This article provides a comprehensive breakdown of CAS 122111-01-7, a chemical compound known as 2-Deoxy-2,2-Difluoro-D-Erythro-Pentafuranous-1-Ullose-3,5-Dibenzoate. The article delves into the chemical structure, properties, applications, and significance of this compound in various fields, offering a detailed analysis that is both informative and accessible to readers with a general interest in chemistry.
CAS 122111-01-7, or 2-Deoxy-2,2-Difluoro-D-Erythro-Pentafuranous-1-Ullose-3,5-Dibenzoate, is a complex organic compound that has garnered attention in the scientific community due to its unique structure and potential applications. This compound is characterized by its difluorinated deoxyribose backbone, which sets it apart from other similar compounds. The purpose of this article is to decode the chemical properties, synthesis, and potential uses of this intriguing molecule.
The chemical structure of CAS 122111-01-7 is quite intricate, featuring a difluorinated deoxyribose backbone with a pentafuranose ring and a 3,5-dibenzoate group. The difluorination of the deoxyribose molecule introduces two fluorine atoms, which can significantly alter the compound's physical and chemical properties. The pentafuranose ring adds complexity to the structure, while the 3,5-dibenzoate group contributes to the compound's solubility and potential biological activity.
The physical properties of CAS 122111-01-7 are influenced by its complex structure. The compound is expected to be solid at room temperature, with a melting point that can be determined through experimental methods. Its solubility in various solvents, such as water, organic solvents, and polar aprotic solvents, is another important physical property that can affect its applications. Additionally, the compound's stability under different conditions, such as temperature and pH, is crucial for its use in various processes.
The synthesis of CAS 122111-01-7 involves a series of chemical reactions that allow for the construction of its complex structure. The process typically starts with the preparation of the difluorinated deoxyribose backbone, followed by the introduction of the pentafuranose ring and the 3,5-dibenzoate group. The choice of synthetic route can significantly impact the yield and purity of the final product, making optimization of the synthesis process a critical aspect of its production.
The unique properties of CAS 122111-01-7 suggest a variety of potential applications. In the pharmaceutical industry, the compound could be explored as a lead molecule for the development of new drugs, particularly those targeting biological processes that involve sugar derivatives. Additionally, its potential use in materials science, such as in the development of novel polymers or coatings, cannot be overlooked. Furthermore, the compound's unique structure may make it a valuable tool in research, serving as a probe for studying the interactions between carbohydrates and other molecules.
The biological significance of CAS 122111-01-7 is an area of active research. The compound's difluorinated deoxyribose backbone and pentafuranose ring may mimic the structure of natural sugars, which could have implications for its interaction with biological molecules. Studies into the compound's potential as an inhibitor or activator of specific enzymes or receptors could lead to new insights into biological processes and the development of novel therapeutic agents.
In conclusion, CAS 122111-01-7, or 2-Deoxy-2,2-Difluoro-D-Erythro-Pentafuranous-1-Ullose-3,5-Dibenzoate, is a fascinating compound with a complex structure and a range of potential applications. Its unique properties, such as the difluorinated deoxyribose backbone and pentafuranose ring, make it a subject of interest in various scientific fields. As research continues to unfold, the true potential of this compound may become more apparent, leading to new discoveries and advancements in science and technology.
CAS 122111-01-7, 2-Deoxy-2,2-Difluoro-D-Erythro-Pentafuranous-1-Ullose-3,5-Dibenzoate, chemical structure, synthesis, applications, biological significance
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