As a leading (S)-(+)-N,N-Dimethyl-3-Napthtoxy-(2-Thiophene) Propylamine Oxalate supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.
What is the chemical structure of (S) - (+) -N, N-Dimethyl-3-Napthtoxy- (2-Thiophene) Propylamine Oxalate?
This is (S) - (+) -N, N-dimethyl-3-naphthoxy- (2-thiophene) propylamine oxalate, and its chemical structure is quite complex. This compound is composed of many key parts, the naphthoxy part, the naphthalene ring has a rigid and conjugated structure, and its oxygen atoms can affect the molecular properties by forming hydrogen bonds or participating in electron cloud interactions. As a sulfur-containing heterocycle, thiophenyl groups have a special electron cloud distribution, which endows the molecule with unique electronic properties and reactivity. The propylamine chain provides a flexible part for the molecule. N, N-dimethyl modification changes the electron density and steric resistance of nitrogen atoms, which affects molecular solubility and interactions with other molecules. Oxalate part, oxalate ions form salts with amine groups to improve the stability and solubility of compounds.
Overall view, (S) - (+) -N, N -dimethyl-3-naphthoxy- (2-thiophene) propylamine Oxalate structure interacts with each part to synergistically determine its physicochemical properties and biological activities, which may have potential application value in the fields of medicinal chemistry and organic synthesis.
What are the main uses of (S) - (+) -N, N-Dimethyl-3-Napthtoxy- (2-Thiophene) Propylamine Oxalate?
(S ) - (+) - N, N-dimethyl-3-naphthoxy- (2-thiophene) propylamine oxalate, which is an organic compound. It has a wide range of uses in the field of medicine, or has potential medicinal value, or can act as a pharmaceutical intermediate, helping to develop new drugs for the treatment of specific diseases. However, the specific efficacy and applicable diseases still need to be confirmed by in-depth research and clinical trials.
In the field of scientific research, it is an important research object. Scientists use it to explore its chemical properties and reaction mechanisms to deepen their understanding of the relevant knowledge in the field of organic chemistry and promote the development of chemical disciplines. Or it can be used to develop new chemical synthesis methods and open up new ideas for organic synthetic chemistry. < Br >
In the chemical industry, it may be a key raw material for the preparation of special materials. After specific reactions and processing, it is converted into materials with unique properties. It is used in fields such as polymer materials and functional coatings to meet the diverse needs of different industries for material properties.
Looking at its application, although it has broad prospects, in actual use, it is also necessary to carefully consider its safety and environmental impact, follow relevant regulations and standards, and ensure its rational and safe use.
What is the synthesis method of (S) - (+) -N, N-Dimethyl-3-Napthtoxy- (2-Thiophene) Propylamine Oxalate?
The synthesis method of (S) - (+) -N, N -dimethyl-3-naphthoxy- (2-thiophene) propane oxalate is an exquisite chemical process. The method needs to follow rigorous steps and principles.
At the beginning, various raw materials need to be carefully selected. Pure naphthol is selected, which is the key starting material, and its purity depends on the quality of the product. The match is a specific thiophene derivative, and the two need to be compatible in precise proportions.
At the beginning of the reaction, place naphthol in a suitable reaction vessel and add an appropriate amount of organic solvent to create a suitable reaction environment. Next, slowly add alkali substances, which can catalyze the process of the reaction and activate naphthol. After the activation of naphthol is completed, add thiophene derivatives dropwise. This process requires close attention to the temperature and rate of the reaction to prevent the reaction from being too violent or slow.
After the initial reaction of naphthol and thiophene derivatives, introduce dimethylamine reagent. The addition of dimethylamine transforms the chemical structure of the reaction system and gradually approaches the structure of the target product. At this stage, the pH and temperature of the reaction need to be strictly controlled to ensure that the reaction proceeds along the expected path.
After the above steps, the reaction preliminarily generates (S) - (+) -N, N -dimethyl-3-naphthoxy- (2-thiophene) propylamine. However, this product still needs further processing to form oxalate form. Then oxalic acid is added, and oxalic acid reacts with the above product to form a salt, and (S) - (+) -N, N -dimethyl-3-naphthoxy- (2-thiophene) propylamine oxalate crystals are precipitated.
Finally, the crystalline product is filtered, washed and dried to obtain high-purity (S) - (+) -N, N -dimethyl-3 -naphthoxyl- (2 -thiophene) propylamine oxalate. Each step needs to be carefully controlled, and a slight poor pool may affect the quality and yield of the product.
What are the physicochemical properties of (S) - (+) -N, N-Dimethyl-3-Napthtoxy- (2-Thiophene) Propylamine Oxalate?
(S ) -( + ) - N, N-dimethyl-3-naphthoxy- (2-thiophene) propylamine oxalate, this is an organic compound. Its physical and chemical properties are very important, and it is related to its application in many fields.
First of all, the appearance of this compound is usually white to off-white crystalline powder, fine texture, and slightly shiny under light. This appearance feature is easy to identify and preliminarily judge.
Melting point is also a key property. Its melting point is in a specific range, which is of great significance for identification and purity considerations. Accurate determination of melting point can help to judge the purity of the compound. If the melting point deviates from the standard value, or suggests that there are impurities mixed in.
In terms of solubility, (S ) -( + ) - N, N -dimethyl-3-naphthoxy- (2-thiophene) propylamine oxalate exhibits different solubility characteristics in common organic solvents. In polar organic solvents such as methanol and ethanol, it has certain solubility and can form a uniform solution; in non-polar solvents such as n-hexane, the solubility is poor. This property is a key consideration in the separation, purification and preparation of compounds.
Stability cannot be ignored either. Under normal storage conditions, this compound is relatively stable. When exposed to high temperature, strong light or specific chemical substances, the stability may be affected. For example, in a high temperature environment, it may trigger a decomposition reaction, causing its chemical structure to change, which in turn affects its performance and efficacy.
Furthermore, its acidity and alkalinity are also important properties. The form of oxalate determines that it has certain acidic characteristics, and its chemical behavior varies in different acid-base environments. This property has a significant impact on drug absorption, distribution and metabolism in the field of drug development.
(S) - (+) -N, N-Dimethyl-3-Napthtoxy- (2-Thiophene) Propylamine Oxalate in the market prospects?
(S ) - (+) - N, N - dimethyl - 3 - naphthoxy - (2 - thiophene) propylamine oxalate in the market prospects? This is related to the field of medicinal chemistry.
Looking back at the past, new chemical compounds often need to go through a lot of hard work at the beginning of their advent. Or due to the complex synthesis process, resulting in high costs, which is a constraint on promotion. And drug research and development, must follow strict regulations, after many clinical trials, prove that it is safe and effective, before it can enter the market.
(S ) - (+) - N, N-dimethyl-3-naphthoxy- (2-thiophene) propylamine oxalate, if it has unique pharmacological activity, such as excellent efficacy in the treatment of specific diseases, may open up new paths. However, it is also facing competition. Similar drugs may already occupy the market, and it is not easy to stand out.
Furthermore, market demand is also the key. If the disease targeted is frequently-occurring and difficult, and existing therapies are insufficient, its prospects may be brighter. However, if the audience is scarce, or there are alternatives, the road to promotion will be difficult.
Although there are potential advantages, if you want to succeed in the market, you must carefully plan for R & D, production, and promotion, weigh costs and benefits, and respond to regulations and policies in order to find a place. The future remains to be clarified by multiple efforts and opportunities.
