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Ketones, chiral reagents

The hydride-donor class of reductants has not yet been successfully paired with enantioselective catalysts. However, a number of chiral reagents that are used in stoichiometric quantity can effect enantioselective reduction of acetophenone and other prochiral ketones. One class of reagents consists of derivatives of LiAlH4 in which some of die hydrides have been replaced by chiral ligands. Section C of Scheme 2.13 shows some examples where chiral diols or amino alcohols have been introduced. Another type of reagent represented in Scheme 2.13 is chiral trialkylborohydrides. Chiral boranes are quite readily available (see Section 4.9 in Part B) and easily converted to borohydrides. [Pg.110]

Further progress will undoubtedly involve the preparation of more generally applicable effective reagents, for example for the reduction of dialkyl ketones. Further systematic studies of promising reducing systems as well as increased knowledge of the actual species formed in the reaction of LAH with chiral reagents will be valuable. [Pg.296]

Enantioselective deprotonations of meso substrates such as ketones or epoxides are firmly entrenched as a method in asymmetric synthesis, although the bulk of this work involves stoichiometric amounts of the chiral reagent. Nevertheless, a handful of reports have appeared detailing a catalytic approach to enantioselective deprotonation. The issue that ultimately determines whether an asymmetric deprotonation may be rendered catalytic is a balance of the stoichiometric base s ability... [Pg.294]

Absolute configurations are based on chemical correlation. Maximum optical rotation of the silyl enol ethers are derived from chemical correlation with known compounds whose ec values arc based either on optical rotation, H-NMR spectroscopy in the presence of a chiral shift reagent or on derivatization with chiral reagents. b Ketone/base/(CH3)3SiCl ratio 1 12 5. c In the presence of 1 equiv of HMPA. d At — 90°C. e In the presence of 3 equiv of HMPA. f In the presence of 2 equiv of HMPA. In toluene/HMPA. h At —105 °C. 1 d.r. values. [Pg.599]

When the ketone (65) was treated with the chiral reagent produced by decomposing LiAlH with (S)-2-(anilinomethyl) pyrrolidine, the alcohol (66) obtained in 60 % yield. The optical yield could be determined as 62 % e.e. 95). [Pg.186]

Chiral sulfinimines 236 are very useful intermediates for the preparation of enantiomer-ically pure primary amines 237 (equation 158) . This reaction has been applied to the synthesis of a-amino acids . For sulfinimines obtained from simple ketones, lithium reagents are preferable for the addition , while for cyclic ketones organomagnesium compounds gave the best results. Addition of alkyl and aryl Grignard compounds to sulfinimines, derived from 3- and 4-substituted cyclohexanones, proceeds with excellent diastereoselectivity, depending on the stereochemistry of the ring substituents rather than the sulfinyl group . [Pg.575]

Exercise 19-2 Using equations, show the reactions whereby the following chiral reagents could be used to resolve aldehydes and ketones. (Review Sections 15-4E and 16-4C.)... [Pg.870]

This obviously is unlikely for the given example because there is no reason for cyanide ion to have anything other than an exactly equal chance of attacking above or below the plane of the ethanal molecule, producing equal numbers of molecules of the enantiomers, 21 and 22. However, when a chiral center is created through reaction with a dissymmetric (chiral) reagent, we should not expect an exactly 1 1 mixture of the two possible isomers. For example, in an aldol-type addition (Section 18-8E) of a chiral ester to a pro-chiral ketone the two configurations at the new chiral center in the products 23 and 24 are not equally favored. That is to say, asymmetric synthesis is achieved by the influence of one chiral center (R ) on the development of the second ... [Pg.893]

Two principal approaches to the synthesis of an optically pure chiral secondary or tertiary alcohol from the reaction of an organometallic reagent with an aldehyde or ketone respectively are of current interest. In the first approach an alkyllithium or dialkylmagnesium is initially complexed with a chiral reagent which then reacts with the carbonyl compound. In this way two diastereo-isomeric transition states are generated, the more stable of which leads to an enantiometic excess of the optically active alcohol. This approach is similar in principle to the asymmetric reductions discussed in Section 5.4.1 (see also p. 15). Two chiral catalysts may be noted as successful examples, (10) derived... [Pg.532]

Asymmetric reduction of prochiral ketones. Chiral metal hydrides previously investigated have been effective only for asymmetric reduction of aromatic or a,p-ucclylenic ketones. This new reagent unexpectedly reduces straight-chain aliphatic ketones such as 2-bulanonc and 2-octanone to the corresponding (S)-alcohols in 76%... [Pg.457]

In 2003, Paterson and co-workers reported a second-generation strategy for the synthesis of discodermolide, which aimed to eliminate the use of all chiral reagents and auxiliaries, and reduce the total number of synthetic steps (Scheme 24) [58, 59], These specific aims were achieved by employing an unprecedented aldol coupling at C5-C6 between C1-C5 aldehyde 118 and the advanced C6-C24 methyl ketone 119 and utilising diol 120 as a common precursor for the synthesis of the three subunits 118, 121 (C9-C16) and 98 (C17-C24). [Pg.38]

Several synthetic examples that successfully exploit TK for biocatalytic conversions have been reported. For example, the total synthesis of the beetle pheromone (+)-exo-brevicomin utilizes TK from Baker s yeast as the sole chiral reagent. Starting with racemic 2-hydroxybutanol, the ability of TK to effect kinetic resolution of substrates was exploited (Scheme 5.56). The smooth reaction of 2-hydroxybutanol with HPA was catalyzed by TK at pH 7.5 to yield the enantioenriched ketone in 90% yield. This intermediate was chemically converted into (+)-exo-brevicomin.101... [Pg.320]

Asymmetric reduction of ketones. Chiral ketals 2, obtained by reaction of 1 with prochiral ketones, are reduced diastereoselectively to 3 by several aluminum hydride reagents, the most selective of which is dibromoalane (LiAIHj-AIBr, 1 3). Oxidation and cleavage of the chiral auxiliary furnishes optically active alcohols (4) in optical yields of 78-96% ee (equation 1). [Pg.377]

There are several ways for achieving asymmetric reduction of aldehydes and ketones. For example, a chiral catalyst or chiral reagent can be used for the enantioselective reduction. [Pg.243]

Synthesis of Chiral Reagents. An efficient chiral a-chloro-a-nitroso reagent derived from 10-camphorsulfonyl chloride (1, Cy2NH 2, NH2OH 3. t-BuOCl 70-78%) has been developed for the asymmetric a-amination of ketone enolates (eq 7). The resulting p-keto /V-hydroxylamine can be converted to the anti-1,2-hydro y amine under reducing conditions (NaBHt Zn, HCl, AcOH),... [Pg.177]

Enantioselective Reduction of Imines and Ketoxime O-Ethers. In addition to the reduction of prochiral ketones, chiral oxazaborolidines have been employed as enantioselective reagents and catalysts for the reduction of imines (eq 11) and ketoxime O-ethers (eq 12) - to give chiral amines. It is interesting to note that the enantioselectivity for the reduction of ketoxime O-ethers is opposite that of ketones and imines. For more information, see 2-Amino-3-methyl-l,l-diphenyl-I-butanol. [Pg.511]

Until recently, the preparation of the bicyclic ene-diones (47a,b), which are important intermediates in steroid total synthesis, has led only to racemic mixtures This deficiency has now been met as follows. Michael addition of the vinyl ketone (44) to the cyclic diketones (45a) and (45b) afforded the triketo-intermediates (46a) and (46b) in high yield, each containing a prochiral centre. Optically active amines and amino-acids were used as chiral reagents to... [Pg.337]

If an achiral ferrocene derivative is converted to a chiral one by chiral reagents or catalysts, this may be called an asymmetric synthesis. All asymmetric syntheses of ferrocene derivatives known so far are reductions of ferrocenyl ketones or aldehydes to chiral secondary alcohols. Early attempts to reduce benzoylferrocene by the Clemmensen procedure in (5)-l-methoxy-2-methylbutane as chiral solvent led to complex mixtures of products with low enantiomeric excess [65]. With (25, 3R)-4-dimethylamino-l,2-diphenyl-3-methyl-2-butanol as chiral modifier for the LiAlH4 reducing agent, the desired alcohol was formed with 53% ee (Fig. 4-9 a) [66]. An even better chiral ligand for LiAlH4 is natural quinine, which allows enantioselective reduction of several ferrocenyl ketones with up to 80% ee [67]. Inclusion complexes of ferrocenyl ketones with cyclodextrins can be reduced by NaBH4 with up to 84% enantioselectivity (Fig. 4-9 b) [68 — 70]. [Pg.181]

Asymmetric synthesis (1) Use a chiral auxiliary (chiral acetal—the synthetic equivalent of an aldehyde chiral hydrazone—the synthetic equivalent of a ketone) covalently attached to an achiral substrate to control subsequent bond formations. The auxiliary is later disconnected and recovered, if possible. (2) Use a chiral reagent to distinguish between enantiotopic faces or groups (asymmetric induction) to mediate formation of a chiral product. The substrate and reagent combine to form diastereomeric transition states. (3) Use a chiral catalyst to discriminate enantiotopic groups or faces in diastereomeric transition states but only using catalytic amounts of a chiral species. [Pg.124]

With protected ketone 85 in hand, the next aldol coupling required its syn-selective reaction with aldehyde 74 to install the C15-C16 stereocenters in 86 (Scheme 9-28). A boron triflate reagent would be expected to generate the desired (Z)-enolate. However, studies earned out on the separate components indicated that this was a mismatched reaction, and it did not prove possible to overturn the aldehyde facial bias by use of a chiral reagent. [Pg.264]

Given this problem, the attachment of the butanone synthon to aldehyde 74 prior to the methyl ketone aldol reaction was then addressed. To ovenide the unexpected. vTface preference of aldehyde 74, a chiral reagent was required and an asymmetric. syn crotylboration followed by Wacker oxidation proved effective for generating methyl ketone 87. Based on the previous results, it was considered unlikely that a boron enolate would now add selectively to aldehyde 73. However, a Mukaiyama aldol reaction should favour the desired isomer based on induction from the aldehyde partner. In practice, reaction of the silyl enol ether derived from 87 with aldehyde 73, in the presence of BF3-OEt2, afforded the required Felkin adduct 88 with >97%ds (Scheme 9-29). This provides an excellent example of a stereoselective Mukaiyama aldol reaction uniting a complex ketone and aldehyde, and this key step then enabled the successful first synthesis of swinholide A. [Pg.265]


See other pages where Ketones, chiral reagents is mentioned: [Pg.70]    [Pg.95]    [Pg.110]    [Pg.334]    [Pg.284]    [Pg.82]    [Pg.280]    [Pg.199]    [Pg.70]    [Pg.328]    [Pg.20]    [Pg.336]    [Pg.289]    [Pg.425]    [Pg.63]    [Pg.149]    [Pg.192]    [Pg.19]    [Pg.41]    [Pg.476]    [Pg.655]    [Pg.817]    [Pg.20]    [Pg.70]    [Pg.140]   
See also in sourсe #XX -- [ Pg.616 ]




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Chiral ketones

Chiral reagent

Diastereoselectivity reagents with chiral ketone

Divergent RRM Using a Single Chiral Reagent Ketone Reduction

Grignard reagents addition to chiral ketones

Grignard reagents chiral ketones

Ketones chiral boron reagents

Ketones external chiral reagents

Ketones reagents

Organolithium reagents chiral ketones

Organolithium reagents, reaction with chiral ketones

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