BOC-TRANS-4-FLUORO-L-PROLINE CAS 203866-14-2: A Key Fluorinated Building Block for Pharmaceutical Synthesis and Research
Discover the critical role of BOC-TRANS-4-FLUORO-L-PROLINE, a vital fluorinated pharmaceutical intermediate, in advancing drug discovery and synthesis. Explore its applications in developing life-saving therapeutics.
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Boc-trans-4-fluoro-L-proline
As a leading supplier in China, we offer BOC-TRANS-4-FLUORO-L-PROLINE, a crucial fluorinated pharmaceutical intermediate. Its unique structure and Boc protection make it indispensable for sophisticated organic synthesis, particularly in the development of advanced pharmaceuticals. We provide high-purity intermediates to support your research and manufacturing needs.
- Utilize this fluorinated pharmaceutical intermediate in the synthesis of potent dipeptidyl peptidase IV inhibitors for type 2 diabetes treatment.
- Leverage BOC-TRANS-4-FLUORO-L-PROLINE in the creation of pyrrolotriazines derivatives, vital anti-tumor agents.
- Incorporate this chiral building block into your peptide synthesis to enhance stability and bioactivity.
- Explore its applications in creating 19F NMR probes for enantiomeric purity analysis.
Advantages Offered by the Product
Enhanced Therapeutic Efficacy
The fluorine substitution in BOC-TRANS-4-FLUORO-L-PROLINE can significantly improve the metabolic stability and bioavailability of drug candidates, leading to better therapeutic outcomes in medicinal chemistry.
Precise Molecular Design
The presence of the Boc protecting group allows for controlled, site-specific reactions, enabling chemists to construct complex molecular architectures with high precision, crucial for drug discovery.
Versatile Synthesis Intermediate
This compound serves as a versatile chiral building block, opening avenues for synthesizing a wide range of biologically active molecules, including peptide-based therapeutics and novel inhibitors.
Key Applications
Pharmaceutical Synthesis
BOC-TRANS-4-FLUORO-L-PROLINE is a cornerstone for synthesizing complex APIs, contributing to the development of new treatments for various diseases.
Drug Discovery
Its unique fluorinated structure aids researchers in exploring novel chemical entities and understanding structure-activity relationships in drug discovery programs.
Peptide Engineering
This building block is employed to introduce specific modifications into peptides, aiding in the study of protein folding, function, and the development of peptide-based drugs.
Chemical Research
As a valuable chiral building block, it supports advancements in organic chemistry and the creation of innovative compounds for diverse research applications.