(S)-N-(2′,6′-dimethylphenyl)-piperidine-2- carboxylic amide CAS:27262-40-4

(S)-N-(2',6'-dimethylphenyl)-piperidine-2-carboxylic amide, abbreviated as DMPA, exhibits diverse applications primarily in pharmaceutical research and chemical synthesis due to its unique structural and chemical properties: Medicinal Chemistry: DMPA is investigated for its pharmacological potential, particularly in drug discovery and development. Researchers explore its interactions with biological targets and its role in modulating biochemical pathways, aiming to create new therapeutic agents for various medical conditions. Neuroscience Research: DMPA's piperidine core suggests potential neuroactive properties, making it a subject of interest in neuroscience studies. Research efforts include evaluating its effects on neuronal function and its application in neurological disorders. Biological Probes: DMPA serves as a valuable tool in biological research to study protein-ligand interactions and cellular processes. Its chemical structure enables researchers to examine binding affinity and specificity, providing insights into disease mechanisms and pathways. Optical Materials: DMPA contributes to the development of optical materials and sensors due to its structural versatility and potential optical properties. Researchers utilize its molecular structure to design materials suitable for optical devices and sensor technologies. Catalysis: In organic synthesis, DMPA functions as a catalyst or catalyst precursor in various chemical reactions. Its piperidine scaffold and amide group enhance catalytic activity, facilitating the synthesis of complex organic molecules and pharmaceutical intermediates. Industrial Applications: Beyond research, DMPA finds applications in industrial processes such as the production of specialty chemicals and materials. Its role as a building block allows for the creation of advanced materials tailored to industrial needs. In summary, (S)-N-(2',6'-dimethylphenyl)-piperidine-2-carboxylic amide plays a significant role in pharmaceutical research, neuroscience, biological probes, optical materials development, catalysis, and industrial applications. Its distinct chemical structure and potential biological activities make it a versatile compound for advancing scientific knowledge and innovation across various disciplines.