Taurocyamine

Taurocyamine is a compound found in various marine animals, particularly in shellfish. While it may seem like a relatively obscure substance, it holds significant relevance to everyday life due to its potential use in pharmaceutical research and the development of new medications. Research suggests that taurocyamine may have properties that could be beneficial in treating neurological disorders, such as Alzheimer’s disease and Parkinson’s disease. Therefore, further exploration of taurocyamine’s properties and potential applications could potentially lead to advancements in healthcare and improved treatments for these conditions.

Table of Contents:

• 💡  Commercial Applications
• ⚗️  Chemical & Physical Properties
• 🏭  Production & Procurement
• ⚠️  Safety Considerations
• 🔬  Potential Research Directions
• 🧪  Related Compounds

💡  Commercial Applications

Taurocyamine, a derivative of creatine, has several commercial and industrial applications. It is commonly used as a dietary supplement to improve physical performance and muscle strength. Additionally, taurocyamine is utilized in certain sports nutrition products to promote endurance and enhance athletic performance.

In the realm of drug and medication applications, taurocyamine has shown promise as a potential treatment for neuromuscular disorders. Studies have indicated that taurocyamine may help improve muscle function and mobility in individuals with certain muscle-wasting diseases. Furthermore, research is ongoing to explore the potential therapeutic benefits of taurocyamine in managing symptoms of age-related muscle decline.

While the commercial and industrial applications of taurocyamine primarily revolve around athletic performance and physical enhancement, its medicinal properties show potential for addressing various health conditions. Whether used as a dietary supplement for muscle building or as a therapeutic agent for neuromuscular disorders, taurocyamine continues to be a subject of interest in both the fitness and medical industries.

⚗️  Chemical & Physical Properties

Taurocyamine is a white crystalline solid with no distinct odor. It appears as fine powder particles and does not exhibit any particular scent.

With a molar mass of approximately 212.24 g/mol and a density of about 2.35 g/cm³, taurocyamine falls within the range of common food items such as glucose (molar mass: 180.16 g/mol, density: 1.54 g/cm³) and table salt (molar mass: 58.44 g/mol, density: 2.16 g/cm³).

Taurocyamine has a melting point of around 300°C and a boiling point of approximately 500°C. This places it in a higher range compared to common food items such as sugar (melting point: 186°C, boiling point: 186°C) and butter (melting point: 32-35°C, boiling point: 177°C).

Taurocyamine is sparingly soluble in water and exhibits a low viscosity. Compared to common food items such as salt (soluble in water) and honey (viscous), taurocyamine’s solubility in water and viscosity are relatively lower.

🏭  Production & Procurement

Taurocyamine is a compound that is primarily produced through organic synthesis in laboratory settings. This process involves the combination of specific chemical reagents to form the desired compound in a controlled environment. The synthesis of Taurocyamine requires expertise in organic chemistry and precise adherence to reaction conditions.

Taurocyamine can be procured through specialized chemical suppliers that offer this compound for research purposes. It may also be sourced from pharmaceutical companies that produce it for use in drug development and testing. Once procured, Taurocyamine can be transported in sealed containers to ensure its integrity and stability during transit.

The transportation of Taurocyamine typically involves standard shipping practices, such as using a reliable courier service or freight carrier. Due to its chemical nature, precautions must be taken to prevent contamination and ensure safe handling during transportation. It is important to follow established safety guidelines and regulations when procuring and transporting Taurocyamine to prevent any potential risks to human health and the environment.

⚠️  Safety Considerations

Safety considerations for Taurocyamine include its potential to cause irritation or sensitization upon contact with skin or eyes. It may also pose a risk of serious health effects if inhaled or ingested. Proper personal protective equipment should be worn when handling this substance, and work areas should be well-ventilated to prevent exposure.

Hazard statements for Taurocyamine include its classification as a skin and eye irritant, as well as a respiratory and skin sensitizer. It may cause allergic skin reactions in some individuals upon prolonged or repeated exposure. Ingestion or inhalation of Taurocyamine may result in serious health effects, including respiratory irritation or gastrointestinal discomfort.

Precautionary statements for Taurocyamine recommend wearing protective gloves and eye protection when handling this substance. Work areas should be well-ventilated to prevent exposure to vapors or dust particles. In case of skin contact, it is advised to wash the affected area thoroughly with soap and water. If exposure occurs through inhalation, move to a well-ventilated area and seek medical attention if respiratory symptoms persist. In case of ingestion, seek medical advice immediately and do not induce vomiting.

🔬  Potential Research Directions

One potential research direction for Taurocyamine is its physiological effects on various biological systems. Understanding how this compound interacts with receptors and enzymes in the body could provide insights into its potential therapeutic applications.

Another research avenue is investigating the pharmacokinetics of Taurocyamine, including its absorption, distribution, metabolism, and excretion in the body. This information is crucial for determining the optimal dosage and frequency of administration for potential medical use.

Furthermore, exploring the potential bioavailability of Taurocyamine through different routes of administration, such as oral, parenteral, or pulmonary delivery, could broaden its therapeutic potential. Studying the compound’s stability and solubility in different formulations may also be crucial for its development as a drug candidate.

🧪  Related Compounds

One similar compound to Taurocyamine based upon molecular structure is Creatine. Creatine is a nitrogenous organic acid that occurs naturally in vertebrates. It plays a crucial role in energy metabolism, particularly in muscle cells, where it helps regenerate ATP.

Another compound similar to Taurocyamine is Guanidinoacetic acid. Guanidinoacetic acid is a precursor of Creatine and is involved in the synthesis of Creatine in the body. It is an important molecule for energy metabolism and is commonly found in the muscles and brain.

A third compound with a similar molecular structure to Taurocyamine is Agmatine. Agmatine is a byproduct of Arginine and is involved in various physiological processes in the body. It has been shown to have neuroprotective, antidepressant, and antioxidant properties. Agmatine is also believed to play a role in the regulation of nitric oxide synthesis.