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Prolines ketones

Enamines derived from ketones are allylated[79]. The intramolecular asymmetric allylation (chirality transfer) of cyclohexanone via its 5-proline ally ester enamine 120 proceeds to give o-allylcyclohexanone (121) with 98% ee[80,8l]. Low ee was observed in intermolecular allylation. Similarly, the asymmetric allylation of imines and hydrazones of aldehydes and ketones has been carried out[82]. [Pg.308]

Since most often the selective formation of just one stereoisomer is desired, it is of great importance to develop highly selective methods. For example the second step, the aldol reaction, can be carried out in the presence of a chiral auxiliary—e.g. a chiral base—to yield a product with high enantiomeric excess. This has been demonstrated for example for the reaction of 2-methylcyclopenta-1,3-dione with methyl vinyl ketone in the presence of a chiral amine or a-amino acid. By using either enantiomer of the amino acid proline—i.e. (S)-(-)-proline or (/ )-(+)-proline—as chiral auxiliary, either enantiomer of the annulation product 7a-methyl-5,6,7,7a-tetrahydroindan-l,5-dione could be obtained with high enantiomeric excess. a-Substituted ketones, e.g. 2-methylcyclohexanone 9, usually add with the higher substituted a-carbon to the Michael acceptor ... [Pg.242]

An excellent synthetic method for asymmetric C—C-bond formation which gives consistently high enantioselectivity has been developed using azaenolates based on chiral hydrazones. (S)-or (/ )-2-(methoxymethyl)-1 -pyrrolidinamine (SAMP or RAMP) are chiral hydrazines, easily prepared from proline, which on reaction with various aldehydes and ketones yield optically active hydrazones. After the asymmetric 1,4-addition to a Michael acceptor, the chiral auxiliary is removed by ozonolysis to restore the ketone or aldehyde functionality. The enolates are normally prepared by deprotonation with lithium diisopropylamide. [Pg.975]

Thus the product in such cases can exist as two pairs of enantiomers. In a di-astereoselective process, one of the two pairs is formed exclusively or predominantly as a racemic mixture. Many such examples have been reported. In many of these cases, both the enolate and substrate can exist as (Z) or (E) isomers. With enolates derived from ketones or carboxylic esters, (E) enolates gave the syn pair of enantiomers (p. 146), while (Z) enolates gave the anti pair. Addition of chiral additives to the reaction, such as proline derivatives, or (—)-sparteine lead to product formation with good-to-excellent asynunetric induction. Ultrasound has also been used to promote asymmetric Michael reactions. Intramolecular versions of Michael addition are well known. ... [Pg.1023]

The values of x = 0.5 and = 1 for the kinetic orders in acetone [1] and aldehyde [2] are not trae kinetic orders for this reaction. Rather, these values represent the power-law compromise for a catalytic reaction with a more complex catalytic rate law that corresponds to the proposed steady-state catalytic cycle shown in Scheme 50.3. In the generally accepted mechanism for the intermolecular direct aldol reaction, proline reacts with the ketone substrate to form an enamine, which then attacks the aldehyde substrate." A reaction exhibiting saturation kinetics in [1] and rate-limiting addition of [2] can show apparent power law kinetics with both x and y exhibiting orders between zero and one. [Pg.451]

The detailed mechanism of this enantioselective transformation remains under investigation.178 It is known that the acidic carboxylic group is crucial, and the cyclization is believed to occur via the enamine derived from the catalyst and the exocyclic ketone. A computational study suggested that the proton transfer occurs through a TS very similar to that described for the proline-catalyzed aldol reaction (see page 132).179... [Pg.139]

Enantioselectivity has been observed for acyclic ketones, using proline as a catalyst. Under optimum conditions, ds > 80% and e.e. > 70% were observed.324 These... [Pg.195]

Catalytic Enantioselective Reduction of Ketones. An even more efficient approach to enantioselective reduction is to use a chiral catalyst. One of the most developed is the oxazaborolidine 18, which is derived from the amino acid proline.148 The enantiomer is also available. These catalysts are called the CBS-oxazaborolidines. [Pg.416]

Lewis-Acid Catalyzed. Recently, various Lewis acids have been examined as catalyst for the aldol reaction. In the presence of complexes of zinc with aminoesters or aminoalcohols, the dehydration can be avoided and the aldol addition becomes essentially quantitative (Eq. 8.97).245 A microporous coordination polymer obtained by treating anthracene- is (resorcinol) with La(0/Pr)3 possesses catalytic activity for ketone enolization and aldol reactions in pure water at neutral pH.246 The La network is stable against hydrolysis and maintains microporosity and reversible substrate binding that mimicked an enzyme. Zn complexes of proline, lysine, and arginine were found to be efficient catalysts for the aldol addition of p-nitrobenzaldehyde and acetone in an aqueous medium to give quantitative yields and the enantiomeric excesses were up to 56% with 5 mol% of the catalysts at room temperature.247... [Pg.268]

Organic-Base Catalyzed. Asymmetric direct aldol reactions have received considerable attention recently (Eq. 8.98).251 Direct asymmetric catalytic aldol reactions have been successfully performed using aldehydes and unmodified ketones together with chiral cyclic secondary amines as catalysts.252 L-proline and 5,5-dimethylthiazolidinium-4-carboxylate (DMTC) were found to be the most powerful amino acid catalysts for the reaction of both acyclic and cyclic ketones as aldol donors with aromatic and aliphatic aldehydes to afford the corresponding... [Pg.268]

Inspired by the proline-catalyzed Robinson annulation pioneered by Wiechert, Hajos, Parrish and coworkers [39], they were able to construct cyclohexanones of type 2-107 with up to four stereogenic centers with excellent enantio- and di-astereoselectivity from unsaturated ketones 2-104 and acyclic (l-ketoesters 2-105 in the presence of 10 mol% phenylalanine-derived imidazohdine catalyst 2-106. The final products can easily be converted into useful cyclohexanediols, as well as y- and e-lactones. [Pg.63]

A very interesting organocatalyzed one-pot Michael addition/aldol condensation/Darzens condensation has been reported for the asymmetric synthesis of epoxy-ketones <06JA5475>. An initial asymmetric Michael condensation between 16 and 17 is catalyzed by proline derivative 18. Intermediate 19 then undergoes an aldol condensation followed by a stereoselective Darzens condensation to provide epoxy-ketone 20 in moderate yield and with surprisingly good enantiomeric excess. [Pg.74]

Aldol-type reactions of nitrones (303) occur with electron-deficient ketones, such as a-keto esters, a, 3-diketones, and trifluoromethyl ketones. These reactions are catalyzed by secondary amines. The use of chiral cyclic amines A1-A7 leads to a-(2-hydroxyalkyl)nitrones (304) in moderate yields and rather high optical purity (Scheme 2.120) (381). The mechanism of the nitrone-aldol reaction of iV-methyl-C-ethyl nitrone with dimethyl ketomalonate in the absence and presence of L- proline has been studied by using density functional theory (DFT) (544). [Pg.228]

Synthesis of the common intermediate C (4), and its further conversion to 2 and 3 is illustrated in Scheme 7-3. Two racemic compounds, ( )-7 and ( + )-10, are prepared from readily available starting materials 5 and 8, respectively (Scheme 7-2). Coupling of 7 and 10 gives a mixture of diastereomers 11. An intramolecular aldol reaction of 11 catalyzed by D-proline yields diastereomers 12 and 13 in equal molar ratios (about 36% ee for each diastereomer). Compound 12, the desired ketone, is converted to 14, which is further purified by crystallization to give the compound in the desired stereochemistry in sterically pure form. Reduction of the ketone carbonyl group and subsequent methoxy... [Pg.398]

Once the functionalized proline (116) was in place, it could be converted to the desired indolizidine ring system using several steps, which included a Wacker oxidation, to generate a methyl ketone... [Pg.300]

The Baylis-Hillman reaction (Scheme 3) of ethyl vinyl ketone with electron-deficient aromatic aldehydes (e.g. where R = 0-NO2C6H4), in MeCN or EtCN solution, has been found to proceed enantioselectively in presence of catalytic base (32) derived from proline. The Michael adduct formed between the catalyst and the vinyl... [Pg.357]

At present, one of the most successful catalysts for enamine activation has been proline (2). Proline is a cheap, widely and commercially available amino acid that can be found in both enantiomeric forms and, as such, represents a remarkable synthetic alternative to many established asymmetric catalysts. Given such attractive features, it has become the catalyst of choice for many enamine-catalyzed processes. However, various more recent studies have demonstrated that proline is not a universal catalyst for transformations that involve the a-functionalization of ketone or aldehyde carbonyls. Indeed, these studies have demonstrated that the iminium catalysts developed by MacMillan (imidazolidinones) and Jprgensen (pyrrolidines) are also highly effective for enamine activation with respect to... [Pg.326]

Typical starting materials, catalysts, and products of the enamine-catalyzed aldol reaction are summarized in Scheme 17. In proline-catalyzed aldol reactions, enantioselectivities are good to excellent with selected cyclic ketones, such as cyclohexanone and 4-thianone, but generally lower with acetone. Hindered aldehyde acceptors, such as isobutyraldehyde and pivalaldehyde, afford high enantioselectivities even with acetone. In general, the reactions are anti selective, but there are aheady a number of examples of syn selective enamine aldol processes [200, 201] (Schemes 17 and 18, see below). However, syn selective aldol reactions are still rare, especially with cychc ketones. [Pg.44]

Ketone donors bearing a-heteroatoms are particularly useful donors for the enamine-catalyzed aldol reactions (Scheme 18). Both anti and syn aldol products can be accessed in remarkably high enantioselectivities using either proline or proline-derived amide, sulfonamide, or peptide catalysts. The syn selective variant of this reaction was discovered by Barbas [179]. Very recently, Luo and Cheng have also described a syn selective variant with dihydroxyacetone donors [201], and the Barbas group has developed improved threonine-derived catalysts 71 (Scheme 18) for syn selective reactions with both protected and unprotected dihydroxyacetone [202]. [Pg.45]

The first asymmetric enamine-catalyzed Mannich reactions were described by List in 2000 [208]. Paralleling the development of the enamine-catalyzed aldol reactions, the first asymmetric Mannich reactions were catalyzed by proline, and a range of cyclic and acyclic aliphatic ketones were used as donors (Schemes 24 and 25). In contrast to the aldol reaction, however, most Mannich reactions are syn selective. This is presumably due to the larger size of the imine acceptor, forcing the imine and the enamine to approach each other in a different manner than is possible with aldehyde acceptors (Scheme 23). [Pg.51]

Since the initial studies, the substrate scope has expanded to include heteroatom-substituted ketones [208-216], cyclic ketones [217] and aldehydes [211, 218-226] as donors, and formaldehyde-derived imines [218, 227-232] as well as glyoxylate-derived imines [96, 220, 233-237] as acceptors. In addition, several alternative catalysts to proline have been pursued [238-242]. [Pg.51]

Enamine nucleophiles react readily with soft conjugated electrophiles, such as a, 3-unsaturated carbonyl, nitro, and sulfonyl compounds [20-22], Both aldehydes and ketones can be used as donors (Schemes 27 and 28). These Michael-type reactions are highly useful for the construction of carbon skeletons and often the yields are very high. The problem, however, is the enantioselectivity of the process. Unlike the aldol and Mannich reactions, where even simple proline catalyst can effectively direct the addition to the C = O or C = N bond by its carboxylic acid moiety, in conjugate additions the charge develops further away from the catalyst (Scheme 26) ... [Pg.54]

Highly enantioselective organocatalytic Mannich reactions of aldehydes and ketones have been extensively stndied with chiral secondary amine catalysts. These secondary amines employ chiral prolines, pyrrolidines, and imidazoles to generate a highly active enamine or imininm intermediate species [44], Cinchona alkaloids were previonsly shown to be active catalysts in malonate additions. The conjngate addition of malonates and other 1,3-dicarbonyls to imines, however, is relatively nnexplored. Snbseqnently, Schans et al. [45] employed the nse of Cinchona alkaloids in the conjngate addition of P-ketoesters to iV-acyl aldimines. Highly enantioselective mnltifnnctional secondary amine prodncts were obtained with 10 mol% cinchonine (Scheme 5). [Pg.152]

As previously noted (Scheme 1), prior to the explosion of interest in iminium ion catalysis as a platform for the activation of a,P-unsaturated carbonyl compounds in 2000, Yamaguchi [29-33] and Taguchi [34] showed that proline derived bi-func-tional catalysts could provide an effective platform for the ion-pair controlled conjugate addition of malonates and nitroalkanes to a, 3-unsaturated ketones with good levels of stereocontrol. [Pg.299]

Hanessian described the facile addition of cyclic and acyclic nitroalkanes to cyclic a,P-unsaturated ketones using L-proline 58 as the catalyst (3-7 mol%) in the presence of 2,5-dimethylpiperazine [100], The reactions proceeded efficiently at room temperature and consistently provided adduct 59 with increased levels of enantioselectivity when compared with the rubidium prolinate method disclosed by Yamaguchi [29] (Scheme 24). The presence of trace amounts of water in the reaction was found to be essential, suggesting a hydrolytic step is involved in the catalytic... [Pg.301]

Improvements in the enantioselectivities were observed using benzodiazepine 130 and L-proline (58) which catalysed the reaction of methyl vinyl ketone and a small... [Pg.320]

The most efficient catalyst system for the Morita-Baylis-Hillman reaction of methyl vinyl ketone has been reported by Miller [183, 184], Use of L-proline (58) (10 mol%) in conjunction with the A-methyl imidazole containing hexapeptide 131 (10 mol%) provided an efficient platform for the reaction of 125 with a series of aromatic aldehydes 127 (52-95% yield 45-81% ee) (Scheme 52). Importantly, it was shown that the absolute configuration of the proline catalyst was the major factor in directing the stereochemical outcome of the reaction and not the complex peptide backbone. [Pg.321]


See other pages where Prolines ketones is mentioned: [Pg.18]    [Pg.437]    [Pg.164]    [Pg.1037]    [Pg.1223]    [Pg.269]    [Pg.161]    [Pg.95]    [Pg.28]    [Pg.1308]    [Pg.256]    [Pg.111]    [Pg.250]    [Pg.324]    [Pg.327]    [Pg.327]    [Pg.328]    [Pg.329]    [Pg.60]    [Pg.67]    [Pg.286]    [Pg.320]   
See also in sourсe #XX -- [ Pg.291 , Pg.292 , Pg.293 ]




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Prolines 3-hydroxy ketone donor

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