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Reactions benzoin

Benzilic acid rearrangement Benzoin reaction (condensation) Blanc chloromethylation reaction Bouveault-Blanc reduction Bucherer hydantoin synthesis Bucherer reaction Cannizzaro reaction Claisen aldoi condensation Claisen condensation Claisen-Schmidt reaction. Clemmensen reduction Darzens glycidic ester condensation Diazoamino-aminoazo rearrangement Dieckmann reaction Diels-Alder reaction Doebner reaction Erlenmeyer azlactone synthesis Fischer indole synthesis Fischer-Speior esterification Friedel-Crafts reaction... [Pg.1210]

The triazole 76, which is more accurately portrayed as the nucleophilic carbene structure 76a, acts as a formyl anion equivalent by reaction with alkyl halides and subsequent reductive cleavage to give aldehydes as shown (75TL1889). The benzoin reaction may be considered as resulting in the net addition of a benzoyl anion to a benzaldehyde, and the chiral triazolium salt 77 has been reported to be an efficient asymmetric catalyst for this, giving the products (/ )-ArCH(OH)COAr, in up to 86% e.e. (96HCA1217). In the closely related intramolecular Stetter reaction e.e.s of up to 74% were obtained (96HCA1899). [Pg.100]

Benzoin, reaction with chloroform to give 1,1,3 tnchloro n nonane, 45, 104... [Pg.121]

Asymmetric Benzoin Reactions Thiazolium Salt Pre-Catalysts... [Pg.273]

The first asymmetric benzoin reactions were reported by Sheehan and Hannemann nsing chiral thiazolinm salt pre-catalyst 100 of unknown absolute configuration [40], Low yields and enantioselectivities were obtained, and although a wide range of thiazolium salt pre-catalysts have since been studied, of which 101-105 are representative, the enantioselectivities obtained for the condensation of benzaldehyde using thiazolium pre-catalysts are generally poor (Scheme 12.19) [41],... [Pg.273]

Scheme 12.19 Chiral thiazolium pre-catalysts for the asymmetric benzoin reaction... Scheme 12.19 Chiral thiazolium pre-catalysts for the asymmetric benzoin reaction...
Attempted intermolecular cross-benzoin reactions typically generate a thermodynamically controlled mixture of products [50], although several groups including Enders [51], Suzuki [52] and You [53] have utilised catalysts 116-118 for the intramolecular crossed benzoin of keto-aldehydes (Scheme 12.22). [Pg.275]

Scheme 12.22 Asymmetric intramolecular cross-benzoin reactions... Scheme 12.22 Asymmetric intramolecular cross-benzoin reactions...
Suzuki and co-workers recently applied the asymmetric intramolecular benzoin reaction to the synthesis of the homoisoflavonoid (-F)-sappanone B 122 [54]. The authors found that triazolium salt pre-catalyst 120 gave the best results for the... [Pg.275]

Attack by eCN is slow (rate-limiting), while proton transfer from HCN or a protic solvent, e.g. HzO, is rapid. The effect of the structure of the carbonyl compound on the position of equilibrium in cyanohydrin formation has already been referred to (p. 206) it is a preparative proposition with aldehydes, and with simple aliphatic and cyclic ketones, but is poor for ArCOR, and does not take place at all with ArCOAr. With ArCHO the benzoin reaction (p. 231) may compete with cyanohydrin formation with C=C—C=0, 1,4-addition may compete (cf. p. 200). [Pg.212]

Nicolaou and coworkers reported efficient enantioselective syntheses of ( )-kinamycin C (3), ( )-kinamycin F (6), and ( )-kinamycin J (10) [39], Nicolaou s retrosyntheses of these targets are shown in Scheme 3.13. The authors envisioned that all three metabolites could be accessed from the common precursor 82. The a-hydroxyketone function of 82 was envisioned to arise from an intramolecular benzoin reaction of the ketoaldehyde 83. This key bond disconnection would serve to forge the cyclopentyl ring of the kinamycin skeleton. The ketoaldehyde 83 was deconstructed by an Ullmann coupling of the aryl bromide 84 and the a-iodoenone 85. The latter were anticipated to arise from the bromojuglone derivative 86 and the enantiomerically enriched enone 87, respectively. [Pg.54]

Scheme 3.17 Potential mechanism for the carbene-catalyzed benzoin reaction... Scheme 3.17 Potential mechanism for the carbene-catalyzed benzoin reaction...
The benzoin reaction and the reaction of Cannizzaro, which are discussed later, likewise take place because of the tendency of the aldehydes to undergo condensation. The specific catalyst determines in each case the particular way along which the condensation will proceed. [Pg.219]

Tetra-n-butylammonium cyanide is a better catalyst for benzoin condensation reactions than is sodium cyanide, and >70% yields are obtained under mild conditions [63, 64] tetra-ethylammonium cyanide is less effective. Polymer-supported ammonium catalysts have also been used to promote the benzoin reaction and, although yields are only moderate (40-60%), the convenience of removal of the catalyst is an advantage. Use of chiral ammonium groups produces an enantiomeric excess of chiral products from the condensation of benzaldehyde, but furfural tends to produce a racemate [65]. [Pg.270]

The benzoin reaction dates back to 1832 when Wohler and Liebig reported that cyanide catalyzes the formation of benzoin 6 from benzaldehyde 5, a seminal example in which the normal mode of polarity of a functional group was reversed (Eq. 1) [26], This reversal of polarity, subsequently termed Umpolung [27], effectively changes an electrophilic aldehyde into a nucleophilic acyl anion equivalent. [Pg.81]

Scheme 1 Lapworth s proposed mechanism of the benzoin reaction... Scheme 1 Lapworth s proposed mechanism of the benzoin reaction...
Breslow and co-workers elucidated the currently accepted mechanism of the benzoin reaction in 1958 using thiamin 8. The mechanism is closely related to Lapworth s mechanism for cyanide anion catalyzed benzoin reaction (Scheme 2) [28, 29], The carbene, formed in situ by deprotonation of the corresponding thiazolium salt, undergoes nucleophilic addition to the aldehyde. A subsequent proton transfer generates a nucleophilic acyl anion equivalent known as the Breslow intermediate IX. Subsequent attack of the acyl anion equivalent into another molecule of aldehyde generates a new carbon - carbon bond XI. A proton transfer forms tetrahedral intermediate XII, allowing for collapse to produce the a-hydroxy ketone accompanied by liberation of the active catalyst. As with the cyanide catalyzed benzoin reaction, the thiazolylidene catalyzed benzoin reaction is reversible [30]. [Pg.82]

In 2002, Enders and co-workers took advantage of the bicyclic restriction first introduced by keeper and Rawal to develop catalyst 20. Use of this catalyst provides a number of benzoin derivatives 22a-h in up to 95% ee (Table 1) [41]. The stereochemistry of the benzoin reaction catalyzed by thiazolium and triazo-lium pre-catalysts has subsequently been modeled by Honk and Dudding [42]. [Pg.84]

Table 1 Substrate scope of the asymmetric benzoin reaction [FXl]... Table 1 Substrate scope of the asymmetric benzoin reaction [FXl]...
The benzoin reaction typically consists of the homocoupling of two aldehydes, which results in the formation of inherently dimeric compounds, therefore limiting the synthetic utility. The aoss-benzoin reaction has the potential to produce four products, two homocoupled adducts and two cross-benzoin products. Several strategies have been employed to develop a selective cross-benzoin reaction, including the use of donor-acceptor aldehydes, acyl silanes, acyl imines, as well as intramolecular reactions. [Pg.84]

Miiller and co-workers have developed an enantioselective enzymatic crossbenzoin reaction (Table 2) [43, 44], This is the first example of an enantioselective cross-benzoin reaction and takes advantage of the donor-acceptor concept. This transformation is catalyzed by thiamin diphosphate (ThDP) 23 in the presence of benzaldehyde lyase (BAL) or benzoylformate decarboxylase (BFD). Under these enzymatic reaction conditions the donor aldehyde 24 is the one that forms the acyl anion equivalent and subsequently attacks the acceptor aldehyde 25 to provide a variety of a-hydroxyketones 26 in good yield and excellent enantiomeric excesses without contamination of the other cross-benzoin products 27. The authors chose 2-chlorobenzaldehyde 25 as the acceptor because of its inability to form a homodimer under enzymatic reaction conditions. [Pg.85]


See other pages where Reactions benzoin is mentioned: [Pg.73]    [Pg.268]    [Pg.273]    [Pg.274]    [Pg.275]    [Pg.280]    [Pg.213]    [Pg.56]    [Pg.213]    [Pg.77]    [Pg.77]    [Pg.81]    [Pg.83]    [Pg.83]    [Pg.84]    [Pg.84]   
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See also in sourсe #XX -- [ Pg.25 ]

See also in sourсe #XX -- [ Pg.26 ]

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See also in sourсe #XX -- [ Pg.12 , Pg.35 , Pg.200 , Pg.555 ]

See also in sourсe #XX -- [ Pg.400 ]

See also in sourсe #XX -- [ Pg.12 ]

See also in sourсe #XX -- [ Pg.147 ]




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Asymmetric benzoin reaction

Aza-benzoin reactions

Aza-cross-benzoin reaction

Benzoin

Benzoin and Related Reactions

Benzoin condensation Stetter reaction

Benzoin condensation reaction

Benzoin reaction intramolecular crossed

Benzoin reactions catalysis

Benzoin reactions cyclization

Benzoin reactions, carbene catalysis

Benzoin reactions, organocatalysis

Benzoin, 2,4-dihydroxydeoxyVilsmeier-Haack reaction

Benzoin, reaction with

Benzoin, reaction with chloroform

Cross-benzoin reaction

Cross-benzoin reactions intermolecular

Cross-benzoin reactions intramolecular

Diels-Alder-benzoin reaction

Enantioselectivity cross-benzoin reaction

Homo-benzoin reaction

Intramolecular reactions crossed-benzoin condensation

Michael-benzoin reaction

Michael-cross-benzoin cyclisation reaction

Reaction Condensation of an Aldehyde by Potassium Cyanide to a Benzoin

Stetter Reaction, Benzoin Condensation and Pinacol Coupling

The Stetter Reaction, Benzoin Condensation, and Pinacol Coupling

Thiamine-Dependent Acyloin and Benzoin Reactions

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