2-Amino-5-iodo-4-methylpyridine-3-carbonitrile

2-Amino-5-iodine-4-methylpyridine-3-formonitrile has a wide range of uses. In the field of medicinal chemistry, it is often used as a key intermediate to help create a variety of specific drugs. Due to the unique chemical structure of this compound, it can precisely bind to specific targets in organisms, thus exhibiting significant biological activity. For example, when developing innovative drugs for some difficult diseases, 2-amino-5-iodine-4-methylpyridine-3-formonitrile can play a key role in building the core skeleton of the drug. After subsequent chemical modification and optimization, it is very likely to derive drugs with excellent efficacy and minimal side effects.
In the field of materials science, it also has outstanding performance. With its own special chemical properties, it can participate in the synthesis of materials with unique photoelectric properties. For example, in the preparation of organic Light Emitting Diode (OLED) materials, the introduction of 2-amino-5-iodine-4-methylpyridine-3-formonitrile may optimize the luminous efficiency and stability of the material, making the OLED display show more vivid colors and lower energy consumption, which strongly promotes the display technology to a new height.
Furthermore, in the field of pesticide chemistry, this compound can also play an important role. As a key raw material for the synthesis of new pesticides, through its interaction with specific biomolecules in pests, high-efficiency, low-toxicity, and environmentally friendly pesticide varieties can be developed, which can not only effectively prevent and control crop diseases and pests, ensure food yield and quality, but also reduce the negative impact on the ecological environment. This meets the urgent needs of the current development of green agriculture.

2-Amino-5-iodine-4-methylpyridine-3-formonitrile is one of the organic compounds. Its physical properties are particularly important, related to its performance in various chemical processes and practical applications.
In terms of appearance, this compound is usually in a solid state, with a color of white to light yellow powder. This form provides convenience when storing and using. Its powdery texture allows it to disperse more evenly when mixing and participating in the reaction, which helps to improve the efficiency of the reaction.
Melting point is also a key physical property. However, the exact melting point needs to be determined by fine experiments, because it is affected by various factors such as the purity of the compound and the measurement environment. Generally speaking, the melting point of organonitrile compounds is mostly within a specific range, and it is speculated that the melting point of this compound may be in a suitable range. This melting point characteristic plays an important role in the separation and purification process.
In terms of solubility, 2-amino-5-iodine-4-methylpyridine-3-formonitrile may have a certain solubility in organic solvents such as dichloromethane, N, N-dimethylformamide (DMF). This property allows it to effectively contact and react with other reactants in organic synthesis reactions and in selected solvent systems. In water, its solubility may be relatively low, because although there are amino groups in the structure of the compound that can form hydrogen bonds with water, the presence of iodine atoms, methyl groups and nitrile groups reduces the overall affinity with water.
Furthermore, its density is also a physical property that cannot be ignored. Although the exact value needs to be accurately measured, based on its molecular structure and the type and quantity of atoms contained, it can be preliminarily inferred that its density may be similar to that of compounds with similar structures. The characteristics of density are of great significance in operations involving the relationship between the mass and volume of substances, such as solution preparation, measurement of reactant materials, etc.
In addition, the stability of the compound is also an important consideration. Under normal environmental conditions, if there is no special chemical substance or external factors to stimulate, it may remain relatively stable. In case of extreme conditions such as high temperature, strong acid, and strong base, its structure may change, triggering chemical reactions and causing changes in its chemical properties.
In summary, the physical properties of 2-amino-5-iodine-4-methylpyridine-3-formonitrile, such as appearance, melting point, solubility, density, and stability, are interrelated and affect their application in the chemical field. In-depth understanding of them is the key to organic synthesis and related research.

The chemical synthesis of 2-amino-5-iodine-4-methylpyridine-3-formonitrile is an important topic in the field of organic synthesis. To synthesize this compound, several paths are often followed.
One of them can be started from a compound containing a pyridine ring. First, take a suitable pyridine derivative and introduce a methyl group at a specific position. This step is achieved by nucleophilic substitution reaction. Choose a suitable methylation reagent, such as iodomethane, and react with the pyridine derivative under basic conditions to connect the methyl group to the desired position.
Then, introduce a cyano group at another position of the pyridine ring. The common method is to react with halogenated pyridine derivatives with cyanide reagents, such as potassium cyanide, sodium cyanide, etc., in the presence of a phase transfer catalyst, so that the cyanyl group replaces the halogen atom to obtain a cyanide-containing pyridine compound.
As for the introduction of iodine atoms, it can be carried out after the pyridine ring has a methyl group and a cyanide group. Generally speaking, this purpose can be achieved by using electrophilic substitution reactions. With an appropriate iodine substitution reagent, such as N-iodosuccinimide (NIS), under specific reaction conditions, such as suitable solvents, temperatures and catalysts, iodine atoms are substituted for hydrogen atoms on the pyridine ring and positioned to the target position to obtain 2-amino-5-iodine-4-methylpyridine-3-formonitrile.
Second, there are also strategies for synthesizing pyridine rings. For example, using nitrogen-containing and carbon-containing small molecules as raw materials, the pyridine ring structure is constructed by multi-step reaction. First, the specific nitrogen-containing and carbon-containing compounds undergo condensation, cyclization and other reactions to form the prototype of the pyridine ring, and then methyl, cyano and iodine atoms are introduced in sequence. Each step of the reaction requires fine regulation of the reaction conditions to achieve the expected chemical selectivity and yield. Finally, the target product 2-amino-5-iodine-4-methyl pyridine-3-formonitrile is obtained.

2-Amino-5-iodine-4-methylpyridine-3-formonitrile is a chemical substance, and many matters need to be paid attention to when storing.
Bear the brunt, and the temperature and humidity must be properly controlled. This material may be affected by changes in temperature and humidity, so it should be stored in a cool and dry place. If the humidity is too high, it may cause deliquescence and damage its quality; if the temperature is too high, it may cause its chemical reaction and reduce its purity.
Secondly, light is also the key. Many chemicals react easily when exposed to light, and this substance may be no exception. Therefore, it should be stored in a dark container, such as a brown bottle, to avoid direct exposure to sunlight or strong light.
Furthermore, the storage place should be kept away from fire, heat and oxidants. 2-Amino-5-iodine-4-methylpyridine-3-formonitrile may be flammable, meet with oxidants, or react violently, causing fire or explosion risk.
In addition, storage containers are also careful. Make sure that the container is well sealed to prevent its leakage. The material should be compatible with the substance and do not react chemically with it. At the same time, the name, properties and storage precautions of the substance should be clearly marked on the outside of the container for easy access and management.
At the end, the storage area should be well ventilated. If the substance leaks or evaporates, harmful gases can be discharged in time to ensure environmental safety and avoid the risk of human poisoning.
All of these are for those who should pay attention when storing 2-amino-5-iodine-4-methylpyridine-3-formonitrile, and must not be taken lightly.

Looking at this question, I am inquiring about the market price range of 2-amino-5-iodine-4-methylpyridine-3-formonitrile. However, the price of this chemical is influenced by many factors, and it is difficult to draw a conclusion.
The first to bear the brunt is the difference between the manufacturers. Manufacturers have their own pricing differences due to the quality of technology and cost. Most of them are well-known large factories with exquisite technology and high product purity, and the price may be high; while small factory products may be slightly cheaper due to their lower purity.
Furthermore, the trend of market supply and demand is also the key. If the demand is strong and the supply is limited, the price will rise; on the contrary, if the supply exceeds the demand, the price will decline.
In addition, the amount of purchase has a great impact on the price. If you buy in bulk, merchants may give discounts for small profits but quick turnover; if you buy in small quantities, the unit price will be high.
As far as I know, the price of this chemical may be between a few yuan and a few tens of yuan per gram. If you buy a large amount, you may be able to negotiate a lower price; if you only need a small amount, you can buy it from a small reagent, and the price may be slightly higher.
However, this is only a rough guess. The actual price needs to be consulted in detail with chemical product suppliers, or you need to check the market on the chemical trading platform to get an accurate number.