Product Name:(4-Formylpiperazinyl)-N-(methylpropyl)formamide
IUPAC Name:N-(butan-2-yl)-4-formylpiperazine-1-carboxamide
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Product Overview |
(4-Formylpiperazinyl)-N-(methylpropyl)formamide, commonly known as FMF, is a chemical compound that has gained increasing attention in scientific research for its potential applications in various fields. FMF is a piperazine derivative that has a unique structure and properties, making it a promising candidate for drug discovery and development, as well as other scientific research applications. |
Synthesis and Application |
The synthesis of FMF involves the reaction of piperazine with N-methylpropanamide and formic acid under controlled conditions. The process requires expertise and precision to achieve high yield and purity of the final product. The synthesis method has been optimized and improved over time, allowing for the production of FMF in large quantities for research purposes. FMF has been studied extensively for its potential applications in various fields, including medicinal chemistry, materials science, and biochemistry. In medicinal chemistry, FMF has been investigated as a potential drug candidate for the treatment of various diseases, including cancer, bacterial infections, and neurological disorders. In materials science, FMF has been used as a building block for the synthesis of novel materials with unique properties. In biochemistry, FMF has been studied for its interactions with proteins and enzymes, providing insights into its mechanism of action and potential therapeutic applications. |
Future Directions |
There are several future directions for the study of FMF. One area of focus is the development of new drugs based on FMF, particularly for the treatment of cancer and bacterial infections. Another area of focus is the investigation of FMF's interactions with proteins and enzymes, which could provide insights into its mechanism of action and potential therapeutic applications. Additionally, the synthesis of novel materials based on FMF could lead to the development of new materials with unique properties and applications. Overall, the study of FMF has the potential to lead to significant advances in various fields, making it an exciting area of research. |