N(epsilon)-Trifluoroacetyl-L-lysine: Your Key Pharmaceutical Intermediate
Discover the high-purity N(epsilon)-Trifluoroacetyl-L-lysine (CAS 10009-20-8), essential for advanced pharmaceutical synthesis.
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N(epsilon)-Trifluoroacetyl-L-lysine
N(epsilon)-Trifluoroacetyl-L-lysine is a vital pharmaceutical intermediate, highly valued for its purity of over 99%. This compound plays a critical role in the synthesis of various Active Pharmaceutical Ingredients (APIs), most notably as a key building block for Angiotensin-Converting Enzyme (ACE) inhibitors such as Lisinopril and Quinapril.
- Facilitate ACE inhibitor synthesis: As a crucial component in the manufacturing process for drugs like Lisinopril, its high purity ensures efficacy.
- Support biochemical research: Its role as an inhibitor of L-lysine cyclodeaminase makes it valuable for scientific studies and understanding metabolic pathways.
- Enable advanced chemical synthesis: The trifluoroacetyl group enhances chemical reactivity and solubility, beneficial for complex organic synthesis.
- Ensure quality and consistency: With a purity degree of 99%, it meets stringent pharmaceutical manufacturing standards, ensuring reliable results.
Advantages You Gain
Uncompromised Purity
Achieve superior results in your pharmaceutical manufacturing with our N(epsilon)-Trifluoroacetyl-L-lysine, guaranteed to be over 99% pure, supporting the development of potent and safe medications.
Versatile Application
This compound serves as an indispensable pharmaceutical intermediate, vital for the synthesis of widely used ACE inhibitors and other complex organic molecules.
Reliable Sourcing
Access a global network of trusted suppliers for N(epsilon)-Trifluoroacetyl-L-lysine, ensuring a stable and dependable supply chain for your production needs.
Key Applications
Pharmaceutical Synthesis
Critical as a pharmaceutical intermediate, particularly in the production of ACE inhibitors, contributing to cardiovascular treatments.
Drug Discovery
A valuable tool in drug discovery for creating novel compounds and studying the biological activity of modified amino acids.
Biochemical Research
Utilized in biochemical studies, including enzyme inhibition and protein modification research, supporting advancements in life sciences.
Organic Synthesis
Its unique chemical structure makes it a versatile reagent in various organic synthesis processes, enabling the creation of complex molecular architectures.