2-(METHYLSULFANYL)[1,3]OXAZOLO[4,5-B]PYRIDINE

2-%28METHYLSULFANYL%29%5B1%2C3%5DOXAZOLO%5B4%2C5-B%5DPYRIDINE, this is an organic compound, the Chinese name may be 2 - (methylthio) [1,3] oxazolo [4,5 - b] pyridine. Its main uses are quite wide, in the field of medicinal chemistry, often used as a key intermediate in drug synthesis. Due to its unique chemical structure, it can be linked to other compounds through specific chemical reactions to construct drug molecules with specific biological activities, or can be used to develop therapeutic drugs for specific diseases.
It also has important applications in the field of materials science. Because of its structural properties, it may endow materials with special electrical, optical or mechanical properties. For example, in the field of organic photoelectric materials, rational design and modification may improve the photoelectric conversion efficiency of materials for the preparation of high-efficiency solar cells, Light Emitting Diode and other photoelectric devices.
Furthermore, it also has potential value in pesticide chemistry. Or it can be used as a structural unit of pesticide active ingredients. After optimization design, a new type of pesticide with high efficiency, low toxicity and environmental friendliness can be developed to help agricultural pest control and ensure crop yield and quality. In short, 2 - (methylthio) [1,3] oxazolo [4,5 - b] pyridine has shown important uses and broad application prospects in many fields such as medicine, materials and pesticides due to its unique chemical structure.

To prepare 2 - (methylthio) [1,3] oxazolo [4,5 - B] pyridine, you can do it numerically. One is to use [1,3] oxazolo [4,5 - B] pyridine as a group to react with reagents containing methylthio groups. In this process, the reaction conditions, such as temperature, solvent and catalyst, need to be carefully selected. Appropriate temperature or in a specific range, and when the selected solvent can accommodate the reactants and do not initiate side reactions, the catalyst can promote the reaction quickly.
Second, the oxazole ring and methylthio group can be gradually introduced through a series of reactions starting from pyridine compounds. This approach may involve multiple steps of transformation, each step needs to be precisely controlled. First, the specific position of the pyridine is functionalized, and then the oxazole ring is formed by cyclization reaction, and then the methyl thio group is introduced. Each step of the reaction needs to select the appropriate reaction reagents and conditions according to the nature and reaction mechanism of the reactants.
Or it can be started from other related heterocyclic compounds and appropriately modified to reach the target product. Therefore, it is necessary to study the reactivity and transformation laws of each heterocyclic ring in detail, and design a reasonable synthesis route. It may involve many reaction types such as substitution, addition, and elimination, and the yield and selectivity of each step are related to the success or failure of the final synthesis. In conclusion, the synthesis of 2 - (methylthio) [1,3] oxazolo [4,5 - B] pyridine requires a comprehensive review of the advantages and disadvantages of each method, and the optimal method should be selected according to the existing raw materials, experimental conditions and cost considerations.

2 - (methylthio) [1,3] oxazolo [4,5 - B] pyridine, this substance is an organic compound, its physical and chemical properties are quite critical, and it is related to many fields of application.
When it comes to physical properties, under normal temperature and pressure, it is mostly in solid form, due to the intermolecular force. Looking at its color, it is often white or off-white, but it may vary slightly due to the influence of impurities. Its melting point or in a specific temperature range is a key indicator for identification. Due to the structure, the molecules are arranged in an orderly manner, and a certain amount of energy is required to destroy the lattice and realize the phase transition. The boiling point also has a specific value, reflecting the energy required for gasification, which is closely related to the intermolecular force.
In terms of solubility, it may have different performances in organic solvents. Because of its sulfur and nitrogen heterocyclic structure, it has a certain polarity, and it may have good solubility in polar organic solvents such as dichloromethane and N, N-dimethylformamide, which is conducive to synthesis and reaction operation. The solubility in water is poor or poor, because the force between water and the compound is weak, it is difficult to overcome the intermolecular force to disperse it.
Talking about chemical properties, the sulfur atoms in this compound are rich in electrons, easy to form nucleophilic centers, and participate in nucleophilic substitution reactions. If reacted with halogenated hydrocarbons, sulfur atoms can attack the positive center of halogenated hydrocarbons and form new carbon-sulfur bonds to achieve structural modification. The oxazolopyridine ring is aromatic and stable, and can also participate in electrophilic substitution reactions. Under specific conditions, the electron cloud density distribution on the ring affects the reaction check point, and can introduce different functional groups to expand chemical properties and applications.
Nitrogen atoms also have potential reactivity, can bind with protons as basic, or participate in coordination chemistry to form complexes with metal ions, and may have applications in catalysis and materials science. This compound has rich chemical properties and provides broad space for organic synthesis and related research.

I look at the "2- (METHYLSULFANYL) [1,3] OXAZOLO [4,5 - B] PYRIDINE" you are asking about, which is a chemical substance. However, in the modern market, its price range is difficult to say exactly. Because the price is often affected by many factors, it is difficult to generalize.
First, the cost of production is the key. The difficulty of obtaining raw materials and the simplicity of the refining process all affect the cost. If the raw materials are rare and difficult to find, or the refining requires exquisite and complex methods, the cost will be high, and the price will also rise.
Second, the supply and demand situation of the market also has a great impact. If there is a strong demand for this product at a certain time and a place, but the supply is limited, the price will rise; conversely, if the supply is abundant and the demand is limited, the price may decline.
Third, the purity of the preparation also affects the price. High-purity products are difficult to prepare and have high process requirements, and the price is naturally higher than that of low-purity products.
Fourth, regional differences cannot be ignored. In different places, prices will also fluctuate due to different transportation costs and market environments.
Therefore, in order to know the exact price range of this product, it is necessary to check the chemical product trading platform in detail, consult professional chemical traders or relevant manufacturers, and obtain accurate numbers.

2-%28METHYLSULFANYL%29%5B1%2C3%5DOXAZOLO%5B4%2C5-B%5DPYRIDINE, this is the chemical name of an organic compound, which is solved by modern chemical terms, namely 2- (methylthio) [1,3] oxazolo [4,5 - b] pyridine. However, the safety and toxicity of this compound are not detailed in the books, so I will deduce it from reason.
The nature of all things depends on its texture and structure. This compound contains the ring system of oxazolopyridine, and is connected to methylthio. Oxazolopyridine ring, often biologically active, exists in many drug molecules, or interacts with macromolecules such as receptors and enzymes in living organisms. Methylthio is also unusual, nucleophilic, and can participate in a variety of chemical reactions.
In terms of its safety, it is unknown how easy it is to degrade in the environment. If it is difficult to degrade, it may accumulate in water, soil and organisms, causing ecological changes. And its metabolic pathways in different organisms are unknown, or toxic metabolites are generated.
Talk about toxicity, although there is no empirical evidence, but heterocyclic and thioether structures containing nitrogen and oxygen may have potential toxicity. Heterocyclic compounds may interfere with normal physiological functions due to their binding to biological macromolecules; thioethers may also react through oxidation and other reactions to generate more toxic sulfoxides and sulfones.
Although this is the case, the above are all speculations. In order to determine its safety and toxicity, it is necessary to use rigorous scientific methods, through experimental investigation and data demonstration, to make a conclusion.