2,6-bis[(4R)-4-(propan-2-yl)-4,5-dihydro-1,3-oxazol-2-yl]pyridine

This is a compound of 2,6-bis [ (4R) -4 - (isopropyl) -4,5-dihydro-1,3-oxazole-2-yl] pyridine. Looking at its name, the summary of its chemical structure can be known. "2,6-bis" shows that there is the same substituent at the 2nd and 6th positions of the pyridine ring. "[ (4R) -4 - (isopropyl) -4,5-dihydro-1,3-oxazole-2-yl]", this is a specific substituent structure.
Wherein, " (4R) " indicates that the 4-position carbon atom of the oxazole ring has the R configuration, which is a sign of stereochemistry and relates to the spatial arrangement of molecules. "4- (isopropyl) ", indicating that the 4-position is connected to isopropyl, which is a branched alkyl group containing three carbon atoms. "4,5-dihydro" refers to the hydrogenation of the 4 and 5 double bonds of the oxazole ring to form a structure with a low degree of unsaturation. " The oxazole ring is a five-membered heterocyclic ring containing one oxygen atom and one nitrogen atom, and the 2-group is connected to the pyridine ring at the second position of the oxazole ring.
The pyridine ring is a six-membered nitrogen-containing heterocyclic ring with stable properties. 2,6-bis [ (4R) -4 - (isopropyl) -4,5-dihydro-1,3-oxazole-2-yl] pyridine may have important uses in organic synthesis, medicinal chemistry and other fields due to its specific structure or unique physical and chemical properties. Its structure is exquisitely designed, and its components interact to affect the overall characteristics of the molecule.

2% 2C6 - bis% 5B% 284R% 29 - 4 -% 28propan - 2 - yl% 29 - 4% 2C5 - dihydro - 1% 2C3 - oxazol - 2 - yl% 5Dpyridine, an organic compound, often with its unique chemical structure, plays a key role in many fields.
In the field of medicinal chemistry, it is often used as an intermediate for drug development. Because the molecule contains a specific nitrogen heterocyclic structure, it can interact with specific targets in organisms. Many drug molecular designs, with the help of the structure of this compound, are chemically modified to obtain drugs with specific biological activities, or have antibacterial, anti-inflammatory, anti-tumor and other effects, helping humans to conquer various diseases.
In the field of materials science, this compound has also attracted much attention. Due to its structural properties, it may participate in material synthesis and endow materials with special properties. For example, in the preparation of polymer materials, the introduction of this compound structural unit may improve the optical and electrical properties of materials, providing the possibility for the creation of new functional materials, which are used in cutting-edge fields such as electronic devices and optical displays.
In the field of organic synthetic chemistry, it is an important synthetic building block. Chemists use various organic synthesis methods to construct more complex organic molecular structures according to their structural characteristics. With its unique reactivity, it participates in various reactions such as cyclization and coupling, expands the structural diversity of organic compounds, and promotes the progress and development of organic synthetic chemistry.
In summary, 2% 2C6 - bis% 5B% 284R% 29 - 4 -% 28propan - 2 - yl% 29 - 4% 2C5 - dihydro - 1% 2C3 - oxazol - 2 - yl% 5Dpyridine has shown important application value in the fields of medicine, materials, and organic synthesis, contributing to the innovation and development of various fields.

To prepare 2,6-bis [ (4R) -4- (isopropyl) -4,5-dihydro-1,3-oxazole-2-yl] pyridine, there are many methods, and each has its advantages and disadvantages.
First, a compound containing a pyridine structure is used as the starting material, and the 2,6 positions of the pyridine ring are introduced into a specific group through a specific reaction. This path requires fine regulation of the reaction conditions to ensure the accuracy of the introduction of the group, and the purity and activity of the starting material have a great influence on the reaction. Severe temperature, pressure and catalyst conditions may be required during the reaction. If improper control is made, the yield and purity of the product will be affected.
Second, the oxazole ring structure can be constructed first, and then it can be linked to the pyridine derivative. When constructing the oxazole ring, attention should be paid to the control of stereochemistry to obtain the desired (4R) configuration. The linking step also needs to select appropriate reactions and reagents to ensure the accuracy of the connection check point and the stability of the product configuration.
Third, a stepwise synthesis strategy is adopted, and the intermediate containing part of the structure is first synthesized, and then combined by multi-step reaction. Although this strategy is complicated, each step of the reaction can be finely optimized, which is beneficial to improve the overall synthesis efficiency and product quality. However, the multi-step reaction is complicated, and the total yield may be affected, and the intermediate needs to be strictly separated and purified in each step. In conclusion, the synthesis of this compound requires comprehensive consideration of factors such as the availability of raw materials, the difficulty of reaction conditions, cost-effectiveness, and product quality, and careful selection of synthesis methods to obtain satisfactory results.

2% 2C6 - bis% 5B% 284R% 29 - 4 -% 28propan - 2 - yl% 29 - 4% 2C5 - dihydro - 1% 2C3 - oxazol - 2 - yl% 5Dpyridine, this is an organic compound whose physical properties are of great research value.
Looking at its morphology, it is mostly a stable solid at room temperature and pressure. Due to the strong intermolecular forces, it has a certain lattice structure. Its color is often white or off-white, and when the purity is very high, the color is more white.
When it comes to the melting point, after many experiments, it is found that it is about a specific temperature range. This temperature reflects the energy required for the molecule to break free from the lattice binding, which is one of the important characteristics of the compound.
In terms of solubility, it shows a certain solubility in common organic solvents, such as some alcohols and ethers. This is due to the specific interaction between the molecular structure of the compound and the organic solvent molecules, such as van der Waals force, hydrogen bond, etc. However, the solubility in water is poor, because the hydrophobic group of the compound dominates, and the force on the water molecule is weak.
density is also one of its physical properties. It can be known by accurate measurement methods that it has a specific value. This value is of great significance for considering its distribution and behavior in different systems. In addition, the compound has good stability and is not prone to decomposition or other chemical reactions under normal environmental conditions. This is due to the stability of its molecular structure and relatively high chemical bond energy, which is sufficient to resist the influence of common environmental factors.

I don't know the price range of 2,6 - bis [ (4R) -4- (propan - 2 - yl) -4,5 - dihydro - 1,3 - oxazol - 2 - yl] pyridine in the market. This is a more professional chemical substance, and its price varies depending on many factors such as quality, purity, supplier, purchase volume, and market supply and demand. For the exact price range, you can consult chemical product suppliers, chemical reagent sales platforms, such as Sinopharm Group Chemical Reagent Co., Ltd., search banner reagent network, etc., or explore relevant information on chemical industry trading websites, or consult chemical industry professionals and scientific research institutions. It may be distinguished by scientific research grade, industrial grade, etc. due to different uses, and the prices of each grade are also different. Therefore, it is difficult to determine its market price range based on the name of this object alone.