2-Fluoro-3-iodo-5-methylpyridine: A Key Heterocyclic Intermediate for Biologically Active Compound Synthesis
Unlock novel therapeutic pathways with this essential building block in pharmaceutical research.
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2-Fluoro-3-iodo-5-methylpyridine
This specialized heterocyclic compound, identified by CAS 153034-78-7, serves as a critical intermediate in the synthesis of advanced pharmaceutical compounds. Its unique structure makes it invaluable for creating molecules with specific biological activities, particularly within the realm of protein kinase inhibitors.
- Leveraging 2-Fluoro-3-iodo-5-methylpyridine synthesis methods allows researchers to efficiently produce complex organic molecules.
- The compound's utility extends to building blocks for pharmaceutical development, enabling the creation of novel drug candidates.
- Explore the diverse CAS 153034-78-7 applications in creating targeted therapies for various diseases.
- As a key component in organic synthesis, it facilitates the development of new chemical entities with high therapeutic potential.
Advantages Offered
Versatile Synthetic Utility
The strategic placement of fluorine and iodine atoms on the pyridine ring provides versatile reactivity, making it an excellent precursor for cross-coupling reactions and further functionalization, essential for heterocyclic building blocks for pharmaceuticals.
Enabling Targeted Therapies
As an intermediate for protein kinase inhibitor development, this compound is instrumental in designing drugs that precisely target disease pathways, offering hope for more effective treatments.
High Purity and Reliability
Supplied with high purity (often 95%min to 99.92%), it ensures reproducible results in complex synthetic routes, critical for pharmaceutical research and development.
Key Applications
Pharmaceutical Intermediates
Crucial for the synthesis of Active Pharmaceutical Ingredients (APIs), particularly in the development of novel therapeutics. Its structure is key to biologically active compound precursors.
Organic Synthesis
Serves as a versatile building block in complex organic chemistry research, enabling the creation of a wide array of novel compounds and materials.
Medicinal Chemistry Research
Utilized in drug discovery programs to explore new chemical spaces and develop compounds with improved efficacy and safety profiles.
Material Science
Potential applications in advanced materials, leveraging its unique chemical structure for specialized properties.