2 Amino 6 Iodo 7h Purine

2-Amino-6-iodo-7H-purine, Chinese name 2-amino-6-iodine-7H-purine. This is one of the purine compounds, which is very important in the fields of organic chemistry and medicinal chemistry.
To clarify its chemical structure, look at the basic structure of purines. Purines are fused from a pyrimidine ring and an imidazole ring, have a double ring structure, contain four nitrogen atoms, and their numbering rules are established. On the basis of the purine parent nucleus, the 2-amino-6-iodo-7H-purine is added with amino group (-NH 2O) at the 2nd position, the 6-iodized atom (-I), and the 7-position hydrogen is not replaced, and it is still represented by 7H.
Its structure can be described as follows: in the purine bicyclic structure, the nitrogen atom connected to the imidazole ring and the pyrimidine ring is 1 position, numbered clockwise along the pyrimidine ring, and the 2 position has an amino group. This amino group is composed of nitrogen atoms and two hydrogen atoms, which are covalently bonded to the purine ring; the 6 position is connected to an iodine atom, and the iodine atom is single-bonded to the carbon atom of the purine ring; and the 7 position is only a hydrogen atom, which is not replaced by other groups. In this way, the chemical structure of 2-amino-6-iodo-7H-purine can be clearly presented. This unique structure endows the compound with specific chemical properties and biological activities, which is of great significance in related research and applications.

2-Amino-6-iodine-7H-purine is one of the organic compounds. Its main uses are related to many fields, let me tell you one by one.
In the process of pharmaceutical research and development, this compound is of great significance. Because of its unique structure, it may be used as a key intermediate to create new drugs. In the development of anti-cancer drugs, scientists hope that by chemically modifying and modifying it, it has the ability to target cancer cells and interfere with the growth, proliferation and metabolism of cancer cells, so as to achieve the purpose of treating cancer. Studies have also shown that it may have potential value in the treatment of certain viral infectious diseases, and can inhibit the spread of viruses by affecting specific biological processes required for virus replication.
In the field of materials science, 2-amino-6-iodine-7H-purine has also emerged. Due to its molecular properties, it may be used to prepare functional materials. For example, in organic optoelectronic materials, it can adjust the electrical and optical properties of materials and improve their photoelectric conversion efficiency. It is expected to be applied to the manufacture of solar cells, Light Emitting Diodes and other devices, contributing to the development of new energy and optoelectronic technologies.
Furthermore, in biochemical research, this compound can be used as a probe molecule. By tagging specific biomolecules, scientists can gain a clearer understanding of the chemical reactions and molecular interactions in living organisms, helping to uncover the mysteries of life processes, such as the interaction mechanism between proteins and nucleic acids.

2-Amino-6-iodo-7H-purine is an organic compound. The details of its physical properties can be described by you.
The first word about the appearance, this material is usually solid, its color is often white or white powder, the texture is fine, just like the snow that falls at the beginning of winter, pure and simple.
As for the melting point, this compound has a specific melting point value, but in order to be precise, it still needs to depend on the experimental conditions and sample purity. Generally speaking, its melting point is within a certain range, and this property is the key to the identification and purification of the compound. Just as with fire testing, the melting point is one of the important criteria for verifying its quality.
In terms of solubility, 2-amino-6-iodo-7H-purine behaves differently in different solvents. In water, its solubility is limited and only slightly soluble, just like a pearl in shallow water, it is difficult to melt in it; while in some organic solvents, such as dimethyl sulfoxide (DMSO), it can show good solubility, just like fish get water and blend leisurely. This difference in solubility provides various possibilities for its applications in chemical synthesis, drug development and other fields.
In addition, its density is also an important physical property. Although the exact density value needs to be precisely measured to know, it can be inferred that its density has its own unique characteristics compared with similar compounds. This density characteristic has a deep impact on the separation and mixing of substances, and it is like weighing the weight, determining the ups and downs and aggregation of substances.
Looking at its stability, under normal temperature and humidity conditions, 2-amino-6-iodo-7H-purine can still maintain relative stability. However, in case of extreme environments, such as high temperature, strong acid and alkali, etc., its structure may be damaged, just like a strong city encountering strong bandits, which will inevitably damage its original appearance.
To sum up, the physical properties of 2-amino-6-iodo-7H-purine are of great significance in many aspects such as chemical research and industrial production, just like the stars in the night sky, each shining with unique brilliance, guiding the way to explore the mysteries of the material world.

The synthesis method of 2-amino-6-iodine-7H-purine is ancient, and after years of precipitation, it has gradually become complete. In the past, various sages worked hard in the field of chemical synthesis, and finally obtained methods to produce this substance.
First, purine is used as the initial material, and iodine atoms are introduced by halogenation. First, purine is placed in a specific reaction environment, accompanied by halogenated reagents, so that it can react at a suitable temperature and pressure. During this process, the reaction conditions need to be carefully regulated to prevent side reactions from breeding. After the halogenation reaction is completed, after the amination step, the purine molecule is introduced into the amino group with a suitable amination reagent, and then 2-amino-6-iodine-7H-purine is obtained.
Second, there are also those who use nitrogen-containing heterocyclic compounds as starting materials. First construct the basic skeleton of purines, which is often formed by cyclization. When the skeleton is first formed, the halogenation and amination reactions are carried out in sequence. When cyclization, it is crucial to choose the appropriate catalyst and reaction medium, which is related to the success or failure of the skeleton construction and the quality. The halogenation and amination steps also need to be done with caution, and the best reaction parameters should be found according to the characteristics of the compound.
Third, organometallic reagents are also commonly used in this synthesis. Organometallic reagents interact with compounds containing iodine and nitrogen, and with the help of the catalytic activity of metals, the reaction is guided to the target product. This path requires high accuracy of the reaction, and the purity, dosage, and timing of the reaction are all key factors. Fine operation is required to obtain the ideal yield and purity.
Looking at the various synthesis methods, although each has its own advantages, chemists are required to understand the reaction mechanism, observe the characteristics of substances, and control the process of the reaction with exquisite skills to obtain the pure product of 2-amino-6-iodine-7H-purine for scientific research and various applications.

Today I have a question, what is the price range of 2-amino-6-iodo-7h-purine in the market. This is a chemical substance, its price is difficult to determine, and it changes for a variety of reasons.
Bear the brunt, and the difficulty of preparation is greatly related. If the preparation of this substance requires complicated methods, using rare materials, and consuming huge amounts of capital, the price will be high. On the contrary, if the preparation is simple and the materials used are ordinary, the price may be close to the people.
Furthermore, the market supply and demand situation is also serious. If there are many people who want it, and there are few people who supply it, the price will rise; if the supply exceeds the demand, the merchant may reduce the price to promote.
There are also purity points. High purity, because purification is not easy, the price is often higher than that of low purity.
And different merchants, because of their different cost accounting and profit requirements, have different pricing.
As for the exact price range, it is difficult to specify. For details, you can visit the chemical raw material trading platform and consult chemical reagent suppliers to get a near-real price.