2-(2-AMINOTHIAZOLE-4-YL)-2-[2-(TERTBUTOXYCARBONYL)ISOPROPOXYIMINO]ACETIC ACID

This is an organic compound, named 2- (2-aminothiazole-4-yl) -2- [2 - (tert-butoxycarbonyl) isopropoxyamino] acetic acid. To clarify its chemical structure, each part needs to be analyzed first.
"2 - (2-aminothiazole-4-yl) ", thiazole is a five-membered heterocyclic ring containing sulfur and nitrogen, with an amino group at 2 positions and a main chain at 4 positions. The thiazole ring has certain stability and biological activity, and is commonly found in many drugs and biologically active molecules.
"2- [2- (tert-butoxycarbonyl) isopropoxyamino]", this part contains isopropoxy, oxylianimino, imino and tert-butoxycarbonyl. Tert-butoxycarbonyl is often used as an amino protecting group, which can prevent the amino group from being unduly affected during the reaction in organic synthesis.
"Acetic acid" is the core of the main chain and has carboxyl groups. Overall, this compound has a complex structure, and its parts interact with each other, which may endow it with unique chemical and biological properties. Its structural design may be based on the purpose of organic synthesis, such as obtaining specific reactivity, regulating molecular hydrophobicity, or simulating a biologically active structure for use in medicine, pesticide research and development, etc. < Br >
These complex compounds often require multi-step organic reactions, and carefully planned reaction sequences and conditions to achieve the desired structure and purity. The analysis of their structures is the cornerstone for exploring their properties and potential applications.

2-%282-AMINOTHIAZOLE-4-YL%29-2-%5B2-%28TERTBUTOXYCARBONYL%29ISOPROPOXYIMINO%5DACETIC ACID, that is, 2- (2-aminothiazole-4-yl) -2- [2 - (tert-butoxycarbonyl) isopropoxyamino] acetic acid, this substance is widely used.
In the field of pharmaceutical chemistry, it is often a key intermediate. Many antibacterial and antiviral drugs depend on it for synthesis. Taking a new type of antibacterial drug as an example, in the construction of its chemical structure, the 2-aminothiazole group of the compound is combined with a specific side chain through a series of chemical reactions, which can optimize the affinity of the drug and the bacterial target and enhance the antibacterial activity. And because of its structural characteristics, it can effectively improve the pharmacokinetic properties of drugs, such as improving bioavailability and prolonging the action time in vivo.
In the field of organic synthesis, it is also an important building block. With the activity checking points of carboxyl groups, imino groups and thiazole rings in the molecule, it can participate in various types of organic reactions, such as esterification reaction and amidation reaction. Through such reactions, organic compounds with more complex and diverse structures can be constructed, expanding the material library of organic synthesis chemistry, and laying the foundation for the research and development of new functional materials and fine chemicals.
In the field of pesticides, this compound can be used as the starting material to modify and modify, and pesticide products with high insecticidal and bactericidal properties can be developed. Due to its unique chemical structure, it has a highly selective inhibitory or killing effect on specific crop pests and pathogens, and has a smaller impact on the environment than traditional pesticides, which is in line with the current green agricultural development concept.

The methods for synthesizing 2- (2-aminothiazole-4-yl) -2- [2- (tert-butoxycarbonyl) isopropoxyamino] acetic acid are various and ingenious. The common ones are about a few ends.
First, it can be started by a compound containing a 2-aminothiazole structure. First, take a suitable thiazole derivative and introduce the amino group at its 4-position. In this step, select a suitable amination reagent and control the reaction conditions, such as temperature, pH, etc., to introduce the amino group accurately. Then, the fragment containing 2- (tert-butoxycarbonyl) isopropoxyamino is prepared. The corresponding alcohol is often reacted with the tert-butoxycarbonylation reagent to obtain the tert-butoxycarbonyl derivative of the alcohol. After appropriate oxidation or other transformations, the imino structure is obtained. Finally, the amino-containing thiazole fragment is connected to the imino-containing fragment to construct the carbon-carbon bond or carbon-hetero bond of the target molecule. In this case, a condensation reagent is used to promote the binding of the two. After appropriate post-treatment, the product can be obtained.
Second, the construction of the thiazole ring is used as a starting strategy. Sulfur-containing and nitrogen-containing raw materials can be used to cyclize to form thiazole rings under specific conditions, and suitable substituents can be reserved on the rings. After the thiazole ring is formed, 2-amino and 2- (tert-butoxycarbonyl) isopropoxyamino structures are introduced in sequence. This process requires fine regulation of the reaction sequence and conditions of each step to ensure the selectivity and yield of each step. Each step of the reaction affects each other. If the conditions are improper, it is easy to cause side reactions to occur, resulting in impure products or low yields.
Or there are other unique synthesis routes. However, no matter what method is used, many factors such as the availability of raw materials, the difficulty of reaction, the cost and the impact on the environment need to be considered. On the road of synthesis, if you are walking on a secret path, you must carefully choose each step in order to achieve the best condition of the target product.

We look at the "2- (2-AMINOTHIAZOLE-4-YL) -2- [2- (TERTBUTOXYCARBONYL) ISOPROPOXYIMINO] ACETIC ACID" you are inquiring about in the market price range, which is a professional content in the field of fine chemicals. However, it is not easy to determine the price.
Because the price of chemical products is often affected by many factors. First, the cost of raw materials is the key. The preparation of this compound, the various raw materials required, if the supply of raw materials is tight, or the origin changes, or the market supply and demand imbalance, can cause the price of raw materials to fluctuate, which in turn affects the cost and selling price of the product. Second, the simplicity of the production process also has an impact. If the process is complicated, high-end equipment and exquisite technology are required, and the investment of manpower and material resources is quite large, the price will be high; on the contrary, the process is simple, the cost may be reduced. Third, the market supply and demand situation is related to the price. If the demand is strong and the supply is limited, the price will rise; if the supply exceeds the demand, the price may fall. Fourth, regional differences cannot be ignored. In different places, due to different transportation costs and the degree of market competition, the price may vary.
As for the exact price range, it is difficult to determine. Or you need to consult the merchants specializing in such chemical products, the trading platform of chemical raw materials, or refer to industry reports and market surveys to get a more accurate price range. However, I cannot give you an accurate price definition based on the existing information.

2-%282-AMINOTHIAZOLE-4-YL%29-2-%5B2-%28TERTBUTOXYCARBONYL%29ISOPROPOXYIMINO%5DACETIC ACID, it is an organic compound. Its safety and stability are related to many aspects.
When it comes to safety, this compound behaves differently in different scenarios. In the laboratory, strict procedures must be followed when operating. Because its chemical structure has a specific activity or reacts with other substances, protective measures are indispensable when exposed. If the operator is in front of appropriate protective equipment, including gloves, goggles, etc., to prevent skin and eye contact and avoid potential irritation or toxic damage. In case of inadvertent contact, it should be dealt with immediately according to the established emergency procedures.
As for stability, it is greatly affected by environmental factors. In terms of temperature, high temperature may cause it to decompose, so storage needs to be placed in a suitable low temperature environment. Humidity is also the key. High humidity environment may cause reactions such as hydrolysis, which will damage its structural stability. And this compound is sensitive to light, and strong light irradiation or induced luminescent chemical reactions cause it to deteriorate. Therefore, storage is often required in a cool, dry and dark place.
In addition, specific functional groups in its chemical structure also affect its stability. Such as amino groups, carboxyl groups, etc., or participate in chemical reactions to change its chemical properties. During synthesis, storage and application, these factors need to be considered to maintain its stability and safety.