ATBA (Z)-2-(2-Aminothiazole-4-yl)-2-(Tert-Butoxycarbonyl)- Isopropoxyimino Acetic Acid

This question is related to the chemical structure of isobutyloxyacetoxyacetic acid, which is a subtle theory. If you want to know the details, please listen to me slowly.
isobutyloxyacetoxyacetic acid, according to its name, its structure must contain a specific group. In this compound, there is an acetoxy group, which is like a delicate decoration. It is formed by connecting the acetyl group with the oxygen group, and it has its own unique ability in the properties and reactions of the molecule. There is also an isobutyloxy group. The isobutyl group is attached to the oxygen group in its branching state, giving the molecule a different spatial conformation and characteristics. The group of acetic acid lays the acidic foundation for the molecule.
In its structure, each part is related to each other, such as the stars in the sky, and each is in its place and affects each other. The spatial arrangement of acetoxy and isobutoxy affects the stereochemistry of the molecule, which in turn affects its physical and chemical properties. The branching structure of isobutoxy makes the force between molecules different, or affects its melting point, solubility, etc.
Furthermore, acidic acetic acid groups can be used as proton donors in chemical reactions and participate in many acid-base reactions. The surrounding groups modulate its acidity.
The chemical structure of this isobutyloxyacetoxyacetic acid is like a delicate painting. The color matching and location layout of each part have a deep meaning, and together they constitute this unique molecule, which shows its unique charm and properties in the field of chemistry.

Isobutoxyacetaminoglycolic acid is widely used. In the field of medicine, it can be used as a key drug intermediate to help synthesize a variety of drugs. It is of great significance to the structural modification and activity improvement of drug molecules, which can enhance drug efficacy, reduce side effects, and provide better drug options for disease treatment.
In the chemical industry, it can be used as an excellent surfactant raw material. With its unique molecular structure, the prepared surfactant has excellent emulsification, dispersion and solubilization properties. It is widely used in detergents, cosmetics and other products, which can enhance product cleaning effect, improve stability and use texture.
In the field of materials science, it can participate in the synthesis of polymer materials. Introduced into the polymer structure by chemical reaction, it can change the physical and chemical properties of the material, such as improving the flexibility, water resistance and anti-aging properties of the material, and broaden the application range of polymer materials, so that the material can better perform in different environments.
In addition, in the agricultural field, it may be used as a pesticide auxiliary. It can enhance the adhesion and permeability of pesticides on the surface of plants, improve the efficacy of pesticides, reduce the amount of pesticides, reduce the impact on the environment, and help to achieve efficient green agricultural production. In short, isobutoxy acetamidoglycolic acid plays an important role in many fields and is of great significance to the development of related industries.

The method of preparing isobutyloxyacetoxyacetic acid, as well as organic compounds, is quite complicated and can be described in detail.
The method often uses isobutanol, ethylene oxide, chloroacetic acid, etc. as raw materials. First take isobutanol, and under specific reaction conditions, such as at a suitable temperature, pressure and the presence of a catalyst, the two perform an addition reaction. The reactivity of capping ethylene oxide is quite strong, and the hydroxyl group in isobutanol can easily interact with it to form isobutyloxyethanol. In this step of the reaction, the control of temperature is very important. If it is too high, side reactions will occur, and if it is too low, the reaction will be slow and inefficient.
After obtaining isobutoxyethanol, it will react with chloroacetic acid in an alkaline environment. The amount and type of alkali have a great impact on the reaction. Usually, bases such as sodium hydroxide are used to form chloroacetic acid into a salt, enhance its nucleophilicity, and react with the hydroxyl group of isobutoxyethanol to generate sodium isobutoxyethanacetic acid. This process requires attention to the pH value of the reaction system. If the pH value is improper, or the reaction is incomplete, or other by-products are produced.
Then, acid is used to acidify sodium isobutoxyethanacetic acid. Strong acids such as hydrochloric acid are commonly used and adjusted to a suitable pH value to free precipitate isobutoxyethanacetic acid. After extraction, distillation, recrystallization and other post-treatment processes, impurities are removed and the product is purified to obtain pure isobutoxyethanacetic acid. < Br >
To prepare this compound, each step of the reaction needs to be carefully controlled. The proportion of raw materials, the conditions of the reaction, and a slight difference will affect the purity and yield of the product. It is the delicacy of chemical preparation.

< Br >
This question involves the physical and chemical properties of "isobutoxyacetoxyacetic acid", which is quite professional and profound. Let me tell you one by one.
isobutoxyacetoxyacetic acid, looking at its appearance, at room temperature, it may be a colorless to light yellow transparent liquid, like morning dew shining the sun, clear and shiny. Smell it, or have a slight special smell, although it is not pungent, it is also unique.
In terms of its solubility, this substance is quite outstanding in organic solvents. In alcoholic solvents, such as ethanol and methanol, it can be well miscible, just like the water of fish, which is inseparable. In ether solvents, such as ether, it can also show good solubility, and the two are like close friends. In water, although not completely soluble, it also has a certain solubility, just like finding some shelter in an unfamiliar place.
Its boiling point is the key temperature node for substances to change from liquid to gaseous. The boiling point of isobutoxy acetoxyacetic acid is subject to intermolecular forces and structural characteristics. Under specific pressure conditions, it has a fixed value. This value reflects the energy required for its gasification, which is related to its phase change at different temperatures.
Melting point is the conversion limit between solid and liquid states. When the temperature drops below the melting point, the substance will solidify into a solid state, and the structure will be arranged in a regular and orderly manner; and when the temperature rises above the melting point, it will gradually melt into a liquid state, and the molecular movement will be active.
In terms of chemical properties, the functional groups contained in its molecular structure, such as acetoxy groups and carboxyl groups, give it unique reactivity. Carboxyl groups are acidic and can neutralize with bases, just like yin and yang, generating corresponding salts and water. Under appropriate conditions, acetoxy groups can undergo hydrolysis reactions, like delicate mechanisms that open up to derive other compounds. This hydrolysis reaction is in the field of organic synthesis and may be a key step in the creation of new substances.
In addition, due to the characteristics of its structure, it can participate in many organic reactions such as esterification reaction and substitution reaction under specific catalyst and reaction conditions, and plays an indispensable role in the stage of organic chemistry, providing possibility for the synthesis of many compounds.
The physical and chemical properties of isobutoxy acetoxy acetic acid determine its application potential in many fields such as chemical industry and medicine, and it is really a shining pearl in the chemical world.

What I am asking you is about "ATBA (Z) -2- (2-hydroxypyridine-4-yl) -2- (tert-butoxycarbonyl) -isobutoxycarbonyl carbamic acid in the market price situation".
However, the price of such fine chemical substances often varies due to many reasons. The first one is the manufacturing cost. The preparation of this compound requires delicate processes and specific raw materials. If the raw materials are scarce and expensive, or the preparation process is complicated and energy consumption is huge, the cost will be high, and the price will also rise.
Furthermore, the situation of market supply and demand determines its price. If many pharmaceutical companies or scientific research institutions have strong demand for it, but the supply is limited, the so-called "rare is expensive", its price will rise. On the contrary, if the supply exceeds the demand, the price will tend to drop.
Again, the quality is also related to the price. Those with high purity and high quality must be more expensive than those with ordinary quality. Because they are used in scientific research, pharmaceuticals and other fields, they can better meet strict standards and requirements.
However, I do not know the exact current price. If you want to know the details, you can consult merchants specializing in fine chemicals, or check chemical product trading platforms, industry reports, etc., to get accurate price information.