5-Hydroxy-1-beta-D-ribofuranosylimidazole-4-carboxamide

5 - Hydroxy - 1 - β - D - ribofuranosylimidazole - 4 - carboxamide, which is a rather complex organic compound. In ancient words, its chemical structure can be explained as follows:
In this compound, "5 - Hydroxy" has a hydroxyl group at a specific position (position 5). The hydroxyl group is a group connected by covalent bonds between hydrogen and oxygen atoms. It plays a key role in many chemical reactions and often has active chemical properties. It can participate in various reactions such as esterification and oxidation.
"1 - β - D-ribofuranosyl" means that there is a β-D-furanosyl group attached at position 1. Furanosyl is a pentacarbon sugar with a furan ring structure, and the β configuration indicates a specific spatial orientation between the glycosyl group and the connected atom. This glycosyl group is common in many biomolecules such as nucleotides and is of great significance for maintaining the structure and function of biomolecules.
"imidazole-4-carboxamide" refers to the imidazole ring and has a formamide group attached at position 4. The imidazole ring is a five-membered heterocyclic ring containing two nitrogen atoms, and its conjugate structure endows this ring with certain stability and unique electronic properties. Formamyl groups are formed by linking carbonyl groups to amino groups, which also affect the chemical and physical properties of the whole compound.
Overall, the chemical structure of 5-Hydroxy-1 - β - D-ribofuranosylimidazole-4-carboxamide is composed of hydroxyl groups, furanribosyl groups, imidazole rings and formamide groups. The interaction of each part determines the unique chemical properties and potential biological activities of the compound.

5 - Hydroxy - 1 - β - D - ribofuranosylimidazole - 4 - carboxamide, the Chinese name is often 5 - hydroxy - 1 - β - D - ribosyl imidazole - 4 - formamide, its common uses are as follows:
In medicine, this substance is related to the synthesis of purine nucleotides. There are two pathways for the synthesis of purine nucleotides in the human body, which are the key substrates for remedial synthesis pathways. Many diseases are related to purine metabolism disorders, such as gout. This substance may be the key to exploring related disease mechanisms and developing new drugs. By studying its role in purine nucleotide synthesis, new strategies for treating such diseases may be found.
is an important tool in biochemical research. To study the process of purine metabolism in organisms, it is possible to observe cell metabolic changes by adding this substance, and clarify the specific steps and regulatory mechanisms of purine metabolism. Understanding how cells use its synthetic nucleotides is of great significance for understanding cell growth, proliferation and differentiation.
In the field of agriculture, it may also have potential value. During plant growth and development, purine nucleotides participate in many physiological processes, such as nucleic acid synthesis and energy metabolism. Studies have found that appropriate concentrations of this substance can treat plants, or affect plant purine metabolism, which in turn affects growth and stress resistance. Or new plant growth regulators can be developed to improve crop yield and quality.
This substance plays a key role in the fields of medicine, biochemical research and agriculture. With the deepening of research, more uses may be discovered, bringing benefits to human health and agricultural development.

5-Hydroxy-1 - β - D-ribosyl imidazole-4-formamide, this is an organic compound. Its physical properties are quite unique.
Looking at its shape, it is mostly white to white crystalline powder under normal circumstances. The texture is delicate, just like the first snow in winter, quiet and pure.
When it comes to solubility, this compound can show certain solubility properties in water. Under suitable temperature and stirring conditions, part of it can be dissolved into water to form a clear or slightly cloudy solution, just like fine sand quietly merging into a stream, gradually losing its shape but existing. In polar organic solvents, such as methanol, ethanol, etc., it also has a certain solubility, just like a wanderer finding a suitable place to live, and can blend with the solvent.
Melting point, after rigorous determination, is about a certain temperature range. At this temperature, the compound is like a sleeping spirit waking up, slowly changing from solid to liquid, and undergoing phase changes. This temperature is also its inherent characteristic, just like the sign of its life.
Stability is also one of its important physical properties. Under conventional environmental conditions, if the temperature and humidity are suitable and protected from direct light, this compound can maintain a relatively stable state, just like being in a quiet harbor, calm. However, if the environmental conditions are severe, such as high temperature, high humidity or long-term exposure to strong light, its structure may gradually change, just like a pavilion eroded by wind and rain, and its stability gradually loses.
Its density also has a specific value, although it is difficult for the naked eye to intuitively detect, at the microscopic level, the density of the molecular arrangement determines this value, just like a finely woven brocade, each strand has its place, which together constitutes the unique physical properties of the compound. This density is an indispensable consideration in many experiments and practical applications.

5-Hydroxy-1 - β - D-ribosyl imidazole-4-formamide is an important compound in biochemical research. Its synthesis method has been explored by many parties throughout the ages.
One method is to select the appropriate furan ribose derivative and imidazole compound from the starting material. First, the furan ribose derivative is pretreated to expose its activity check point, which is like opening the door to the reaction. Then, the imidazole compound is reacted with it, and the reaction conditions need to be precisely controlled, such as temperature, pH, and reaction time, all of which are related to success or failure. If the temperature is too high, it may cause a cluster of side reactions; if the temperature is too low, the reaction will be slow and inefficient. This process is like cooking small fresh food, and care needs to be taken.
The second method also starts with other compounds with similar structures and is obtained through several steps of delicate transformation. First, through a specific chemical reaction, the structure of the starting compound is modified to build a skeleton similar to the target product. Then through a selective reaction, the required functional groups are gradually introduced, just like a craftsman carving beautiful jade, carefully creating every detail.
The third method uses biosynthesis. Find a suitable microorganism or enzyme, and use the metabolic mechanism in the organism to catalyze the synthesis of the target product under a specific culture environment. This approach is green and environmentally friendly, but it has strict requirements on biological systems. It requires a deep understanding of the mysteries of biological metabolism in order to be able to control it freely.
The above synthesis methods have their own advantages and disadvantages. It is necessary to make a careful choice according to the actual situation, weighing the availability of raw materials, the cost, and the geometry of the yield. The road of synthesis is long and difficult, but every exploration adds to the progress of science.

5-Hydroxy-1 - β - D-ribosyl imidazole-4-formamide, this is a rather professional chemical substance. On the market, its price range often fluctuates due to multiple factors.
First, purity is the key factor. If the purity of the substance is extremely high, close to the level of scientific research, few impurities, and can be accurately used for high-end experimental research, the price of such purity products should be high. The price per gram may reach hundreds of yuan, or even higher, depending on the specific purity and market supply and demand.
Second, the scale of production also affects the price. If large-scale industrial production, due to the scale effect, the unit cost may be reduced, and the price will also be reduced. However, if it is a small-scale laboratory preparation, the cost remains high, and the price will be relatively high.
Third, the market supply and demand situation also affects its price. If many scientific research institutions or enterprises have strong demand for this material at a certain time, but the supply is limited, the price will rise; conversely, if the supply exceeds the demand, the price will stabilize or decline.
Overall, in common market scenarios, the price per gram of low-purity, industrial-grade products may be in the range of tens of yuan; while the price per gram of high-purity, suitable for fine scientific research products may range from hundreds to hundreds of yuan. However, the market is constantly changing, and the specific price still depends on the actual purchase time and the supplier's quotation.