Exploring [4-(2-Hydroxyethyl)-piperazin-1-yl]-acetic Acid: A Versatile Chemical Intermediate
Discover the key properties and diverse applications of this essential compound in modern chemical research and industry.
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[4-(2-Hydroxyethyl)-piperazin-1-yl]-acetic Acid
This compound, identified by CAS number 124335-65-5, is a crucial intermediate in various chemical synthesis pathways. Its unique structure, featuring a piperazine ring substituted with a hydroxyethyl group and an acetic acid moiety, makes it highly adaptable for creating more complex molecules. Its utility extends to roles such as a biochemical buffer, maintaining precise pH levels critical for experimental integrity.
- An essential building block in organic synthesis: Leveraging the piperazine core, this compound is instrumental in the development of novel organic molecules, contributing to advancements in medicinal chemistry.
- Key role in biochemical assays: Its buffering capabilities ensure stable pH environments, vital for the integrity and function of biomolecules in research settings, a testament to its buffering agents in biochemistry applications.
- Versatile in coordination chemistry: As a ligand, it facilitates the creation of diverse metal complexes, advancing the understanding of metal-ligand interactions and their potential in catalysis.
- Valuable in pharmaceutical research: Its organic synthesis building blocks nature makes it a sought-after material for the development of new pharmaceutical agents and therapies.
Advantages Offered
Enhanced Molecular Design
The inherent chemical structure of [4-(2-Hydroxyethyl)-piperazin-1-yl]-acetic acid offers multiple reactive sites, enabling researchers to precisely engineer molecular structures and tailor properties for specific applications, supporting piperazine derivatives synthesis.
Reliable pH Control
Its efficacy as a buffering agent ensures consistent and reliable pH maintenance in sensitive biological experiments, directly benefiting uses of 4-(2-Hydroxyethyl)-piperazin-1-yl-acetic acid in life sciences research.
Catalytic Potential
The compound's ability to form stable metal complexes opens avenues for developing new catalysts with improved efficiency and selectivity, aiding chemical synthesis applications.
Key Applications
Organic Synthesis
As a fundamental organic synthesis building block, it's indispensable for constructing complex organic frameworks with desired functional properties.
Biochemical Research
Its role as a biochemical buffer is critical for maintaining stable pH in assays, ensuring accurate results in biological studies.
Coordination Chemistry
Explored for creating novel metal complexes, contributing to advancements in catalysis and materials science, aligning with metal complexes in catalysis.
Pharmaceutical Development
Serves as a key intermediate for pharmaceutical intermediates sourcing and the synthesis of potential therapeutic agents.