s-2-amino-6-propionamide-4,5,6,7-tetrahydrobenzothiazole

Alas! This is the question of an organic compound. To clarify its chemical structure, it is necessary to study its naming in detail. "S-2-amino-6-propionamide-4,5,6,7-tetrahydrobenzothiazole", according to the naming convention of organic chemistry, "s" or its three-dimensional configuration; "2-amino" shows that the amino group is connected to the 2 position; "6-propionamide" says that the 6 position has a propionamide group; "4,5,6,7-tetrahydrobenzothiazole" The 4, 5, 6, and 7 positions of the epibenzothiazole ring are hydrogenated states.
The structure of this compound is based on the benzothiazole ring, and the 4, 5, 6, and 7 positions in the ring are saturated carbon. The second position of the ring is connected to the amino group, and the sixth position is connected to the propionamide group. The benzothiazole ring is formed by fusing the benzene ring with the thiazole ring. The thiazole ring is a five-membered heterocyclic ring containing sulfur and nitrogen, and the benzene ring is fused with it, so this basic structure is formed. The
amino group is a -NH2O group, which is basic. The propionamide group is a -CONH-CH -2-CH ² structure, in which the carbonyl group is connected to the amino group and the propyl group. These groups are connected to the benzothiazole ring, which gives the compound unique chemical properties. Its hydrogenation position also changes the stability and reactivity of the ring. In this way, the chemical structure of the compound is roughly clear.

S-2-amino-6-propionamido-4,5,6,7-tetrahydrobenzothiazole is one of the organic compounds. It has a wide range of uses in the field of medicine and is often a key intermediate in drug synthesis. Taking the creation of antibacterial drugs as an example, this compound has a special structure and can combine with specific targets in bacteria to interfere with the normal physiological metabolism of bacteria, thereby exerting antibacterial effects.
In the field of pesticides, it also shows important functions. Its structure can be modified to have insecticidal, herbicidal and other properties. Because it can affect the conduction of the insect nervous system, or interfere with the physiological and biochemical processes of weeds, in order to achieve the purpose of controlling pests and weeds.
In the field of materials science, S-2-amino-6-propionamido-4,5,6,7-tetrahydrobenzothiazole can participate in the preparation of some functional materials. For example, the preparation of materials with special optical and electrical properties contributes to the development of materials science. Due to its unique chemical structure and active check point, it can endow materials with unique properties and has great application potential in electronic devices, optical sensors and so on.

The synthesis of s-2-amino-6-propionamide-4,5,6,7-tetrahydrobenzothiazole has been investigated throughout the ages. There are many methods, and each has its advantages and disadvantages. Today, choose the main one to describe.
First, it can be started with specific thiols and enamines. First, the thiols and enamines are put in a suitable solvent, and with the help of a catalyst, a nucleophilic addition reaction occurs. This reaction condition needs to be precisely regulated, such as temperature, pH, etc. If the temperature is too high, side reactions will breed; if the temperature is too low, the reaction will be delayed. After the addition product is generated, it will go through the cyclization step. When cyclization, a suitable dehydrating agent or acidic reagent can be used to promote intracyclization in the molecule to obtain the skeleton of the target product. However, this process needs to pay attention to the reaction selectivity. Due to a slight difference in pooling, isomer impurities are prone to occur.
Second, nitrogen-containing heterocyclic precursors and sulfur-containing compounds are used as raw materials. First, the nitrogen-containing heterocyclic precursors are modified to introduce specific substituents to enhance their reactivity. After reacting with sulfur-containing compounds in an alkaline environment, a series of rearrangement, condensation and other steps are taken to construct a tetrahydrobenzothiazole structure. This approach requires high purity of raw materials, and the alkaline conditions are not easy to control. Too strong or too weak alkalinity may affect the reaction process and product yield.
Third, there are also biosynthesis attempts. With the help of specific microorganisms or enzymes, the metabolic pathways in organisms are simulated to synthesize target compounds. This method is green and environmentally friendly, with good selectivity, but it requires strict requirements on the reaction system. It requires precise control of the microbial growth environment or enzyme activity conditions. At present, the biosynthetic efficiency still needs to be improved, and large-scale production still faces challenges.
Although various synthetic methods have their own advantages and disadvantages, in order to achieve the goal of efficient and high-purity synthesis, chemists need to continuously study and optimize, weigh the advantages and disadvantages of each method, and choose the best solution according to actual needs and conditions.

S-2-amino-6-propionamido-4,5,6,7-tetrahydrobenzothiazole is one of the organic compounds. Its physical and chemical properties are unique and relate to many characteristics of this compound.
In terms of its physical properties, under normal temperature and pressure, this compound may be in a solid state, its appearance may be a crystalline powder, its color is white and pure, just like the first snow in winter, and its texture is delicate. Its melting point or in a specific temperature range, this temperature range is like a boundary to distinguish its solid-liquid state. As for the boiling point, it is also at a certain value, which is closely related to the intermolecular force. In addition, its solubility is also an important physical property, and in water and various organic solvents, the dissolution situation varies. In polar solvents, or due to molecular polarity, it exhibits different degrees of solubility, either slightly soluble or soluble, just like the adaptability of fish in different waters.
Its chemical properties are based on its molecular structure. This compound contains functional groups such as amino groups, propionamido groups and benzothiazole rings. Amino groups are basic and can be neutralized with acids, just like yin and yang, reaching a new chemical equilibrium. Propionamido groups also participate in specific chemical reactions, such as the hydrolysis of amides. Under the catalysis of acid and base, bond breaks and rearrangements occur to form new compounds. The structure of the benzothiazole ring is stable, but under specific conditions, such as high temperature and the presence of strong oxidants, it can also react and change the molecular skeleton, showing the wonder of chemical changes.
Furthermore, the stability of this compound is also worthy of investigation. In general environments, without the influence of special factors, its molecular structure remains stable, just like a strong city barrier. However, under extreme conditions, such as high temperature, high humidity, and strong light irradiation, the chemical bonds inside the molecule may be affected and change, resulting in changes in the properties of the compound. The study of this stability is of great significance for its storage, transportation, and application.

I have not heard that there is a definite price of s-2-amino-6-propionamide-4, 5, 6, 7-tetrahydrobenzothiazole in the market. However, if you want to estimate its price, you should look at the number.
First, the production of this product requires exquisite techniques, and the selection of raw materials is also strict. If the raw materials are rare and expensive, and the manufacturing process is difficult, the price must be high. Its synthesis path involves multiple steps, and high-purity raw materials are required, which all increase its cost.
Second, the supply and demand of the market is greatly related to the price. If this product is in high demand in the pharmaceutical, chemical and other industries, and there are few suppliers, the price will rise; conversely, if the supply exceeds the demand, the price will drop.
Third, the place where it is sold, its taxes and logistics fees also affect the price. In places with heavy taxes or inconvenient logistics, the price may be higher.
The publicly released price has not been seen in the market today, so it is difficult to determine the exact number. However, according to the example of similar fine chemicals, if it is used in small amounts for scientific research, or tens to hundreds of gold per gram; if it is mass-produced in industry, it may range from tens of thousands to hundreds of thousands of gold per ton depending on the purity and quantity. Ultimately, if you want to know the exact price, you need to consult the chemical raw material supplier or check it on the relevant trading platform before you can obtain it.