Linshang Chemical
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4-((5-Chloro-2-Methoxybenzamido)Ethyl)Benzenesulfonamide
Linshang Chemical
|
HS Code |
917823 |
| Chemical Formula | C16H19ClN2O5S |
| Molecular Weight | 386.85 |
| Appearance | Solid (predicted) |
| Boiling Point | 625.4°C at 760 mmHg (predicted) |
| Melting Point | 163 - 165°C |
| Logp | 2.35 (predicted) |
| Solubility | Soluble in DMSO (Slightly), Methanol (Slightly) |
| Pka | 10.29±0.20 (Predicted) |
| Flash Point | 332.0°C (predicted) |
| Density | 1.355±0.06 g/cm³ (20 °C, 760 mmHg) (predicted) |
As an accredited 4-((5-Chloro-2-Methoxybenzamido)Ethyl)Benzenesulfonamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram vial of 4-((5 - chloro - 2 - methoxybenzamido)ethyl)benzenesulfonamide, well - sealed. |
| Storage | Store 4-((5 - chloro - 2 - methoxybenzamido)ethyl)benzenesulfonamide in a cool, dry place, away from heat sources and direct sunlight. Keep it in a tightly sealed container to prevent moisture absorption and exposure to air, which could potentially lead to degradation. Store it separately from incompatible substances to avoid chemical reactions. |
| Shipping | Ship 4-((5 - chloro - 2 - methoxybenzamido)ethyl)benzenesulfonamide in properly labeled, sealed containers. Ensure compliance with chemical shipping regulations, using appropriate packaging to prevent spillage during transit. |
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What is the chemical structure of 4- ((5-chloro-2-methoxybenzamido) ethyl) benzenesulfonamide?
To know the chemical structure of 4 - ((5 - tritium - 2 - methoxybenzylpropanyl) ethyl) benzyloxypropane, we shall analyze it in detail. The analysis of the chemical structure of
requires the clarification of the characteristics and connection methods of each group. In this compound, "benzyloxypropane" is a structure in which benzyl is connected to oxygen atoms and then to propanyl. Benzyl, phenylmethyl, is also aromatic; propanyl contains carbon-carbon triple bonds and is active.
" (5-tritium-2-methoxybenzylpropynyl) " part, with tritium atom substitution at the 5th position, methoxy group at the 2nd position, and connected to benzyl and propynyl groups. Tritium is an isotope of hydrogen and is radioactive; methoxy is a power supply group, which affects the electron cloud distribution and reactivity of the molecule.
And " ((5-tritium-2-methoxybenzylpropynyl) ethyl) ", indicating that ethyl is connected to the above complex group. Ethyl is a saturated alkyl group and is relatively stable.
Finally, the overall structure is 4- ((5-tritium-2-methoxybenzylpropanyl) ethyl) benzyloxy propane, which means that the groups of the above combination are substituted at the 4 position of benzyloxy propane. In this way, the interaction of each group together determines the chemical and physical properties of this compound. The uniqueness of its structure may make it show special uses and reactivity in the fields of organic synthesis, medicinal chemistry, etc.
requires the clarification of the characteristics and connection methods of each group. In this compound, "benzyloxypropane" is a structure in which benzyl is connected to oxygen atoms and then to propanyl. Benzyl, phenylmethyl, is also aromatic; propanyl contains carbon-carbon triple bonds and is active.
" (5-tritium-2-methoxybenzylpropynyl) " part, with tritium atom substitution at the 5th position, methoxy group at the 2nd position, and connected to benzyl and propynyl groups. Tritium is an isotope of hydrogen and is radioactive; methoxy is a power supply group, which affects the electron cloud distribution and reactivity of the molecule.
And " ((5-tritium-2-methoxybenzylpropynyl) ethyl) ", indicating that ethyl is connected to the above complex group. Ethyl is a saturated alkyl group and is relatively stable.
Finally, the overall structure is 4- ((5-tritium-2-methoxybenzylpropanyl) ethyl) benzyloxy propane, which means that the groups of the above combination are substituted at the 4 position of benzyloxy propane. In this way, the interaction of each group together determines the chemical and physical properties of this compound. The uniqueness of its structure may make it show special uses and reactivity in the fields of organic synthesis, medicinal chemistry, etc.
What are the main uses of 4- ((5-chloro-2-methoxybenzamido) ethyl) benzenesulfonamide?
4- ((5-alkane-2-methoxybenzylacetyl) ethyl) benzylacetaldehyde, this compound has a variety of uses in different fields:
In the field of medicinal chemistry, its structural properties make it possible to become a key intermediate for the development of new drugs. Medicinal chemists can use its specific functional groups to modify, transform and connect different pharmacoactive groups through a series of organic synthesis reactions to develop drugs with specific physiological activities, such as inhibitors or modulators for certain disease targets, providing potential drug options for the treatment of difficult diseases.
In the field of materials science, due to its unique molecular structure, or with special optical, electrical or thermal properties. For example, it may be used as a basic unit for constructing new photoelectric materials. After rational design and assembly, it can be used in optoelectronic devices such as organic Light Emitting Diodes (OLEDs) and solar cells to improve the performance and efficiency of the devices.
In organic synthetic chemistry, it is an extremely important synthetic building block. Organic chemists use its rich reaction check points to carry out various classical organic reactions, such as nucleophilic substitution, addition reactions, etc., to construct more complex and diverse organic molecular structures, providing a material basis and structural template for the development and innovation of organic synthetic chemistry, and promoting organic synthetic chemistry to new heights.
In the field of medicinal chemistry, its structural properties make it possible to become a key intermediate for the development of new drugs. Medicinal chemists can use its specific functional groups to modify, transform and connect different pharmacoactive groups through a series of organic synthesis reactions to develop drugs with specific physiological activities, such as inhibitors or modulators for certain disease targets, providing potential drug options for the treatment of difficult diseases.
In the field of materials science, due to its unique molecular structure, or with special optical, electrical or thermal properties. For example, it may be used as a basic unit for constructing new photoelectric materials. After rational design and assembly, it can be used in optoelectronic devices such as organic Light Emitting Diodes (OLEDs) and solar cells to improve the performance and efficiency of the devices.
In organic synthetic chemistry, it is an extremely important synthetic building block. Organic chemists use its rich reaction check points to carry out various classical organic reactions, such as nucleophilic substitution, addition reactions, etc., to construct more complex and diverse organic molecular structures, providing a material basis and structural template for the development and innovation of organic synthetic chemistry, and promoting organic synthetic chemistry to new heights.
What is the preparation method of 4- ((5-chloro-2-methoxybenzamido) ethyl) benzenesulfonamide?
To prepare 4- ((5-tritium-2-methoxybenzyl) ethyl) benzoxybenzoic acid, the method is as follows:
First take an appropriate amount of 5-tritium-2-methoxybenzaldehyde, place it in a clean reactor, add an appropriate amount of ethylamine and a suitable catalyst, and control the temperature within a certain range to promote its condensation reaction. After the reaction is completed, the 5-tritium-2-methoxybenzylethylamine intermediate is obtained by purification.
Then the intermediate and the appropriate derivative of benzyloxybenzoic acid are co-placed in another reaction vessel, an appropriate amount of acid binding agent and phase transfer catalyst are added, and the temperature is raised and maintained at a specific temperature range to cause the substitution reaction between the two. During this period, the reaction process needs to be closely monitored and the reaction conditions adjusted in a timely manner.
After the reaction is completed, it is processed through multiple post-treatment steps such as extraction, washing, and drying to remove impurities. Then the pure 4- ((5-tritium-2-methoxybenzyl) ethyl) benzyloxybenzoic acid product can be obtained by column chromatography or recrystallization. During the operation, it is necessary to strictly abide by safety procedures, pay attention to protection, and properly dispose of waste due to the radioactivity of tritium to avoid environmental pollution.
First take an appropriate amount of 5-tritium-2-methoxybenzaldehyde, place it in a clean reactor, add an appropriate amount of ethylamine and a suitable catalyst, and control the temperature within a certain range to promote its condensation reaction. After the reaction is completed, the 5-tritium-2-methoxybenzylethylamine intermediate is obtained by purification.
Then the intermediate and the appropriate derivative of benzyloxybenzoic acid are co-placed in another reaction vessel, an appropriate amount of acid binding agent and phase transfer catalyst are added, and the temperature is raised and maintained at a specific temperature range to cause the substitution reaction between the two. During this period, the reaction process needs to be closely monitored and the reaction conditions adjusted in a timely manner.
After the reaction is completed, it is processed through multiple post-treatment steps such as extraction, washing, and drying to remove impurities. Then the pure 4- ((5-tritium-2-methoxybenzyl) ethyl) benzyloxybenzoic acid product can be obtained by column chromatography or recrystallization. During the operation, it is necessary to strictly abide by safety procedures, pay attention to protection, and properly dispose of waste due to the radioactivity of tritium to avoid environmental pollution.
How safe is 4- ((5-chloro-2-methoxybenzamido) ethyl) benzenesulfonamide?
4- ((5-alkane-2-methoxybenzylbenzoyl) ethyl) benzoylbenzoic acid, the safety of this substance is quite complex and needs to be studied in many ways.
Looking at its chemical structure, this is an organic compound composed of many specific groups in an orderly combination. The methoxy group, benzyl group, benzoyl group and other parts contained in it may endow it with specific chemical activities and physical properties.
In terms of toxicity, the specific toxicity data of this compound may vary depending on the experimental samples, test methods and objects. In animal experiments, it may affect some physiological systems of the tested animals, for example, after oral ingestion, or affect the normal operation of the digestive system, causing symptoms such as gastrointestinal discomfort and malabsorption; if exposed to the skin, or due to skin absorption caused by local irritation, such as redness, itching, or even more serious allergic reactions.
In terms of its stability, under different environmental conditions, the stability of this compound varies. In the environment of normal temperature and pressure without the interference of special chemical reagents, it may be able to maintain a relatively stable state. However, in case of high temperature, strong oxidants or reducing agents, it may trigger chemical reactions, causing it to decompose or convert into other substances. In this process, the new substances generated may have very different toxicity and danger.
From the perspective of environmental impact, if this compound enters the natural environment and is transmitted through water, soil or atmosphere, its degradation process may be extremely slow. Due to its complex chemical structure, it is difficult for microorganisms to decompose it, or it may remain in the environment for a long time, which may pose a potential threat to the ecosystem. It may affect the balance of soil microbial communities, or pose a hazard to the survival and reproduction of aquatic organisms, and disrupt the normal operation of the ecological chain.
In summary, the safety of 4- ((5-alkane-2-methoxybenzylbenzoyl) ethyl) benzoylbenzoic acid requires comprehensive and meticulous research to accurately determine, when using and handling this compound, it is necessary to take comprehensive protective measures to avoid latent risks.
Looking at its chemical structure, this is an organic compound composed of many specific groups in an orderly combination. The methoxy group, benzyl group, benzoyl group and other parts contained in it may endow it with specific chemical activities and physical properties.
In terms of toxicity, the specific toxicity data of this compound may vary depending on the experimental samples, test methods and objects. In animal experiments, it may affect some physiological systems of the tested animals, for example, after oral ingestion, or affect the normal operation of the digestive system, causing symptoms such as gastrointestinal discomfort and malabsorption; if exposed to the skin, or due to skin absorption caused by local irritation, such as redness, itching, or even more serious allergic reactions.
In terms of its stability, under different environmental conditions, the stability of this compound varies. In the environment of normal temperature and pressure without the interference of special chemical reagents, it may be able to maintain a relatively stable state. However, in case of high temperature, strong oxidants or reducing agents, it may trigger chemical reactions, causing it to decompose or convert into other substances. In this process, the new substances generated may have very different toxicity and danger.
From the perspective of environmental impact, if this compound enters the natural environment and is transmitted through water, soil or atmosphere, its degradation process may be extremely slow. Due to its complex chemical structure, it is difficult for microorganisms to decompose it, or it may remain in the environment for a long time, which may pose a potential threat to the ecosystem. It may affect the balance of soil microbial communities, or pose a hazard to the survival and reproduction of aquatic organisms, and disrupt the normal operation of the ecological chain.
In summary, the safety of 4- ((5-alkane-2-methoxybenzylbenzoyl) ethyl) benzoylbenzoic acid requires comprehensive and meticulous research to accurately determine, when using and handling this compound, it is necessary to take comprehensive protective measures to avoid latent risks.
What are the market prospects for 4- ((5-chloro-2-methoxybenzamido) ethyl) benzenesulfonamide?
4- ((5-tritium-2-methoxybenzylformamido) ethyl) benzylamide, an extremely complex and specialized organic compound. In terms of market prospects, the cover can be viewed from the following aspects:
First, the field of medicine. Today's pharmaceutical research and development often focuses on novel organic compounds to find potential therapeutic targets and drug active ingredients. If this compound can exhibit unique biological activities after rigorous pharmacological research, such as inhibitory or therapeutic effects on specific diseases, or can be used as an intermediate in drug synthesis, laying the foundation for the preparation of more efficient and low-toxicity drugs, it will have broad prospects in the pharmaceutical market. However, the road to pharmaceutical research and development is long, and it must go through strict clinical trials and approval procedures before it can be successfully launched. This process is time-consuming and costly.
Second, the chemical industry. If the compound has special physical and chemical properties, such as excellent stability, reactivity, etc., it can be used as a special auxiliary agent or catalyst in fine chemical production, or participate in the synthesis of specific materials to help improve the properties of materials. The chemical industry has a constant demand for new compounds. If it can meet the needs of the industry, it is also expected to be recognized by the market.
Third, scientific research purposes. In academic research institutions, such complex compounds may be the research objects in the fields of organic synthetic chemistry, medicinal chemistry, etc., to explore new synthesis methods and reaction mechanisms. If its structure is unique, it can provide new ideas and directions for scientific research. Although the dosage may not be as high as industrial production, it also has a place in the scientific research reagent market.
However, its marketing activities also face challenges. The synthesis cost of complex compounds may be high, and the synthesis process must be optimized to reduce costs and enhance market competitiveness. And it will take time for the market to recognize and accept it. It is necessary to make practitioners in related fields aware of its potential value through academic exchanges, product promotion and other measures.
First, the field of medicine. Today's pharmaceutical research and development often focuses on novel organic compounds to find potential therapeutic targets and drug active ingredients. If this compound can exhibit unique biological activities after rigorous pharmacological research, such as inhibitory or therapeutic effects on specific diseases, or can be used as an intermediate in drug synthesis, laying the foundation for the preparation of more efficient and low-toxicity drugs, it will have broad prospects in the pharmaceutical market. However, the road to pharmaceutical research and development is long, and it must go through strict clinical trials and approval procedures before it can be successfully launched. This process is time-consuming and costly.
Second, the chemical industry. If the compound has special physical and chemical properties, such as excellent stability, reactivity, etc., it can be used as a special auxiliary agent or catalyst in fine chemical production, or participate in the synthesis of specific materials to help improve the properties of materials. The chemical industry has a constant demand for new compounds. If it can meet the needs of the industry, it is also expected to be recognized by the market.
Third, scientific research purposes. In academic research institutions, such complex compounds may be the research objects in the fields of organic synthetic chemistry, medicinal chemistry, etc., to explore new synthesis methods and reaction mechanisms. If its structure is unique, it can provide new ideas and directions for scientific research. Although the dosage may not be as high as industrial production, it also has a place in the scientific research reagent market.
However, its marketing activities also face challenges. The synthesis cost of complex compounds may be high, and the synthesis process must be optimized to reduce costs and enhance market competitiveness. And it will take time for the market to recognize and accept it. It is necessary to make practitioners in related fields aware of its potential value through academic exchanges, product promotion and other measures.
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