AI Article Synopsis
- The Michael addition has been used for over 130 years but its reversibility, particularly with heteronucleophiles, has been less explored until recently.
- Advances in medicinal chemistry are leveraging reversible hetero-Michael reactions, like thia-Michael and aza-Michael reactions, to create Covalent Adaptable Networks (CANs).
- This review analyzes progress in understanding the thia-Michael reaction and its potential for CANs, while also highlighting the emerging role of the aza-Michael reaction in these applications.
Article Abstract
While the Michael addition has been employed for more than 130 years for the synthesis of a vast diversity of compounds, the reversibility of this reaction when heteronucleophiles are involved has been generally less considered. First applied to medicinal chemistry, the reversible character of the hetero-Michael reactions has recently been explored for the synthesis of Covalent Adaptable Networks (CANs), in particular the thia-Michael reaction and more recently the aza-Michael reaction. In these cross-linked networks, exchange reactions take place between two Michael adducts by successive dissociation and association steps. In order to understand and precisely control the exchange in these CANs, it is necessary to get an insight into the critical parameters influencing the Michael addition and the dissociation rates of Michael adducts by reconsidering previous studies on these matters. This review presents the progress in the understanding of the thia-Michael reaction over the years as well as the latest developments and plausible future directions to prepare CANs based on this reaction. The potential of aza-Michael reaction for CANs application is highlighted in a specific section with comparison with thia-Michael-based CANs.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9609322 | PMC |
| http://dx.doi.org/10.3390/polym14204457 | DOI Listing |
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