benzo[d]imidazole-5-carboxamido)

The chemical structure of benzo [d] imidazole-5-formamide is an interesting topic in the field of organic chemistry. In this compound structure, the benzimidazole ring is the core structure. The benzimidazole ring is formed by fusing the benzene ring and the imidazole ring, which has unique aromatic properties and stability.
The benzimidazole ring is connected with a formamide group at position 5. The formamide group (-CONH _ 2) is composed of a carbonyl group (-CO-) linked to an amino group (-NH _ 2). In the carbonyl group, the carbon-oxygen double bond gives it a certain polarity and reactivity, and the amino group can participate in many reactions such as the formation of hydrogen bonds.
Such a structure endows benzo [d] imidazole-5-formamide with various chemical properties and potential applications. For example, due to the characteristics of benzimidazole ring, it may participate in coordination chemistry to form complexes with metal ions; the existence of formamide groups makes it possible to use it in organic synthesis or as a reaction check point for amide bond-related conversion reactions, which has potential uses in pharmaceutical chemistry, materials science and other fields. The delicate combination of its chemical structures lays the foundation for exploring more novel properties and applications.

Benzo [d] imidazole-5-formamide has a wide range of uses. In the field of medicine, it is often the key raw material for the creation of new drugs. Due to its unique chemical structure, it can fit with many targets in the body, or can regulate physiological functions, which is very helpful for the treatment of diseases. For example, in the development of anti-tumor drugs, through ingenious modification and modification, drugs with the ability to target specific tumor cells can be prepared, which can precisely attack the source of the disease and have little damage to normal cells. It is an important direction of medical research.
In the field of materials, it also has extraordinary performance. Because of its stable structure and certain functionality, it is often used to prepare high-performance functional materials. For example, in optical materials, materials can be endowed with special optical properties, such as fluorescence properties, etc., which can be used in optical sensing, biological imaging and other fields to help researchers spy on the mysteries of the microscopic world.
Furthermore, in agriculture, it also has its place. It can be used as a component of plant growth regulators to regulate the growth and development process of plants. Or it can promote the vigorous growth of plant roots and enhance their ability to absorb nutrients; or it can adjust the flowering and fruiting of plants, improve crop yield and quality, and contribute to the harvest of agriculture.
In summary, benzo [d] imidazole-5-formamide has important uses in medicine, materials, agriculture and other fields, and has made great contributions to human life and scientific research progress.

Benzo [d] imidazole-5-formamide This substance has many physical properties. In terms of its color state, it is often white to light yellow powder, and it is fine and uniform in texture. In terms of solubility, it is slightly dissolved in common organic solvents such as ethanol and acetone, like a boat-walking shoal, and it is difficult to flow smoothly; in water, the solubility is extremely low, like a stone sinking into the sea, and it is difficult to find traces.
Its melting point is quite high, just like a fortified city barrier. It needs to reach about 300 ° C before it begins to melt. At this high temperature, its shape changes, from a solid state to a liquid state. Stability is also its outstanding characteristic. Under normal environmental conditions, such as room temperature and pressure without strong oxidants, strong acids and alkalis, it can maintain its own structure and properties for a long time, just like a general sitting firmly in the army tent, without moving.
In case of high temperature and open flame, it is like a tiger that is angered and easy to cause danger. Its density also has characteristics. The relative density is heavier than that of ordinary lightweight substances, but it is not as heavy as heavy metals. It is within a certain range, and the specific value depends on accurate measurement. The physical properties of this benzo [d] imidazole-5-formamide are of great significance in the application of chemistry, medicine and other fields, laying the foundation for its subsequent use.

To prepare benzo [d] imidazole-5-formamide, there are many methods, each with its own advantages.
First, benzimidazole-5-carboxylic acid can be used as the starting point to react with ammonia or amines under suitable conditions. For example, when benzimidazole-5-carboxylic acid and ammonia are reacted at high temperature and pressure with the assistance of a catalyst, through amidation, benzo [d] imidazole-5-formamide can be obtained. Among them, the control of temperature is extremely critical. If it is too high or causes side reactions, if it is too low, the reaction will be delayed.
Second, benzimidazole-5-formyl chloride is used to react with ammonia or amines. First, benzimidazole-5-formyl chloride is prepared, and then it is slowly mixed with ammonia or amine at low temperature. The reaction is mild and the yield is also good. However, formyl chloride is active, and it needs to be carefully prepared and stored to prevent its hydrolysis.
Third, through the hydrolysis of benzimidazole-5-nitrile. In an acidic or alkaline environment, benzimidazole-5-nitrile is hydrolyzed to obtain benzimidazole-5-formamide. In acidic hydrolysis, sulfuric acid, hydrochloric acid, etc. are commonly used; in alkaline hydrolysis, strong bases such as sodium hydroxide are used. In this process, the degree of hydrolysis is related to the purity and yield of the product.
Fourth, an organic synthesis strategy is used to build a benzimidazole ring from the basic raw material through multi-step reaction, and a formamide group is introduced at the same time. Although this approach is complex, it can be fine-tuned according to the required molecular structure to obtain the target product with specific structure and properties.
All these methods have advantages and disadvantages. In actual preparation, the appropriate method needs to be carefully selected according to the availability of raw materials, cost, equipment conditions, and requirements for product purity and yield, in order to achieve the desired preparation effect.

I have not heard that there is a definite price for benzo [d] imidazole - 5 - carboxamido in the market. However, if you want to know its price, you can find it in various ways.
First, interview the merchants of various pharmaceutical shops. They are often involved in the sale of various medicinal materials, or know the approximate price of this product. Trade in the city, the price varies according to the quality, quantity, and source. If the quality is good and the quantity is wide, and the production is near the place, the price may be slightly lower; on the contrary, the quality is poor and the quantity is rare, and the distance comes, the price will be high.
Second, ask the physicians and pharmacists. They are familiar with the pharmacological price, and may have heard of the use and price of benzo [d] imidazole - 5 - carboxamido. Doctors often calculate the cost of medicine, and pay great attention to the price of various medicines.
Third, look at the records of the market and the books of merchants. In ancient times, the market was easy, and there are bookkeeping, and now there are electronic records. Search for relevant transaction records, or you can get the range of its price.
However, this thing may be a rare medicinal material, or it is not widely available in the market, and the price is difficult to know. After going through various paths, it is still difficult to determine its price. It is necessary to inquire from many parties and study schools in detail before you can hope to get a more accurate price range.