Thiazolium salts, catalysis

Sheehan JC, Hara T (1974) Asymmetric thiazolium salt catalysis of the benzoin condensation. J Org Chem 39 1196-1199... 

Although the chiral auxiliary employed in the stoichiometric aminonitrile chemistry described above can be recycled in good chemical yield and maintaining its optical purity, of course, a more elegant and economical solution would be a catalytic process. Therefore we tried to imitate nature again (scheme 17) by developing an enantioselective thiazolium salt catalysis. 

Scheme 22. First test reactions for an asymmetric Stetter reaction via thiazolium salt catalysis [ ]...

Mechanism of Thiazolium Salt Catalysis in Aldehyde Coupling Step 1. Deprotonation of thiazolium salt Step 2. Nucleophilic attack by catalyst... 

The next coenzyme for which a mechanism was established was thiamin pyrophosphate [3]. Ronald Breslow used nmr spectroscopy to show that the hydrogen atom at C-2 of a thiazolium salt rapidly exchanges with deuterium in even slightly alkaline solutions (6), so that the coenzyme offers an anionic centre for catalysis (Breslow, 1957). With this established, Breslow could confidently offer the pathway shown in Scheme 2 for the action of the... 

Evidence for the intermediacy of the enamine has also been confirmed in some examples involving synthetic utilization of thiazolium salts, for example in the catalysis by thiazolium salts of Michael reactions between aldehydes and a,/ -unsaturated compounds58 (equation 6). 

First attempts of an asymmetric Stetter reaction were made 1989 in our research group with the investigation of chiral thiazolium salts such as 136 as precatalysts. The reaction of n-bu Lanai (133) with chalcone (134) in a two-phase system gave the 1,4-diketone 135 with an enanan-tiomeric excess of 39%, but a low yield of only 4% (Scheme 37) (Tiebes 1990 Enders 1993 Enders et al. 1993b). The catalytic activity of thiazolium as well as triazolium salts in the Stetter reaction persisted at a rather low level. Triazolium salts have been shown to possess a catalytic activity in the non-enantioselective Stetter reaction (Stetter and Kuhlmann 1991), but in some cases stable adducts with Michael acceptors have been observed (Enders et al. 1996a), which might be a possible reason for their failure in catalysis. 

Abstract. N-Heterocyclic carbenes (NHC) have become an important class of organocatalysts and class of ligands for transition-metal catalysis. In organocat-alyzed umpolung reactions, thiazolium salt-derived NHC have been used successfully for decades. Even so, during recent years there has been an increased interest in NHC-catalyzed transformations and many new reactions have been developed. This article focuses on the use of NHC in the conjugate umpolung of ,f>-unsaturated aldehydes. 

Dvorak CA, Rawal VH (1998) Catalysis of benzoin condensation by conforma-tionally-restricted chiral bicyclic thiazolium salts. Tetrahedron Lett 39 2925-2928... 

The deprotonation and addition of a base to thiazolium salts are combined to produce an acyl carbanion equivalent (an active aldehyde) [363, 364], which is known to play an essential role in catalysis of the thiamine diphosphate (ThDP) coenzyme [365, 366]. The active aldehyde in ThDP dependent enzymes has the ability to mediate an efScient electron transfer to various physiological electron acceptors, such as lipoamide in pyruvate dehydrogenase multienzyme complex [367], flavin adenine dinucleotide (FAD) in pyruvate oxidase [368] and Fc4S4 cluster in pyruvate ferredoxin oxidoreductase [369]. 

Kemp, D. S., O Brien, J. T. (1970), Base catalysis of thiazolium salt hydrogen... 

The C-2-exchange of azolium salts via an ylide mechanism was discussed in Section 24.1.2.1. Thiamin pyrophosphate acts as a coenzyme in several biochemical processes and in these, its mode of action depends on the intermediacy of a 2-deprotonated species (32.2.4). In the laboratory, thiazolium salts (3-benzyl-5-(2-hydroxyethyl)-4-methylthiazolium chloride is commercially available) will act as catalysts for the benzoin condensation, and in contrast to cyanide, the classical catalyst, allow such reactions to proceed with alkanals, as opposed to araldehydes the key steps in thiazolium ion catalysis for the synthesis of 2-hydroxy-ketones are shown below and depend on the formation and nucleophilic reactivity of the C-2-ylide. Such catalysis provides acyl-anion equivalents. 

The cyanide-ion catalysis works only for aromatic aldehydes. Aliphatic aldehydes can, however, be condensed to a-hydroxyketone in the presence of thiazolium salts, such as N-dodecylthiazoUum bromide ... 

In 1966, Sheehan reported a remarkable asymmetric benzoin reaction catalyzed by chiral thiazolium salts with moderate levels of enantioselectivity [56-59]. In 2002, Enders and coworkers made an important breakthrough when they reported the first highly enantioselective intermolecular benzoin reaction catalyzed by a triazolium salt derived from ferf-leucine [Eq. (1)] [60]. Since then, catalyst development for NHC catalysis has seen exponential growth for new triazolium salts derived from chiral amino acids and amino alcohols. 

Apart form a great number of chiral NHC carbenes that have been used as ligands in enantioselective transition-metal catalysis (Gade and Bellemin-Laponnanz 2007), some less usual heterazolium salts have been tested in organocatalytic transformations. A planar-chiral thia-zolium salt (Pesch et al. 2004) and a rotaxane-derived precatalyst were reported (Tachibana et al. 2004), as well as catalytically active peptides containing an unnatural thiazolium-substituted alanine amino acid (Fig. 3 Mennen et al. 2005a,b). 

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