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What is the chemical structure of this product 1- [2- (2,4-dichlorophenyl) -2- {[4- (phenylthio) benzyl] oxy} ethyl] -1H-imidazole?
This is a question about the chemical structure of a specific compound. The compound is named 1- [2- (2,4-difluorophenyl) -2 - {[4- (benzenesulfonyl) piperazinyl] oxy} ethyl] -1H-pyrazole. To clarify its chemical structure, each part needs to be dissected one by one.
"1H-pyrazole" is the core parent nucleus of the compound. Pyrazole is a five-membered heterocycle containing two adjacent nitrogen atoms, and 1H - represents a hydrogen atom attached to a nitrogen atom.
"1 - [2 - (2,4 - difluorophenyl) -2 - {[4 - (benzenesulfonyl) piperazinyl] oxy} ethyl]" is a substituent attached to the 1 position of pyrazole. Where "2 - (2,4 - difluorophenyl) " means that there is a 2,4 - difluorophenyl group attached to the 2 position of an ethyl group. The 2 and 4 positions of the 2,4 - difluorophenyl ring are replaced by fluorine atoms. " 2 - {[4- (benzenesulfonyl) piperazinyl] oxy} "indicates that the second position of the ethyl group also has a structure connected by an oxygen atom, which is 4- (benzenesulfonyl) piperazinyl. Piperazine is a six-membered heterocyclic ring containing two nitrogen atoms, 4- (benzenesulfonyl) piperazinyl, that is, the fourth position of the piperazine ring is connected with benzenesulfonyl, and benzenesulfonyl is a benzenesulfonyl ring linked sulfonyl group (-SO ₂ - ) 。
In general, this compound takes 1H-pyrazole as the core and connects a complex substituent at 1 position. The substituent is composed of fluorophenyl, piperazinyl and benzenesulfonyl groups through specific connection methods, showing a unique chemical structure.
What are the main physical properties of 1- [2- (2,4-dichlorophenyl) -2- {[4- (phenylthio) benzyl] oxy} ethyl] -1H-imidazole?
1 - [2 - (2,4 -dihydroxyphenyl) - 2 - {[4 - (silicon carboxyl) urea] oxy} ethyl] -1H -imidazole The main physical properties of this compound are described in the "Tiangong", but the characteristics and common sense of the compound can be deduced.
This compound contains a poly-group, in which the presence of a poly-group such as a poly-group and an oxygen group makes it or has a certain solubility in the solution. To a common sense, containing this poly-group, the molecular force is acting, and the poly-group can cause the formation of molecules, etc., or cause the substance to melt and boil.
and the aromatic part is contained in it, and the common properties of aromatics can affect its optical properties, or make this substance have absorption properties in a specific optical domain. And because it contains many atoms and radicals, its chemical properties or activity can be changed and reversed. However, this is based on the deduction of the chemical principle.
As long as it has physical properties, such as melting, boiling, density, solubility, etc., it needs to be refined. "Tiangong" re-engineering and production, the properties of such refined substances can be determined, and the properties of such refined substances can be reached. However, with the current transformation, it can be known from the clues of their initial physical properties.
In which fields is 1- [2- (2,4-dichlorophenyl) -2- {[4- (phenylthio) benzyl] oxy} ethyl] -1H-imidazole used?
1 - [2 - (2,4 - dihydroxyphenyl) - 2 - {[4 - (phenyl) urea] oxy} ethyl] -1H - imidazole This compound is used in the field of medicine and can be used as a pharmaceutical active ingredient to participate in disease treatment, such as the development of anti-cancer drugs, which combine with specific targets of cancer cells by virtue of their structure to hinder the proliferation of cancer cells; in the field of materials science, or can be used to prepare special performance materials, such as materials with high stability or special optical and electrical properties, through their special structure to react or interact with other substances; in the field of agriculture, or can be developed as a new type of pesticide or plant growth regulator to regulate plant growth and development or resist pests and diseases.
This compound has a unique structure, and its dihydroxyphenyl, urea, imidazole and other groups give it a variety of reactivity and characteristics. In the field of medicine, due to in-depth research on the mechanism of action of cancer cells, scientists hope to use this compound to develop targeted anti-cancer drugs and find new ways for cancer treatment; in materials science, researchers value its structural advantages and explore the synthesis of unique performance materials to meet the needs of electronics, optics and other fields; in agriculture, according to plant physiological characteristics and pest control needs, try to develop suitable agricultural products. This shows that this compound has potential application value in many fields, and with in-depth research, it is expected to bring more breakthroughs and innovations.
What is the preparation method of 1- [2- (2,4-dichlorophenyl) -2- {[4- (phenylthio) benzyl] oxy} ethyl] -1H-imidazole?
The preparation method of 1 - [2 - (2,4 - dihydroxyphenyl) - 2 - {[4 - (phenyl) urea] oxy} ethyl] - 1H - imidazole is a rather complicated chemical process. The preparation method needs to follow specific steps and conditions.
At the beginning, when carefully selecting suitable raw materials. It is necessary to use a compound containing 2,4 - dihydroxyphenyl as the starting material, and this compound needs to have a high purity to ensure the smooth progress of the subsequent reaction. In combination with it, it is necessary to choose a reagent containing phenyl urea group. The structure and reactivity of this reagent have a profound impact on the overall reaction trend.
Then, in a suitable reaction vessel, add an appropriate amount of solvent. This solvent needs to be able to dissolve the reactants well and not interfere with the progress of the reaction. Common organic solvents, such as dichloromethane, N, N-dimethylformamide, etc., may be screened and used by experiments.
Then, the reaction temperature and time need to be precisely controlled. The reaction temperature may need to be maintained in a specific range. For example, when the reaction is low temperature, the reaction can be started slowly and orderly. After the reaction is stable, it may need to be moderately heated to speed up the reaction process. The control of the reaction time is also very critical. If it is too short, the reaction will not be fully functional, and if it is too long, it may cause side reactions, which will affect the purity and yield of the product. < Br >
In the reaction process, a specific catalyst may be added. This catalyst can significantly reduce the activation energy of the reaction and accelerate the reaction rate. However, the amount of catalyst needs to be accurately weighed, and too much or too little is not conducive to the efficient progress of the reaction.
After the reaction is completed, a series of separation and purification steps are required. Extraction, column chromatography and other methods can be used to remove unreacted raw materials, by-products and impurities to obtain high-purity 1- [2- (2,4-dihydroxyphenyl) -2 - {[4- (phenyl) urea] oxy} ethyl] -1H -imidazole products. This preparation method requires fine operation and strict control of each link in order to achieve the ideal preparation effect.
What is the market prospect of 1- [2- (2,4-dichlorophenyl) -2- {[4- (phenylthio) benzyl] oxy} ethyl] -1H-imidazole?
There are currently 1- [2- (2,4-dihydroxyphenyl) -2- {[4- (phenyl) amino] carbonyl} ethyl] -1H-pyrazole, which is a specific chemical substance. The analysis of its market prospects should be viewed from the perspective of polyend.
Looking at the pharmaceutical field, such compounds containing specific groups may have unique biological activities. Structures such as 2,4-dihydroxyphenyl and pyrazole rings can be combined with specific targets in vivo, in drug development, or can provide opportunities for the creation of new therapeutic drugs. For example, the development of anti-inflammatory, anti-tumor and other drugs, if they can demonstrate good pharmacological activity and safety, the market demand may be considerable. The current pharmaceutical industry is very thirsty for innovative drugs. If this compound can become an effective therapeutic agent through in-depth research and development, it can win a place in the pharmaceutical market.
In the field of materials, the special structure of the compound may endow it with special physical and chemical properties. For example, in photoelectric materials, or due to the existence of pyrazole rings and related substituents, it presents unique optical and electrical properties, and may have applications in the development of Light Organic Emitting Diode (OLED), solar cells and other materials. With the vigorous development of the electronic information industry, the demand for high-performance materials is increasing day by day. If this compound can meet the material performance requirements, it can also open up a market.
However, the expansion of its market also faces various challenges. The optimization of the synthesis process is extremely critical. If high-efficiency and low-cost synthesis cannot be achieved, large-scale production is limited, and it is difficult to widely promote the market. And in the field of medicine, strict clinical trial requirements require a lot of manpower, material resources and time to prove its safety and effectiveness. The field of materials also needs to deal with issues such as compatibility with other materials.
In conclusion, 1 - [2 - (2,4 -dihydroxyphenyl) -2 - {[4 - (phenyl) amino] carbonyl} ethyl] -1H -pyrazole has potential market prospects, but in order to successfully establish a foothold in the market, many technical and regulatory difficulties need to be overcome.
