Understanding the Chemical Properties of CAS 479-18-5 Diprophylline

Table of Contents

• 1. Introduction to Diprophylline


• 2. Chemical Structure of CAS 479-18-5


• 3. Physical Properties of Diprophylline


• 4. Chemical Properties of Diprophylline


• 5. Applications of Diprophylline


• 6. Safety and Handling of Diprophylline


• 7. Regulatory Status of CAS 479-18-5


• 8. Conclusion


• 9. Frequently Asked Questions

1. Introduction to Diprophylline

Diprophylline, recognized by its CAS number 479-18-5, is a compound that falls within the category of **biochemical substances**. Its importance in both pharmaceutical and research applications cannot be overstated. This article aims to provide a thorough understanding of the **chemical properties, applications, and safety considerations** associated with Diprophylline.

2. Chemical Structure of CAS 479-18-5

The chemical structure of Diprophylline is critical to its functionality and utility. Composed of a unique arrangement of atoms, it features the following attributes:

2.1 Molecular Formula

The molecular formula of Diprophylline is **C13H17N5O3**, indicating the presence of carbon, hydrogen, nitrogen, and oxygen atoms.

2.2 Structural Diagram

While a textual description suffices, the **structural diagram** of Diprophylline highlights its **functional groups** and **stereochemistry**, which play a significant role in its reactivity and interactions with biological systems.

3. Physical Properties of Diprophylline

Understanding the physical properties of Diprophylline is essential for its application in various fields. Key physical attributes include:

3.1 Melting Point

Diprophylline exhibits a melting point range between **150-155°C**, indicating its stability under standard laboratory conditions.

3.2 Solubility

This compound is soluble in **water and alcohol**, making it accessible for various laboratory applications and formulations.

3.3 Appearance

In its pure form, Diprophylline appears as a **white to off-white crystalline powder**, which is indicative of its purity and quality in biochemical applications.

4. Chemical Properties of Diprophylline

The chemical properties of Diprophylline dictate its reactivity and applicability in different contexts. Understanding these properties can aid in both research and practical applications.

4.1 Reactivity

Diprophylline is relatively stable under neutral conditions. However, it may react with strong acids or bases, leading to potential degradation or alteration of its properties.

4.2 pH Stability

This compound displays stability across a pH range of **5-7**, making it suitable for biological environments where it may be utilized.

4.3 Chemical Stability

Diprophylline exhibits good chemical stability, with minimal degradation when stored under recommended conditions. Proper storage is crucial to maintain its efficacy.

5. Applications of Diprophylline

Diprophylline's versatility allows for a wide array of applications across various sectors. Here are some notable uses:

5.1 Pharmaceutical Applications

Diprophylline serves as a key ingredient in several **pharmaceutical formulations** due to its bronchodilator properties, making it beneficial for treating respiratory conditions.

5.2 Research Uses

In biochemical research, Diprophylline is often involved in studies related to **cell signaling and metabolic pathways**, providing insights into complex biological processes.

5.3 Agricultural Applications

The compound is being explored for its potential use in agriculture, particularly in formulations aimed at enhancing plant growth and resilience.

6. Safety and Handling of Diprophylline

Ensuring the safe handling of chemical compounds like Diprophylline is paramount. Adhering to safety protocols minimizes risk and ensures safe usage in laboratory and industrial settings.

6.1 Personal Protective Equipment (PPE)

When handling Diprophylline, it is recommended to wear appropriate **PPE**, including gloves, goggles, and lab coats, to prevent exposure.

6.2 First Aid Measures

In case of exposure, it is essential to follow established first aid measures. This may include rinsing affected areas with water and seeking medical attention if necessary.

7. Regulatory Status of CAS 479-18-5

The regulatory status of Diprophylline is essential for its use in commercial and research applications. It is important to be aware of the regulations governing its use to ensure compliance.

7.1 Regulatory Agencies

Various regulatory agencies, such as the **FDA and EPA**, oversee the use of Diprophylline in pharmaceuticals and other applications, ensuring safety and efficacy standards are met.

7.2 Compliance Requirements

Entities utilizing Diprophylline must adhere to specific compliance requirements, including proper labeling, safety data sheets, and storage guidelines as mandated by regulatory authorities.

8. Conclusion

In summary, understanding the **chemical properties** of CAS 479-18-5 Diprophylline is vital for its effective application in multiple fields. From its structural characteristics to its safety protocols, this compound proves to be a significant player in the biochemical landscape. Emphasizing its practical applications enhances our comprehension of its role in both pharmaceuticals and research, highlighting the importance of ongoing studies in this area.

9. Frequently Asked Questions

9.1 What is Diprophylline used for?

Diprophylline is primarily used in pharmaceutical applications, especially for its bronchodilator properties in treating respiratory ailments.

9.2 Is Diprophylline safe to handle?

Yes, Diprophylline is safe to handle when proper safety procedures and personal protective equipment are used.

9.3 What are the storage requirements for Diprophylline?

Diprophylline should be stored in a cool, dry place, away from direct sunlight and incompatible substances.

9.4 Can Diprophylline be used in agriculture?

Yes, research is being conducted to explore its applications in agriculture, particularly in enhancing plant growth.

9.5 What regulations govern the use of Diprophylline?

The use of Diprophylline is regulated by agencies such as the FDA and EPA, which ensure compliance with safety and efficacy standards.