists of a fused benzene and imidazole ring, which gives it unique chemical properties. The significance of benzimidazole (苯并咪唑) lies not only in its structure but also in its diverse applications. In the pharmaceutical industry, benzimidazole (苯并咪唑) derivatives are widely used as effective drugs. One of the most notable examples is the drug Albendazole, which is used to treat parasitic infections. Albendazole works by inhibiting the polymerization of tubulin, a protein essential for cell division in parasites. This mechanism of action highlights how benzimidazole (苯并咪唑) compounds can target specific biological pathways, making them valuable in treating diseases caused by parasites. Moreover, other benzimidazole (苯并咪唑) derivatives have been developed for their antiviral and anticancer properties. For instance, some studies have shown that certain benzimidazole (苯并咪唑) compounds exhibit activity against various strains of viruses, including those responsible for influenza and HIV. The ongoing research into these compounds indicates their potential as a basis for new antiviral therapies. In addition to their pharmaceutical applications, benzimidazole (苯并咪唑) compounds are also utilized in agriculture. They are commonly found in fungicides, helping to protect crops from fungal infections. The effectiveness of benzimidazole (苯并咪唑) fungicides stems from their ability to disrupt the fungal cell division process, ultimately leading to the death of the fungus. This application is particularly important in ensuring food security and managing agricultural pests. The environmental impact of benzimidazole (苯并咪唑) derivatives is another area of interest. While these compounds are effective in controlling pests and diseases, their persistence in the environment raises concerns about ecological safety. Research is ongoing to develop benzimidazole (苯并咪唑) compounds that are both effective and environmentally friendly, emphasizing the need for sustainable practices in agriculture. Furthermore, the study of benzimidazole (苯并咪唑) has led to advancements in material science. Certain benzimidazole (苯并咪唑) derivatives are being explored for their potential use in organic electronics, such as organic light-emitting diodes (OLEDs) and organic photovoltaics. The unique electronic properties of these compounds make them suitable for developing new technologies that could revolutionize the electronics industry. In conclusion, benzimidazole (苯并咪唑) is a versatile compound with significant implications across various sectors, including medicine, agriculture, and material science. Its unique chemical structure allows for a wide range of applications, making it a subject of extensive research and development. As we continue to explore the potential of benzimidazole (苯并咪唑) and its derivatives, we may unlock new therapeutic strategies and innovative technologies that can benefit society as a whole.