Disodium 4-[3-Methyl-N-(4-Sulfonatobutyl)Anilino]Butane-1-Sulfonate

4- [3-methyl-N - (4-cyanobutyl) benzamide] butyric acid-1-cyanoguanidine, the main application fields of this compound are mostly involved in the field of medical chemistry. In pharmaceutical research and development, such organic compounds containing specific functional groups are often used as key intermediates to create new bioactive drugs.
Looking at its structure, functional groups such as methyl, cyano, and amide groups endow it with unique physicochemical and biological properties. The presence of cyano groups can enhance molecular polarity, affect the solubility and chemical reactivity of compounds, and play a key role in the binding of drugs to targets, or help improve drug affinity and specificity. The amide group has good biocompatibility and can participate in the formation of hydrogen bonds, which is of great significance for stabilizing the conformation of drugs and optimizing the interaction with biomacromolecules.
In the field of anti-cancer drug development, many studies have used these compounds to construct targeted anti-cancer drugs. Its specific structure can precisely act on specific targets of cancer cells, such as certain protein kinases or key nodes of signaling pathways, blocking the proliferation and metastasis of cancer cells, thereby inhibiting the growth and spread of cancer cells.
In the development of drugs for neurological diseases, such compounds may be similar in structure to neurotransmitters and receptors, which can regulate the function of the nervous system, or can be developed as potential drugs for the treatment of neurodegenerative diseases such as Alzheimer's disease and Parkinson's disease.
There are also studies exploring its application potential in the field of cardiovascular diseases. By regulating related targets such as angiotensin converting enzyme, or having a positive impact on blood pressure regulation and cardiovascular remodeling, it provides new ideas for the treatment of cardiovascular diseases.

4- [3-methyl-N- (4-chlorobenzyl) benzamide] butyric acid-1-sodium chlorate, the physical and chemical properties of this substance are as follows:
Its appearance or white to slightly yellow crystalline powder. In terms of solubility, in common organic solvents, such as ethanol, acetone, etc., there is a certain solubility, and the solubility in water is relatively small. This property allows for the separation, purification or preparation of related preparations, according to the difference in solubility, select a suitable solvent for operation.
In terms of melting point, it is determined that the transition from solid to liquid occurs within a specific temperature range. This melting point characteristic is crucial for identifying the substance and controlling its stability under heating and other conditions.
In terms of stability, under normal temperature and general environmental conditions, the substance is relatively stable and is not prone to self-decomposition or other violent chemical reactions. However, if placed in a high temperature, high humidity environment, or in contact with specific strong oxidizing agents or reducing agents, it may initiate chemical reactions, causing structural changes, which in turn affect its performance and efficacy.
In terms of acidity and alkalinity, some groups in the molecular structure of 4- [3-methyl-N - (4-chlorobenzyl) benzamide] butyric acid-1-sodium chlorate may cause the substance to exhibit certain acidic or alkaline characteristics, which has a key impact on the chemical reactions it participates in and the forms and reactivity in different acid-base environments.
In the field of chemical synthesis, understanding its physicochemical properties is helpful to optimize the synthesis route, improve the yield and purity; in drug development, these properties are related to the absorption, distribution, metabolism and excretion of drugs, and play a significant role in the design of drug dosage forms and drug efficacy.

4- [3-methyl-N- (4-cyanobutyl) benzamide] butyric acid-1-cyanoguanidine has many points to pay attention to in the production process.
The first priority is the selection and control of raw materials. The purity and quality of raw materials have a profound impact on the quality and performance of products. It is necessary to carefully screen suppliers and strictly test raw materials to ensure that their indicators meet the production requirements. For raw materials related to specific groups such as methyl and cyanobutyl, more attention should be paid to their purity to prevent impurities from being incorporated, interfering with the reaction process and reducing the purity of the product.
The reaction conditions are also crucial. Temperature, pressure, reaction time and other parameters will affect the rate of reaction and the yield of the product. If the temperature is too high or too low, side reactions may be triggered, resulting in impure products; if the pressure is not properly controlled, the reaction may not proceed smoothly. Therefore, it is necessary to explore the best reaction conditions through multiple experiments and precisely control them during the production process to ensure the stability of the reaction. For example, some reactions need to be carried out within a specific temperature range, and the temperature fluctuation must not exceed the specified range. The use of
catalysts cannot be ignored either. A suitable catalyst can significantly accelerate the reaction rate and improve the yield of the product. However, the type and dosage of catalysts need to be accurately considered. If the amount of catalyst is too small, the catalytic effect is not good; if the amount is too large, it may increase the cost or even introduce new impurities. Therefore, the catalyst should be selected scientifically according to the reaction characteristics, and the dosage should be strictly controlled.
Furthermore, the selection and maintenance of reaction equipment should not be underestimated. The material of the equipment should be able to withstand the corrosion of chemical substances during the reaction process, and have good heat and mass transfer performance. Regular inspection and maintenance of the equipment to prevent leakage and other problems to ensure production safety and product quality. For example, the sealing performance of the reactor must be ensured to ensure good, to avoid leakage of reactants or entry of external impurities.
Separation and purification of the product is also a key link. After the reaction is completed, the product may be mixed with impurities such as unreacted raw materials and by-products. Appropriate separation methods, such as distillation, extraction, crystallization, etc., need to be selected to purify the product to the specified purity. At the same time, during the separation and purification process, attention should be paid to the operating conditions to prevent the loss or deterioration of the product.
The cleanliness and safety of the production environment are also extremely important. During the production process of this compound, some raw materials or products may have dangerous characteristics such as toxicity and corrosion. Therefore, the production site needs to have good ventilation facilities, and the staff should strictly follow the safety operation procedures and take protective measures to prevent safety accidents. In addition, the waste generated in the production process should be properly handled to avoid pollution to the environment.

The advantages of 4- [3-methyl-N- (4-pyridylbutyl) benzylamino] butyric acid-1-pyridinium salt over other similar products lie in the following points:
First of all, in terms of structural characteristics, the unique chemical structure of this compound gives it excellent stability. The pyridyl group in its molecule interacts with the benzylamine group to build a relatively stable chemical structure, which is like a solid foundation, ensuring that the product is not easy to decompose and deteriorate under various environmental conditions. For example, in some application scenarios that require long-term storage or in complex environments, the product can maintain its own stability for a long time, while many congeneric products may experience performance degradation due to structural instability.
Secondly, in terms of activity performance, this compound exhibits a high degree of activity. The presence of pyridyl groups is like a precise key that can specifically bind to certain targets, which makes it exhibit efficient catalytic ability or precise binding ability to target substances when participating in various chemical reactions. For example, in the field of drug development, it can precisely act on specific biological targets. Compared with the blindness of some congeneric products, it can play a more effective pharmacological role, improve the therapeutic effect, and reduce the impact on other non-target sites and reduce side effects.
Furthermore, the product has good solubility. Whether it is in common organic solvents or specific reaction systems, it can show good solubility characteristics. This property greatly enhances its convenience in practical applications, enabling it to be evenly dispersed in the reaction system or preparation, promoting the smooth progress of the reaction and ensuring the consistency of product performance. Many similar products may have problems such as agglomeration and precipitation during application due to poor solubility, which affects the use effect of the product.
Finally, from the perspective of cost-effectiveness, the synthesis process is relatively simple and efficient. Compared with some similar products with complex structure, cumbersome synthesis steps and high cost, 4- [3-methyl-N- (4-pyridylbutyl) benzylamine] butyric acid-1-pyridyl salt can be mass-produced in a more economical way under the premise of ensuring product quality and performance, thus having a significant cost advantage in the market, laying a solid economic foundation for its wide application.

The market price range of 4- [3-methyl-N- (4-cyanobenzyl) indolyl] butyric acid-1-cyanoguanidine-1-sodium cyanoate is difficult to say exactly. Its price is influenced by many factors, such as the quality of materials, the simplicity of the process, supply and demand conditions, regional differences, and even changes in market conditions.
On the material, if the raw material is pure, it is not easy to obtain, or the quality is strictly controlled, the cost will rise, and the price will be high; if the process requires exquisite skills, complicated processes, or special equipment and reagents, the cost will also increase, and the price will rise accordingly.
On the supply and demand side, if there are many seekers and few suppliers, the price will often rise; on the contrary, if the supply exceeds the demand, the price may fall. Regional differences are also the main factor, and different places have different prices due to economic levels, tax policies, and logistics costs.
Furthermore, the market situation is unpredictable, and the economy will rise or fall, policies will rise or fall, and the number of competing products will fluctuate.
To determine its market price, you can consult chemical raw material suppliers, traders, or refer to relevant industry reports and market surveys. However, the price obtained is only a reference for a time and place, and it is difficult to determine.