The Ultimate Guide to Diludine: Properties, Applications, and Insights
Diludine, scientifically recognized as diethyl 1,4-dihydro-2,6-dimethyl-3,5-pyridinedicarboxylate, is a compound of growing interest in various fields, including medicinal chemistry and industrial applications. With a CAS number of 1149-23-1, diludine is known for its antioxidant properties and potential uses in pharmaceutical formulations. This comprehensive guide will explore the properties, applications, and various aspects of diludine, providing an in-depth resource for researchers and industry professionals.
Types and Applications of Diludine
| Type | Description | Applications |
|---|---|---|
| Diludine Standard | Pure form used for research and development | Pharmaceutical studies, Antioxidants |
| Diludine Derivatives | Modified versions for enhanced properties | Drug formulation, Chemical synthesis |
| Analytical Standards | Used for calibration in analytical chemistry | Quality control, Lab testing |
| Biochemical Reagents | Used in biochemical assays and experiments | Research in biochemistry, Enzyme studies |
| Industrial Products | Forms used in manufacturing processes | Material science, Chemical production |
Chemical Properties of Diludine
Diludine possesses unique chemical properties that make it suitable for various applications. Its molecular formula is C13H19NO4, and its structure consists of a pyridine ring with diethyl and dimethyl substituents. Understanding these properties is crucial for optimizing its use in different contexts.
Molecular Structure
The molecular structure of diludine features a pyridine nucleus, which is known for its stability and reactivity. The presence of multiple functional groups provides opportunities for further chemical modifications, enhancing its versatility.
Solubility and Stability
Diludine exhibits good solubility in organic solvents, which is beneficial for formulations in pharmaceuticals and chemical processes. Its stability under various conditions allows it to be stored and handled with relative ease, making it a viable option for long-term applications.
Applications in Medicine
Diludine’s antioxidant properties have garnered interest in the medical field, particularly in the development of therapeutic agents. Research has shown its potential in combating oxidative stress, which is linked to various diseases.
Antioxidant Properties
As an antioxidant, diludine can neutralize free radicals, thus protecting cells from damage. This property makes it a candidate for research in areas like neuroprotection, cardiovascular health, and anti-aging treatments.
Pharmaceutical Development
In pharmaceutical development, diludine can serve as a lead compound for the synthesis of novel drugs. Its ability to interact with biological systems presents opportunities for creating medications that target specific pathways.
Industrial Applications
Beyond its medicinal uses, diludine finds applications in industrial settings. Its chemical properties lend themselves to various manufacturing processes, particularly those involving the synthesis of complex organic compounds.
Chemical Synthesis
Diludine is utilized in the synthesis of other chemicals, thanks to its reactive functional groups. This aspect is particularly advantageous in the production of specialty chemicals and intermediates for larger-scale manufacturing.
Material Science
In the field of material science, diludine and its derivatives can be incorporated into polymers and other materials to enhance their properties. This application is crucial for developing advanced materials with tailored characteristics.
Technical Comparison of Diludine Features
| Feature | Diludine | Standard Reference |
|---|---|---|
| CAS Number | 1149-23-1 | – |
| Molecular Formula | C13H19NO4 | – |
| Molecular Weight | 251.30 g/mol | – |
| Solubility | Soluble in organic solvents | – |
| Stability | Stable under standard conditions | – |
Conclusion
In conclusion, diludine is a compound with significant potential across various fields, particularly in medicine and industry. Its antioxidant properties and versatility in chemical synthesis make it an important candidate for further research and application. Understanding its properties, types, and applications can lead to innovative solutions in pharmaceutical development and material science.
FAQ
What is diludine?
Diludine, or diethyl 1,4-dihydro-2,6-dimethyl-3,5-pyridinedicarboxylate, is a chemical compound known for its antioxidant properties and potential applications in pharmaceuticals and industrial chemistry.
What are the main applications of diludine?
Diludine is primarily used in pharmaceutical development as an antioxidant, in chemical synthesis for producing other compounds, and in material science for enhancing material properties.
How does diludine function as an antioxidant?
Diludine neutralizes free radicals in the body, which helps protect cells from oxidative damage, potentially reducing the risk of various diseases.
Where can I find more information about diludine?
You can find more information about diludine on scientific databases like PubChem (pubchem.ncbi.nlm.nih.gov), Chemsrc (www.chemsrc.com), and various chemical suppliers like Sigma-Aldrich (www.sigmaaldrich.com) and MedChemExpress (www.medchemexpress.com).
Is diludine safe to use in pharmaceuticals?
While diludine shows promise in pharmaceutical applications, safety and efficacy must be evaluated in clinical studies before it can be deemed safe for widespread use.
What is the molecular weight of diludine?
The molecular weight of diludine is approximately 251.30 g/mol.
Can diludine be modified for enhanced properties?
Yes, diludine can be chemically modified to create derivatives with enhanced properties, making it a versatile compound for research and application.
What role does diludine play in material science?
In material science, diludine can be incorporated into polymers and other materials to improve their characteristics, leading to the development of advanced materials.
How is diludine synthesized?
Diludine can be synthesized through various chemical reactions involving pyridine derivatives and carboxylic acids, often requiring specific catalysts and conditions.
What are some potential future applications of diludine?
Future applications of diludine may include its use in novel drug formulations, advanced materials for electronics, and further development in antioxidant therapies for age-related diseases.