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Miscellaneous reactions
Isomerizations of double bonds and tautomerizations (interconversion of isomers) are useful organic transformations. These also can be enhanced by microwave irradiation. Loupy et al. have used microwave-induced, solvent-free, solid-liquid-phase transfer catalysis (PTC), which employs a salt (in this case, potassium t-butoxide) and a phase transfer catalyst (tetrabutylammoniumbromide, TBAB), to isomerize eugenol to isoeugenol (Scheme 135).708 An example of a microwave-enhanced double bond isomerization followed by enol – keto tautomerization is shown in Scheme 136.10,223
Scheme 135
Scheme 136
Dealkoxycarbonylation, also known as the Krapcho reaction, completely removes an ester group directly from the carbon alpha to a carbonyl. These reactions are difficult to achieve with conductive heating, and they usually require very high temperatures with DMSO as the solvent. Loupy uses PTC with LiBr/TBAB to transform malonic esters to monoesters (Scheme 137).709
Scheme 137
Hydrosilylation of alkenes is another reaction that proceeds poorly with conventional heating. The example shown below in Scheme 138 normally requires 18 hours of thermal heat and provides only a 5% product yield. With six 30-second bursts of microwave irradiation, the 2-vinylpyridine is silylated with a 75% yield of product.381
Scheme 138
The Wittig reaction is probably the most reliable olefin-forming reaction in synthetic organic chemistry. In this reaction, an aldehyde or a ketone reacts with a phosphorus ylide, forming an oxaphosphetane intermediate. The four-membered ring collapses and produces the alkene and a phosphine oxide byproduct. Wittig reactions, traditionally, can require up to 24 hours of reflux in high boiling point solvents. There has been some research performed on the microwave-assisted synthesis of both the Wittig reagent (ylide)710 and the reaction itself 711-719. Scheme 139 exhibits successful Wittig transformations on benzaldehyde derivatives that occurred in five minutes.711
Scheme 139
The Peterson olefination, also known as the silyl-Wittig reaction, utilizes a trialkylsilylmethyl lithium (or magnesium) reagent that adds to a ketone or aldehyde. The β-hydroxysilane intermediate, which can be isolated, eliminates water upon acid or base catalysis. Depending on the stability of the β-hydroxysilane, these reactions can require many hours of reflux. A Peterson reaction in which the silylmethyl anion was generated in situ with cesium fluoride on clay was successful in ten minutes with microwave heating (Scheme 140).721
Scheme 140
The role of microwave synthesis in drug discovery and development will only increase over the next several years. There is a need for a very simple, flexible, and compact microwave system that can be used in synthesis laboratories. As with most new technology, various levels of automation will be demanded and introduced to the market to support needs in drug discovery and library generation. This technology will eventually replace hot plates, heating mantles, and block heaters, allowing chemists to begin using microwave energy on a broad scale, as affordable instrumentation becomes readily available. Academia, drug discovery, and lead optimization are the areas expected to receive the most benefit from this new technology. As microwave synthesis instrumentation continues to evolve, new applications will be developed for a variety of chemistries and process developing needs. This will naturally accelerate as the technology is adopted. Undoubtedly, microwave-enhanced synthesis will be a valuable tool for chemists in a variety of fields and specialties for many years to come.
Instruments
10. Majetich, G.; Hicks, R. “Applications of microwave-accelerated organic synthesis.” Radiat. Phys. Chem. 1995, 45, pp. 567-79.
223. Majetich, G.; Hicks, R. “The use of microwave heating to promote organic reactions.” J. Microwave Power Electromagnetic Energy 1995, 30, pp. 27-45.
381. Abramovitch, R.A.; Abramovitch, D.A.; Iyanar, K.; Tamareselvy, K. “Application of microwave energy to organic synthesis: improved technology.” Tetrahedron Lett. 1991, 32, pp. 5251-54.
708. Loupy, A.; Thach, L.N. “Base-catalyzed isomerization of eugenol: solvent-free conditions and microwave activation.” Synth. Commun. 1993, 23, pp. 2571-77.
709. Loupy, A.; Pigeon, P.; Ramdani, M.; Jacquault, P. “A new solvent-free procedure using microwave technology as an alternative to the Krapcho reaction.” J. Chem. Res. (S) 1993, pp. 36-37.
710. Kiddle, J.J. “Microwave irradiation in organophosphorus chemistry. Part 2: Synthesis of phosphonium salts.” Tetrahedron Lett. 2000, 41, pp. 1339-41.
711. Frattini, S.; Quai, M.; Cereda, E. “Kinetic study of microwave-assisted Wittig reaction of stabilized ylides with aromatic aldehydes.” Tetrahedron Lett. 2001, 42, pp. 6827-29.
712. Westman, J. “An efficient combination of microwave dielectric heating and the use of solid-supported tri-phenylphosphine for Wittig reactions.” Org. Lett. 2001, 3, pp. 3745-48.
713. Chen, M.; Yuan, G.; Yang, S. “A new and facile method for synthesis of aza-Wittig reagents under microwave irradiation.” Synth. Commun. 2000, 30, pp. 1287-94.
714. Murphy, P.J.; Lee, S.E. “Recent synthetic applications of the non-classical Wittig reaction.” J. Chem. Soc., Perkin Trans. 1 1999, pp. 3049-66.
715. Sabitha, G.; Reddy, M.M.; Srinivas, D.; Yadav, J.S. “Microwave irradiation: Wittig olefination of lactones and amides.” Tetrahedron Lett. 1999, 40, pp. 165-66.
716. Fu, C.; Xu, C.; Huang, Z.Z.; Huang, X. “α,β-Unsaturated sulfones by the Wittig reaction of stable ylide with aldehydes under microwave irradiation.” Org. Prep. Proc. Intl. 1997, 29, pp. 587-89.
717. Spinella, A; Fortunati, T.; Soriente, A. “Microwave accelerated Wittig reactions of stablized phosphorus ylides with ketones under solvent-free conditions.” Synlett. 1997, pp. 93-94.
718. Lakhrissi, Y.; Taillefumier, C.; Lakhrissi, M.; Chapleur, Y. “Efficient conditions for the synthesis of C-glycosylidene derivatives: a direct and stereoselective route to C-glycosyl compounds.” Tetrahedron Asymm. 2000, 11, pp. 417-21.
719. Xu, C.; Chen, G.; Fu, C.; Huang, X. “The Wittig reaction of stable ylide and aldehyde under microwave irradiation: synthesis of ethyl cinnamates.” Synth. Commun. 1995, 25, pp. 2229-33.
721. Latouche, R.; Texier-Boullet, F.; Hamelin, J. “Alkali metal fluoride-mediated silyl-Reformatskii reaction in solid-liquid media. Activation by microwaves.” Tetrahedron Lett. 1991, 32, pp. 1179-82.