Linshang Chemical
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4-[2-(5-Chloro-2-Methoxy-Benzamide)Ethyl]-Benzenesulphonamide
Linshang Chemical
|
HS Code |
442101 |
| Chemical Formula | C16H17ClN2O4S |
| Molecular Weight | 368.84 g/mol |
| Appearance | Solid (usually white to off - white) |
| Solubility In Water | Low solubility |
| Solubility In Organic Solvents | Soluble in some organic solvents like dichloromethane, DMSO |
| Melting Point | Specific value would require experimental determination |
| Boiling Point | Specific value would require experimental determination |
| Pka | Related to its acidic or basic functional groups (experimental determination needed) |
| Logp | Indicates lipophilicity (experimental determination needed) |
| Chemical Class | Sulphonamide - benzamide derivative |
| Uv Vis Absorption | Characteristic absorption peaks in UV - Vis spectrum (experimental determination needed) |
| Ir Absorption | Characteristic absorption bands in IR spectrum for functional groups |
As an accredited 4-[2-(5-Chloro-2-Methoxy-Benzamide)Ethyl]-Benzenesulphonamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 kg of 4-[2-(5 - chloro - 2 - methoxy - benzamide)ethyl] - benzenesulphonamide in sealed plastic bags. |
| Storage | Store 4-[2-(5 - chloro - 2 - methoxy - benzamide)ethyl] - benzenesulphonamide in a cool, dry place, away from heat sources and direct sunlight. Keep it in a tightly - sealed container to prevent moisture absorption and contamination. Store separately from incompatible substances, such as strong oxidizing agents, to avoid potential chemical reactions. |
| Shipping | The chemical 4 - [2 - (5 - chloro - 2 - methoxy - benzamide)ethyl] - benzenesulphonamide will be shipped in sealed, corrosion - resistant containers. Adequate cushioning is used to prevent damage during transit, following strict chemical shipping regulations. |
Competitive 4-[2-(5-Chloro-2-Methoxy-Benzamide)Ethyl]-Benzenesulphonamide prices that fit your budget—flexible terms and customized quotes for every order.
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Where to Buy 4-[2-(5-Chloro-2-Methoxy-Benzamide)Ethyl]-Benzenesulphonamide in China?
As a trusted 4-[2-(5-Chloro-2-Methoxy-Benzamide)Ethyl]-Benzenesulphonamide manufacturer, we deliver:
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As a leading 4-[2-(5-Chloro-2-Methoxy-Benzamide)Ethyl]-Benzenesulphonamide 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 4- [2- (5-chloro-2-methoxy-benzamide) ethyl] -benzenesulfonamide
4 - [2 - (5 - cyanogen - 2 - methoxy - benzyl acetic anhydride) ] - benzyl acetic anhydride, its chemical structure is quite complicated. Among them, cyano (-CN) has strong electronegativity, which affects both molecular reactivity and stability. 2 - Methoxy, that is, methyl is connected to the oxygen group and added to the benzyl structure, which will change the distribution of benzyl electron clouds and affect its nucleophilic or electrophilic reactivity.
Benzyl acetic anhydride is composed of the structural phase of benzyl and acetic anhydride. The structure of acetic anhydride contains carbonyl (C = O), which is electrophilic and is often a check point for nucleophilic substitution reactions. The conjugation system of the benzene ring in benzyl gives the molecule specific electron delocalization characteristics, which affects the overall stability and reactivity. In
5-cyano-2-methoxy-benzyl acetic anhydride, each group interacts with each other, and the cyano and methoxy groups have different electronic effects on benzyl groups, or induce or conjugate, which comprehensively affects the molecular reaction path and chemical properties. When this structure participates in the reaction, the electrophilicity of carbonyl groups, the conjugation effect of benzene rings, and the electronic effects of cyano and methoxy groups are all key factors, which affect the reaction rate and product formation.
And for 4- [2- (5-cyanogen-2-methoxy-benzyl acetic anhydride) ] -benzyl acetic anhydride as a whole, the structure of benzyl acetic anhydride on both sides, under different reaction conditions, or competition or synergy, depending on the specific reaction mechanism and environment, exhibit unique chemical behavior, which affects its application in organic synthesis, pharmaceutical chemistry and other fields.
Benzyl acetic anhydride is composed of the structural phase of benzyl and acetic anhydride. The structure of acetic anhydride contains carbonyl (C = O), which is electrophilic and is often a check point for nucleophilic substitution reactions. The conjugation system of the benzene ring in benzyl gives the molecule specific electron delocalization characteristics, which affects the overall stability and reactivity. In
5-cyano-2-methoxy-benzyl acetic anhydride, each group interacts with each other, and the cyano and methoxy groups have different electronic effects on benzyl groups, or induce or conjugate, which comprehensively affects the molecular reaction path and chemical properties. When this structure participates in the reaction, the electrophilicity of carbonyl groups, the conjugation effect of benzene rings, and the electronic effects of cyano and methoxy groups are all key factors, which affect the reaction rate and product formation.
And for 4- [2- (5-cyanogen-2-methoxy-benzyl acetic anhydride) ] -benzyl acetic anhydride as a whole, the structure of benzyl acetic anhydride on both sides, under different reaction conditions, or competition or synergy, depending on the specific reaction mechanism and environment, exhibit unique chemical behavior, which affects its application in organic synthesis, pharmaceutical chemistry and other fields.
What is the main use of 4- [2- (5-chloro-2-methoxy-benzamide) ethyl] -benzenesulfonamide
This question seems to seek the main use of benzenesulfonamide in "4- [2- (5-hydroxy-2-methylamino-benzamide) ethyl] -benzenesulfonamide", and imitate the classical Chinese of "Tiangong Kaiwu" to answer. The following is the answer:
Benzenesulfonamide has a wide range of uses. In the field of medicine, it is often a key raw material. Its properties can participate in drug synthesis, help make all kinds of good medicines, or have antibacterial and anti-inflammatory effects, or relieve pain. Doctors use it as medicine to save people and diseases, so that patients can be safe from suffering.
In the chemical industry, it is also indispensable. It can be used to create special chemicals and add special properties to chemical products. For example, in some fine chemical products, it can optimize its quality, increase its stability, or change its reactivity, making the product suitable for diverse needs.
Furthermore, in the process of scientific research and exploration, benzenesulfonamide is an important reagent. Scientists use its characteristics to explore new reaction paths and open up the frontier of chemical cognition. Through various experiments, to understand the principle of material changes, pave the way for scientific progress, and help new discoveries and new creations to be born.
From this perspective, although benzenesulfonamide is small, it has made important contributions in various fields such as medicine, chemical industry, and scientific research, which cannot be ignored.
Benzenesulfonamide has a wide range of uses. In the field of medicine, it is often a key raw material. Its properties can participate in drug synthesis, help make all kinds of good medicines, or have antibacterial and anti-inflammatory effects, or relieve pain. Doctors use it as medicine to save people and diseases, so that patients can be safe from suffering.
In the chemical industry, it is also indispensable. It can be used to create special chemicals and add special properties to chemical products. For example, in some fine chemical products, it can optimize its quality, increase its stability, or change its reactivity, making the product suitable for diverse needs.
Furthermore, in the process of scientific research and exploration, benzenesulfonamide is an important reagent. Scientists use its characteristics to explore new reaction paths and open up the frontier of chemical cognition. Through various experiments, to understand the principle of material changes, pave the way for scientific progress, and help new discoveries and new creations to be born.
From this perspective, although benzenesulfonamide is small, it has made important contributions in various fields such as medicine, chemical industry, and scientific research, which cannot be ignored.
What are the production methods of 4- [2- (5-chloro-2-methoxy-benzamide) ethyl] -benzenesulfonamide
There are several ways to obtain 4- [2- (5-cyanogen-2-methoxy-benzyl) ethyl] -benzylnitrile. Under the idea of "Tiangong Kaiwu", the ancient method can be regarded as follows.
First, it can be synthesized through organic synthesis. First take appropriate starting materials, such as aromatic compounds containing cyanide and methoxy groups, and combine them with chain compounds with appropriate functional groups. Under suitable reaction conditions, such as in the presence of a specific catalyst, control temperature, pressure and reaction time, carry out nucleophilic substitution or condensation reactions, and gradually build the carbon skeleton of the target molecule, and then introduce the required groups to obtain this compound.
Second, or consider extracting relevant structural units from natural products and then chemically modifying them to form. In some plants or microorganisms in nature, or components with similar structures, after extraction, separation and purification, according to the structural requirements of the target compound, chemical means, such as oxidation, reduction, substitution and other reactions, are used to modify and modify its functional groups to achieve the purpose of synthesis.
Third, you can also try to use the concept of biomimetic synthesis. Mimic the chemical reaction mechanism in organisms, use enzymes or similar biological catalysts to react under milder conditions. Enzymes in living organisms have a high degree of selectivity and catalytic efficiency, which can guide the reaction in a specific direction, or can effectively reduce the occurrence of side reactions, improve the purity and yield of the product, and thereby synthesize 4- [2- (5-cyano2-methoxy-benzyl) ethyl] -benzylnitrile.
However, no matter what method is used, it is necessary to carefully consider the reaction conditions, the choice and cost of raw materials, the separation and purification of the product, and many other factors in order to obtain this compound efficiently, economically and environmentally friendly.
First, it can be synthesized through organic synthesis. First take appropriate starting materials, such as aromatic compounds containing cyanide and methoxy groups, and combine them with chain compounds with appropriate functional groups. Under suitable reaction conditions, such as in the presence of a specific catalyst, control temperature, pressure and reaction time, carry out nucleophilic substitution or condensation reactions, and gradually build the carbon skeleton of the target molecule, and then introduce the required groups to obtain this compound.
Second, or consider extracting relevant structural units from natural products and then chemically modifying them to form. In some plants or microorganisms in nature, or components with similar structures, after extraction, separation and purification, according to the structural requirements of the target compound, chemical means, such as oxidation, reduction, substitution and other reactions, are used to modify and modify its functional groups to achieve the purpose of synthesis.
Third, you can also try to use the concept of biomimetic synthesis. Mimic the chemical reaction mechanism in organisms, use enzymes or similar biological catalysts to react under milder conditions. Enzymes in living organisms have a high degree of selectivity and catalytic efficiency, which can guide the reaction in a specific direction, or can effectively reduce the occurrence of side reactions, improve the purity and yield of the product, and thereby synthesize 4- [2- (5-cyano2-methoxy-benzyl) ethyl] -benzylnitrile.
However, no matter what method is used, it is necessary to carefully consider the reaction conditions, the choice and cost of raw materials, the separation and purification of the product, and many other factors in order to obtain this compound efficiently, economically and environmentally friendly.
What is the safety of 4- [2- (5-chloro-2-methoxy-benzamide) ethyl] -benzenesulfonamide?
The safety of Ximing 4- [2- (5-cyanogen-2-methoxy-benzyl-thiophene-acetyl) ethyl] -thiophene-acetyl requires detailed investigation of its chemical properties, reactivity, toxicology, etc.
This compound contains cyanyl, cyanyl, and many are toxic. It may release cyanide ions in the body and combine with iron ions of cytochrome oxidase, causing interruption of the respiratory chain of cells and inability to utilize oxygen, resulting in tissue hypoxia, asphyxia, and life-threatening.
It also contains thiophene structure, and thiophene compounds may have certain biological activity and toxicity. Or affect the functions of the nervous system, liver, kidney and other organs. Such as long-term exposure or ingestion, or cause nervous system symptoms, such as headache, dizziness, fatigue, or cause liver and kidney damage, resulting in abnormal liver function indicators and decreased kidney function.
In addition, it contains groups such as methoxy, benzyl, and acetyl. Methoxy groups may affect the lipophilic and metabolic pathways of molecules, the spatial hindrance and electronic effects of benzyl groups or affect the activity and stability of compounds, and acetyl groups may be involved in metabolic transformation in vivo. However, the exact impact of these groups on safety needs to be carefully investigated in combination with specific reactions and metabolic mechanisms.
Its safety concerns all aspects of synthesis, storage, and use. During synthesis, if the reaction conditions are improper, harmful by-products may be generated. If the storage is not in accordance with the specifications, factors such as temperature and humidity, light or cause the compound to decompose and deteriorate, resulting in toxic substances. When used, the operator is not well protected, or ingested through respiratory tract, skin contact and other means, which endangers health.
Therefore, only based on the existing structural information, it is difficult to determine its absolute safety. To be sure, it is necessary to undergo rigorous toxicological experiments, safety assessments, and consider the toxic effects under different exposure routes, doses, and times before a comprehensive and scientific conclusion can be reached to ensure the safety of personnel and the environment.
This compound contains cyanyl, cyanyl, and many are toxic. It may release cyanide ions in the body and combine with iron ions of cytochrome oxidase, causing interruption of the respiratory chain of cells and inability to utilize oxygen, resulting in tissue hypoxia, asphyxia, and life-threatening.
It also contains thiophene structure, and thiophene compounds may have certain biological activity and toxicity. Or affect the functions of the nervous system, liver, kidney and other organs. Such as long-term exposure or ingestion, or cause nervous system symptoms, such as headache, dizziness, fatigue, or cause liver and kidney damage, resulting in abnormal liver function indicators and decreased kidney function.
In addition, it contains groups such as methoxy, benzyl, and acetyl. Methoxy groups may affect the lipophilic and metabolic pathways of molecules, the spatial hindrance and electronic effects of benzyl groups or affect the activity and stability of compounds, and acetyl groups may be involved in metabolic transformation in vivo. However, the exact impact of these groups on safety needs to be carefully investigated in combination with specific reactions and metabolic mechanisms.
Its safety concerns all aspects of synthesis, storage, and use. During synthesis, if the reaction conditions are improper, harmful by-products may be generated. If the storage is not in accordance with the specifications, factors such as temperature and humidity, light or cause the compound to decompose and deteriorate, resulting in toxic substances. When used, the operator is not well protected, or ingested through respiratory tract, skin contact and other means, which endangers health.
Therefore, only based on the existing structural information, it is difficult to determine its absolute safety. To be sure, it is necessary to undergo rigorous toxicological experiments, safety assessments, and consider the toxic effects under different exposure routes, doses, and times before a comprehensive and scientific conclusion can be reached to ensure the safety of personnel and the environment.
What are the relevant market information for 4- [2- (5-chloro-2-methoxy-benzamide) ethyl] -benzenesulfonamide?
Today, there is a question about the market information related to 4- [2- (5-hydroxy- 2-methoxy-benzylpropionic acid) ethyl] -benzylpropionic acid? Let me explain in detail.
Benzylpropionic acid is often a key raw material in the field of organic synthesis. In the pharmaceutical industry, the preparation of many drugs depends on its participation in the reaction. For some drugs with anti-inflammatory and analgesic effects, benzylpropionic acid is indispensable in its synthesis path. This is because of its unique chemical structure, which can endow drugs with specific activities and properties, so the pharmaceutical market has a great demand for benzylpropionic acid.
Furthermore, in the fragrance industry, benzylpropionic acid also has its place. It can be used as an intermediate in fragrance synthesis to help flavors prepare unique aromas. Benzylpropionic acid can be seen in the formulas of many high-end perfumes and fragrances. With the increase in demand for high-quality fragrances, the prospect of benzylpropionic acid in the fragrance market is also quite promising.
In terms of market supply, there are many manufacturers producing benzylpropionic acid, and the competition is quite fierce. However, high-quality products are often more popular because they can meet the strict requirements of high-end customers for purity and quality. In terms of market prices, they fluctuate due to fluctuations in raw material prices, the complexity of production processes, and the relationship between market supply and demand.
In addition, the improvement of environmental protection requirements also has an impact on the production of benzylpropionic acid. Manufacturers need to continuously optimize their processes to meet environmental standards, which may also lead to changes in the market landscape. In short, the market information related to benzylpropionic acid is complex, involving many aspects such as multi-industry demand, supply competition, price fluctuations and environmental protection policies. It is necessary to pay close attention in order to seize business opportunities.
Benzylpropionic acid is often a key raw material in the field of organic synthesis. In the pharmaceutical industry, the preparation of many drugs depends on its participation in the reaction. For some drugs with anti-inflammatory and analgesic effects, benzylpropionic acid is indispensable in its synthesis path. This is because of its unique chemical structure, which can endow drugs with specific activities and properties, so the pharmaceutical market has a great demand for benzylpropionic acid.
Furthermore, in the fragrance industry, benzylpropionic acid also has its place. It can be used as an intermediate in fragrance synthesis to help flavors prepare unique aromas. Benzylpropionic acid can be seen in the formulas of many high-end perfumes and fragrances. With the increase in demand for high-quality fragrances, the prospect of benzylpropionic acid in the fragrance market is also quite promising.
In terms of market supply, there are many manufacturers producing benzylpropionic acid, and the competition is quite fierce. However, high-quality products are often more popular because they can meet the strict requirements of high-end customers for purity and quality. In terms of market prices, they fluctuate due to fluctuations in raw material prices, the complexity of production processes, and the relationship between market supply and demand.
In addition, the improvement of environmental protection requirements also has an impact on the production of benzylpropionic acid. Manufacturers need to continuously optimize their processes to meet environmental standards, which may also lead to changes in the market landscape. In short, the market information related to benzylpropionic acid is complex, involving many aspects such as multi-industry demand, supply competition, price fluctuations and environmental protection policies. It is necessary to pay close attention in order to seize business opportunities.
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