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4,5,6,7 - tetrahydro - 3- (phenylmethyl) - dihydrochloride - (S) - 3H - Imidazo [4,5 - c] pyridine - 6 - carboxylic acid ihydrochloride What is the chemical structure of
This is a rather complex organic compound with a long name and many functional groups. According to this name "4,5,6,7-tetrahydro-3- (phenylmethyl) -dihydrochloride - (S) -3H-imidazolo [4,5-c] pyridine-6-carboxylic acid, dihydrochloride", its structure can be analyzed.
Its core structure is imidazolo [4,5-c] pyridine, which is formed by fusing the imidazole ring with the pyridine ring. At the 3rd position, there is phenyl methyl, that is, benzyl, adding a benzene ring structure to make the molecule aromatic. The 4th, 5th, 6th, and 7th positions are tetrahydrogenated, which means that these positions on the pyridine ring are saturated carbon and hydrogenated. The 6th position is connected with carboxylic acid groups, which is acidic. And this compound contains dihydrochloride, indicating that the molecule forms a salt with two molecules of hydrogen chloride, because there may be a basic check point in the molecule that can bind protons. And (S) indicates that the compound is chiral, and this chiral center or exists in the imidazolopyridine structure, which determines its stereochemical configuration. In short, the structure of this compound fuses a variety of groups and properties, and may have unique uses and properties in the fields of organic synthesis and medicinal chemistry.
4,5,6,7 - tetrahydro - 3- (phenylmethyl) - dihydrochloride - (S) - 3H - Imidazo [4,5 - c] pyridine - 6 - carboxylic acid ihydrochloride What are the physical properties
The physical properties of 4,5,6,7-tetrahydro-3- (phenylmethyl) - (S) -3H-imidazolo [4,5-c] pyridine-6-carboxylic acid dihydrochloride are particularly important for its application in various fields.
Looking at its morphology, at room temperature, or white to off-white crystalline powder, fine and uniform, this morphology is easy to store and use, and in many chemical reaction systems, it can rely on its good dispersion characteristics to facilitate the full progress of the reaction.
When it comes to solubility, it shows a certain solubility in water, and can partially dissolve to form a clear or slightly turbid solution. This property is of great significance in the preparation of pharmaceutical preparations, because water can be used as a solvent to integrate it into the system to achieve the expected drug effect release and absorption effect. In common organic solvents, such as ethanol and acetone, their solubility is also different. The solubility is slightly higher in ethanol, and a uniform solution can be formed, while the solubility is limited in acetone. This difference provides many ideas and basis for separation, purification and formulation optimization. The melting point of
, after rigorous determination, is about a specific temperature range. This temperature range is the inherent characteristic of the substance, like its unique "identity". The determination of the melting point not only helps to identify the purity of the substance, but also serves as a key monitoring indicator during the synthesis and preparation process to ensure the quality and stability of the product.
In terms of density, it has a relatively stable value. Although this value seems ordinary, it is an indispensable parameter in the measurement of materials and mixing ratio in chemical production, which directly affects the accuracy of the production process and the quality of the product.
The above physical properties are the key to the in-depth understanding and rational use of 4,5,6,7-tetrahydro-3- (phenylmethyl) - (S) -3H-imidazolo [4,5-c] pyridine-6-carboxylic acid dihydrochloride, which needs to be explored in detail before it can be used to its full potential.
4,5,6,7 - tetrahydro - 3- (phenylmethyl) - dihydrochloride - (S) - 3H - Imidazo [4,5 - c] pyridine - 6 - carboxylic acid What is the main use of ihydrochloride
This is the name of an organic compound. Looking at its name, it is extremely complicated. This compound is often used in the field of medicinal chemistry and is often a key intermediate involved in the development of new drugs.
In the process of pharmaceutical research and development, such complex organic compounds are often used as basic structures. Chemists modify and modify their structures to explore new drug molecules with better pharmacological activity, higher selectivity and lower toxic and side effects. It is a key cornerstone in the synthesis of medicinal chemistry, helping researchers build a drug structure with excellent efficacy.
Or in the field of biochemical research, this compound can be used as a tool to explore the mechanism of action of specific biomolecules, and to observe and analyze changes in biological processes by combining with targets in organisms, thus contributing to the understanding of life science.
Furthermore, in the field of organic synthetic chemistry, the synthesis process of this compound can test the skills and wisdom of chemists and motivate them to explore novel synthesis methods and strategies to achieve efficient and green synthesis paths and promote the development of organic synthetic chemistry.
4,5,6,7 - tetrahydro - 3- (phenylmethyl) - dihydrochloride - (S) - 3H - Imidazo [4,5 - c] pyridine - 6 - carboxylic acid ihydrochloride What are the synthesis methods
To make 4%2C5%2C6%2C7+-+tetrahydro+-+3+-+%28phenylmethyl%29+-+dihydrochloride+-+%28S%29+-+3H+-+Imidazo%5B4%2C5+-+c%5Dpyridine+-+6+-+carboxylic+acid+ihydrochloride, there are many methods, each with its own strengths, choose one or two to describe in detail.
One can be obtained by starting from a certain starting material and reacting in several steps. First, the raw material and a specific reagent are reacted under suitable conditions. This step requires temperature control and time control to achieve the best conversion. For example, under the action of a reagent A and B, in a certain catalyst, in a certain solvent, heated to a certain temperature, and reacted for several hours to obtain an intermediate product. Then the intermediate product is reacted with others, and also treated under specific conditions to gradually construct the target molecular structure. In this process, the control of the reaction conditions is the key, and a slight difference will affect the yield and purity.
Second, there are other methods. Start with C raw material and go through a unique reaction path. First, through a certain type of reaction, the raw material undergoes a specific transformation, or substitution, addition, etc. This reaction often requires a specific reaction environment, such as inert gas protection, precise pH regulation. Subsequent to several steps of modification, the structure of the target product is gradually reached. Each step of the reaction requires fine operation, and the separation and purification of intermediates cannot be ignored, otherwise impurities will accumulate and affect the quality of the final product.
Preparation of this product, although the methods are different, but all need to understand the reaction mechanism and strictly control the details of the operation, in order to improve the yield and purity, and obtain the required 4%2C5%2C6%2C7+-+tetrahydro+-+3+-+%28phenylmethyl%29+-+dihydrochloride+-+%28S%29+-+3H+-+Imidazo%5B4%2C5+-+c%5Dpyridine+-+6+-+carboxylic+acid+ihydrochloride.
4,5,6,7 - tetrahydro - 3- (phenylmethyl) - dihydrochloride - (S) - 3H - Imidazo [4,5 - c] pyridine - 6 - carboxylic acid ihydrochloride What are the precautions during use
This is 4,5,6,7-tetrahydro-3- (phenylmethyl) - (S) -3H-imidazolo [4,5-c] pyridine-6-carboxylic acid dihydrochloride. When using, many matters should be paid attention to.
First, the properties of this substance are crucial. It is a specific organic compound chemically synthesized, containing dihydrochloride components, with specific chemical activity and stability. When using, be sure to check its physical and chemical properties, such as solubility, melting point, boiling point, etc., which are crucial for accurate control and reaction conditions setting. If its solubility is unknown, or the reaction system is uneven, it will affect the reaction process and product purity.
Second, safety protection should not be underestimated. Chemicals have many latent risks, and this compound may be irritating, toxic and other hazards. When taking it, protective measures must be comprehensive, such as wearing laboratory clothes, wearing gloves and goggles, to ensure that the operation is carried out in a well-ventilated place, to prevent inhalation, contact with skin and eyes, so as not to damage health.
Third, the reaction conditions need to be precisely controlled. When participating in a chemical reaction, factors such as temperature, pH, reaction time, etc. have a great impact on the reaction result. At different temperatures, the reaction rate and product selectivity may vary. If the temperature is too high, side reactions may occur; if the temperature is too low, the reaction will be slow or even difficult to proceed. Therefore, it is necessary to precisely regulate the reaction conditions according to the reaction mechanism and the expected product.
Fourth, the storage conditions cannot be ignored. Improper storage may cause the compound to deteriorate and deactivate. According to its nature, a suitable storage environment should be selected, such as a dry and cool place, to avoid light, moisture and contact with other substances to initiate reactions, so as to ensure its quality and performance stability. In this way, good use results can be obtained and latent risks and losses can be avoided.
