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Cyanide-catalyzed benzoin condensation

The mechanism of the cyanide- and thioazolium ion-catalyzed conjugate addition reactions is considered to be analogous to the Lapworth mechanism for the cyanide-catalyzed benzoin condensation. Thus the cyano-stabilized carbanion resulting from deprotonation of the cyanohydrin of the aldehyde is presumed to be the actual Michael donor. After conjugate addition to the activated olefin, cyanide is eliminated to form the product and regenerate the catalyst. [Pg.165]

Finally, other important contributions that should be cited as very relevant with regard to the evolution of the organocatalysis field are those related to the use of stable A-heterocyclic carbenes as catalysts. The basis of this chemistry also finds its roots at the very early beginnings of organic synthesis, in particular in the well-known cyanide-catalyzed benzoin condensation by Liebig and Wholer, and... [Pg.8]

The reaction of two molecules of benzaldehyde to form benzoin is generally referred to as the benzoin condensation. It is normally catalyzed by cyanide ion, although thiazolium ions will also catalyze it, as we have discussed above and shown in Fig. 1.2. The normal solvent for the benzoin condensation is ethanol, to dissolve all the components of the reaction. However, it seemed to us likely that there would be overlap of the phenyl rings in the transition state for the benzoin condensation, and thus that reaction in water could lead to hydrophobic accelerations. This proved to be the case. We saw that the rate of the cyanide-catalyzed benzoin condensation was 200-fold faster in water than in ethanol. Also, we saw that added LiCl increased the reaction rate, while added lithium perchlorate decreased it. Such salt effects are diagnostic of the presence of some acceleration by hydrophobic packing in the transition state for the reaction. [Pg.17]

The effects of inorganic salts on the rate of the aqueous cyanide-catalyzed benzoin condensation were discussed in terms of stabilization or destabilization of the water structure (Kool and Breslow, 1988) ... [Pg.131]

Two related modifications have been developed to provide cross-benzoin products not accessible under classical benzoin condensation conditions. In the first approach, one aldehyde partner is converted to a cyanohydrin derivative which serves as the stoichiometric equivalent of intermediate 3a on the catalytic cycle of the cyanide-catalyzed benzoin condensation. A number of cyanohydrin derivatives can be used, with the most popular being the O-silyl cyanohydrin 14, first reported by Hiinig and Wehner. In a subsequent step, the cyanohydrin derivative is treated with stoichiometric base followed by the second aldehyde to give the silylated cross-benzoin product 16 in high yield. [Pg.385]

ALkah metal cyanides catalyze the condensation of benzaldehyde to form benzoin. [Pg.33]

This procedure is representative of a new general method for the preparation of noncyclic acyloins by thiazol ium-catalyzed dimerization of aldehydes in the presence of weak bases (Table I). The advantages of this method over the classical reductive coupling of esters or the modern variation in which the intermediate enediolate is trapped by silylation, are the simplicity of the procedure, the inexpensive materials used, and the purity of the products obtained. For volatile aldehydes such as acetaldehyde and propionaldehyde the reaction Is conducted without solvent in a small, heated autoclave. With the exception of furoin the preparation of benzoins from aromatic aldehydes is best carried out with a different thiazolium catalyst bearing an N-methyl or N-ethyl substituent, instead of the N-benzyl group. Benzoins have usually been prepared by cyanide-catalyzed condensation of aromatic and heterocyclic aldehydes.Unsymnetrical acyloins may be obtained by thiazol1um-catalyzed cross-condensation of two different aldehydes. -1 The thiazolium ion-catalyzed cyclization of 1,5-dialdehydes to cyclic acyloins has been reported. [Pg.173]

Although the catalysis of the dimerization of aldehydes to acyloins by thiazolium ion has been known for some tlrae, the development of procedures using anhydrous solvents which give satisfactory yields of acyloins on a preparative scale was first realized in the submitters laboratories. The mechanism proposed by Breslow - for the thiazolium ion-catalyzed reactions is similar to the Lapworth mechanism for the benzoin condensation with a thiazolium ylide replacing the cyanide ion. Similar mechanisms are involved... [Pg.173]

Acyloins (a-hydroxy ketones) are formed enzymatically by a mechanism similar to the classical benzoin condensation. The enzymes that can catalyze reactions of this type arc thiamine dependent. In this sense, the cofactor thiamine pyrophosphate may be regarded as a natural- equivalent of the cyanide catalyst needed for the umpolung step in benzoin condensations. Thus, a suitable carbonyl compound (a -synthon) reacts with thiamine pyrophosphate to form an enzyme-substrate complex that subsequently cleaves to the corresponding a-carbanion (d1-synthon). The latter adds to a carbonyl group resulting in an a-hydroxy ketone after elimination of thiamine pyrophosphate. Stereoselectivity of the addition step (i.e., addition to the Stand Re-face of the carbonyl group, respectively) is achieved by adjustment of a preferred active center conformation. A detailed discussion of the mechanisms involved in thiamine-dependent enzymes, as well as a comparison of the structural similarities, is found in references 1 -4. [Pg.672]

Cyanide-catalyzed condensation of aryl aldehyde to benzoin. Now cyanide is mostly replaced by a thiazolium salt. Cf. Stetter reaction. [Pg.47]

Acyloin condensations. Formaldehyde in the presence of 1 undergoes selfcondensation to form dihydroxyacetone (a triose) in high yield rather than the expected glycolaldehyde.1 Surprisingly, the condensation of formaldehyde and another aldehyde catalyzed by 1 in the presence of N(C2H5)3 results almost exclusively in a l-hydroxy-2-one, RCOCH2OH. Sodium cyanide, a known catalyst for benzoin condensations, is not effective for the condensation of formaldehyde and benzal-dehyde in the presence of N(C2H5)3.2... [Pg.130]

Propose a mechanism for the benzoin condensation, which is specifically catalyzed by cyanide ... [Pg.460]

The Stetter Reaction is a 1,4-addition (conjugate addition) of an aldehyde to an a,p-unsaturated compound, catalyzed by cyanide or a thiazolium salt. This reaction competes with the corresponding 1,2-addition, which is the Benzoin Condensation. However, the Benzoin-Condensation is reversible, and since the Stetter Reaction leads to more stable products, the main product will be derived from 1,4-addition. [Pg.222]

When, in 1832, Wohler and Liebig first discovered the cyanide-catalyzed coupling of benzaldehyde that became known as the benzoin condensation , they laid the foundations for a wide field of growing organic chemistry [1]. In 1903, Lapworth proposed a mechanistical model with an intermediate carbanion formed in a hydrogen cyanide addition to the benzaldehyde substrate and subsequent deprotonation [2]. In the intermediate active aldehyde , the former carbonyl carbon atom exhibits an inverted, nucleophilic reactivity, which exemplifies the Umpo-lung concept of Seebach [3]. In 1943, Ukai et al. reported that thiazolium salts also surprisingly catalyze the benzoin condensation [4], an observation which attracted even more attention when Mizuhara et al. found, in 1954, that the thiazolium unit of the coenzyme thiamine (vitamin Bi) (1, Fig. 9.1) is essential for its activity in enzyme biocatalysis [5]. Subsequently, the biochemistry of thiamine-dependent enzymes has been extensively studied, and this has resulted in widespread applications of the enzymes as synthetic tools [6]. [Pg.331]

The benzoin condensation catalyzed by N-heterocyclic carbenes has been investigated intensively. First investigations date back to 1832 when Wohler and Liebig discovered the cyanide-catalyzed coupling of benzaldehyde to benzoin (Wohler and Liebig 1832). In 1903 Lapworth postulated a mechanism for this reaction in which an intermediate car-banion is formed by hydrogen cyanide addition to benzaldehyde fol-... [Pg.83]

The reaction of two moles of benzaldehyde to form a new carbon-carbon bond is known as the benzoin condensation. It is catalyzed by two rather different catalysts—cyanide ion and the vitamin thiamine—which, on close examination, are seen to function in exactly the same way. [Pg.467]

Chapter 54 The Benzoin Condensation Cyanide Ion and Thiamine Catalyzed... [Pg.469]

Studies on thiamine (vitamin Bi) catalyzed formation of acyloins from aliphatic aldehydes and on thiamine or thiamine diphosphate catalyzed decarboxylation of pyruvate have established the mechanism for the catalytic activity of 1,3-thiazolium salts in carbonyl condensation reactions. In the presence of bases, quaternary thiazolium salts are transformed into the ylide structure (2), the ylide being able to exert a cat ytic effect resembling that of the cyanide ion in the benzoin condensation (Scheme 2). Like cyanide, the zwitterion (2), formed by the reaction of thiazolium salts with base, is nucleophilic and reacts at the carbonyl group of aldehy s. The resultant intermediate can undergo base-catalyzed proton... [Pg.542]

Benzoin Condensation. This involves the reaction of two molecules of aromatic aldehyde having no a-hydrogen with the formation of an a-hydroxyketone. The reaction is catalyzed by cyanide ion. [Pg.309]

Upon treating certain (but not all) aromatic aldehydes or glyoxals (a-keto aldehydes) with cyanide ion (CN ), benzoins (a-hydroxy-ketones or acyloins) are produced in a reaction called the benzoin condensation. The reverse process is called the retro-benzoin condensation, and it is frequently used for the preparation of ketones. The condensation involves the addition of one molecule of aldehyde to the C=0 group of another. One of the aldehydes serves as the donor and the other serves as the acceptor. Some aldehydes can only be donors (e.g. p-dimethylaminobenzaldehyde) or acceptors, so they are not able to self-condense, while other aldehydes (benzaldehyde) can perform both functions and are capable of self-condensation. Certain thiazolium salts can also catalyze the reaction in the presence of a mild base. This version of the benzoin condensation is more synthetically useful than the original procedure because it works with enolizable and non-enolizable aldehydes and asymmetric catalysts may be used. Aliphatic aldehydes can also be used and mixtures of aliphatic and aromatic aldehydes give mixed benzoins. Recently, it was also shown that thiazolium-ion based organic ionic liquids (Oils) promote the benzoin condensation in the presence of small amounts of triethylamine. The stereoselective synthesis of benzoins has been achieved using chiral thiazolium salts as catalysts. [Pg.54]

See other pages where Cyanide-catalyzed benzoin condensation is mentioned: [Pg.278]    [Pg.259]    [Pg.382]    [Pg.253]    [Pg.420]    [Pg.278]    [Pg.259]    [Pg.382]    [Pg.253]    [Pg.420]    [Pg.359]    [Pg.469]    [Pg.54]    [Pg.351]    [Pg.96]    [Pg.230]    [Pg.25]    [Pg.1397]    [Pg.468]    [Pg.54]    [Pg.681]    [Pg.55]    [Pg.432]   
See also in sourсe #XX -- [ Pg.259 ]

See also in sourсe #XX -- [ Pg.259 ]



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