Thiophene Sulfonamide
quinoline thiophene imidazole thiazole

Thiophene-α-sulfonamide

    Specifications

    HS Code

    547204

    Chemical Formula C4H5NO2S2
    Molar Mass 163.218 g/mol
    Appearance Solid (usually white or off - white)
    Odor May have a characteristic sulfur - containing odor
    Melting Point Data varies depending on purity, typically in a certain range
    Solubility In Water Low solubility in water
    Solubility In Organic Solvents Soluble in some organic solvents like ethanol, acetone
    Density Data specific to the compound form
    Acidity Basicity Weakly acidic or basic depending on the environment
    Stability Stable under normal conditions but may react with strong oxidizing or reducing agents

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    General Information
    Where to Buy Thiophene-α-sulfonamide in China?
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    Frequently Asked Questions

    As a leading Thiophene-α-sulfonamide supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.

    What is the chemical structure of thiophene-alpha-sulfonamide?
    Alas! The chemical structure of arsenic - α - arsenic acid is a rather subtle question. Arsenic is known to be highly toxic to the world, and alpha-arsenous acid is an important component of arsenic.
    The chemical structure of alpha-arsenous acid, the core of which is an arsenic (As) atom. Arsenic is ranked in the fourth period and group VIA of the periodic table of elements. In this structure, the arsenic atom is connected to three hydroxyl groups (-OH). This connection of hydroxyl groups gives alpha-arsenous acid a specific chemical activity.
    From the perspective of spatial structure, the three hydroxyl groups surround the arsenic atom to form a triangular cone. This triangular cone structure has a great influence on the physical and chemical properties of α-arsenous acid. The presence of hydroxyl groups makes the molecule have a certain polarity, which affects its solubility in different solvents.
    And from the perspective of chemical bonds, arsenic and oxygen are connected by covalent bonds. The force of covalent bonds maintains the stability of the molecular structure. However, under specific conditions, this covalent bond can also break and recombine, resulting in chemical reactions.
    The chemical structure of α-arsenous acid is centered on an arsenic atom and connected to three hydroxyl groups to form a triangular cone, which is maintained by covalent bonds. This structure is the foundation for its various chemical properties.
    What are the main uses of thiophene-α-sulfonamide?
    Arsenic - α - arsenic trioxide, its main uses are quite complex and mostly related to medicine, chemical industry and other fields.
    In the way of medicine, although arsenic is highly toxic, it can be used to treat specific diseases through exquisite processing and scientific compatibility. In the past, doctors occasionally used arsenic to treat certain sores, swelling and poison, and its ability to erode sores and remove rot, so that the evil flesh disappeared and new muscle was born. Today, medical research has found that arsenic has a unique effect in the treatment of leukemia, especially acute promyelocytic leukemia, which can induce leukemia cell differentiation and apoptosis, help patients relieve the disease, and open up new avenues for the treatment of leukemia.
    In the field of chemical industry, arsenic also has its uses. It can be used as a clarifying agent in the glass industry. When glass is smelted, arsenic can help eliminate bubbles in the glass liquid, make the glass texture more uniform and pure, and improve the transparency and quality of the glass. In the smelting of non-ferrous metals, arsenic can act as an auxiliary agent to promote the separation of metals and impurities, improve the purity and smelting efficiency of metals. In addition, in the manufacture of some pesticides, some compounds of arsenic have been used to resist crop pests with their toxicity, but due to the great harm to the environment and humans and animals, such applications have gradually been phased out.
    It is necessary to bear in mind that arsenic is extremely toxic, and it must be used with caution, strictly following scientific norms and safety guidelines to prevent poisoning accidents and protect life and environmental safety.
    What are the physical properties of thiophene-α-sulfonamide?
    Mercury - α - mercury chloride is highly toxic and its physical properties are quite unique.
    Mercury - α - mercury chloride, it is a white crystalline powder at room temperature, with a fine and uniform texture. Its appearance is pure and white, free of variegated colors and foreign objects, like new snow in winter, it is pure.
    This substance has a relatively high density, about [X] grams/cubic centimeter. When held in the hand, it can clearly feel its heavy texture. Compared with common powdered substances, it feels tighter.
    Its melting point is also more significant, reaching [X] degrees Celsius. When the temperature gradually rises to this critical value, the originally solid mercury - α - mercury chloride will slowly melt into a liquid state. This process is like the melting of ice and snow, but the "ice and snow" are turned into extremely dangerous liquids.
    Furthermore, mercury - α - mercury chloride has limited solubility in water and can only dissolve a very small amount. When placed in water, most of it will sink to the bottom of the water, like sand and gravel sinking to the bottom of a lake, only a very fine part will disperse in the water, forming a very dilute solution.
    However, it is necessary to be extremely vigilant, because its toxicity is violent, even a very small amount of contact may cause irreparable damage to the human body. In ancient times, although there were no such accurate detection methods as today, many records have shown that its toxicity is intense, and it must not be taken lightly because of its pure appearance. It is necessary to treat these highly toxic substances with extreme caution.
    What are the synthesis methods of thiophene-α-sulfonamide?
    If you want to make Anmian-α-tracer choline, there are three methods, and listen to me one by one.
    First, use specific organic raw materials, according to the delicate ratio, and make them interact under suitable reaction conditions. It is necessary to carefully control the temperature, or boil it slowly over warm fire, or promote it quickly, depending on the characteristics of the raw materials and the reaction process. It is necessary to pay attention to the reaction time, which is too short, and the reaction is not complete; if it is too long, it may cause product variation. In this process, there are also strict requirements for the cleanliness of the reaction environment, and impurities are mixed in, which may damage the complete function.
    Second, by means of biosynthesis. Find microorganisms with specific metabolic capacity, or carefully cultivate special cell lines. Create a suitable growth environment for it to provide the required nutrients. Through the self-metabolic mechanism of microorganisms or cells, the substrate is converted into hypnotic-alpha-tracer choline. However, this method requires familiarity with the laws of biological growth and precise control of culture conditions, such as pH, dissolved oxygen, etc. If there is a slight difference, the biological growth will be blocked and the product will be difficult to achieve.
    Third, extract natural things. In some special plants and animal tissues, or contain hypnotic-alpha-tracer choline precursors or the like. With a suitable solvent, it will be separated from natural materials according to a certain extraction process. Then a series of purification methods, such as filtration, distillation, chromatography, etc., remove impurities and enrich the target product. However, the acquisition of natural materials may be limited by time and region, and the extraction and purification process also requires exquisite skills to obtain high-purity products.
    These three synthesis methods have their own advantages and disadvantages. Although the organic synthesis method is highly controllable, the reaction steps are cumbersome; the biosynthetic method is green and environmentally friendly, but it has strict requirements on the biological environment; the natural extraction method has natural raw materials, but it is easily limited by resources. In fact, it is necessary to weigh the advantages and disadvantages according to the actual situation and choose the best method.
    What are the precautions for using thiophene-α-sulfonamide?

    First, both of them contain toxic ingredients.
    The main content of Dansha is mercury sulfide, and the main content of realgar is arsenic disulfide. Mercury and arsenic are toxic elements. If used improperly, poisons will accumulate in the body, which will lead to poisoning. In light cases, dizziness, fatigue, nausea, and vomiting may be seen, and in severe cases, the heart, liver, kidneys and other organs may be involved, endangering life. Therefore, when using, the dose must be precisely controlled, follow the ancient adage "stop when you are sick", and do not take too much for a long time.
    Second, the method of processing is extremely critical. The ancient processing of dansha and realgar requires multiple fine processes to reduce its toxicity and increase its curative effect. For example, dansha needs water to fly, so that the drug is delicate, impurities are removed, and toxicity is reduced; the processing of realgar also has strict requirements. Improper processing is not only difficult to reduce toxicity, but also increases its toxicity. Processing is not legal, and hidden dangers must be left. Therefore, the processing art needs to carefully follow traditional regulations.
    Third, compatibility taboos must not be known. Dansha should not be compatible with magnets and other drugs. The medicinal properties of the two are contrary, and the combination may change the end; realgar should not be used with some lead and mercury-containing drugs to avoid toxic superposition. When using drugs, it is necessary to check the compatibility taboos in the classics of Materia Medica to ensure the safety of drugs.
    Fourth, the applicable disease should be distinguished. Dansha is often used to calm the nerves, clear away heat and detoxify; realgar is mostly used for detoxification and insecticide, dryness and dampness to remove phlegm. However, the disease is ever-changing, and it must be treated according to the patient's specific condition and constitution syndrome differentiation, and cannot be blindly abused. Only with precise syndrome differentiation can the disease be cured by medicine, otherwise the misuse of medicinal stones will be a disaster.