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Asymmetric induction chiral ketones

The extent of asymmetric induction in systems containing an adjacent stereogenic center has been discussed by Morrison and Mosher. 61 Cram suggested a model for asymmetric induction in ketones such as 236 that has come to be known as Cram s open chain model (Cram s model), or simply Cram s rule.2 2,263 This model assumes a kinetically controlled reaction (nonequilibrating and noncatalytic) for asymmetric 1,2-addition to aldehydes and ketones. The three groups attached to the chiral center are Rs (small substituent), Rm (middle-sized substituent), and Rl (large substituent). Determining the relative size of the substituents is... [Pg.352]

Chiral Induction.—As with many synthetic techniques in organic chemistry, PTC methods have been under investigation to determine whether asymmetric induction (chiral selection) can be achieved. In this case chiral onium salts are necessary, and the systems investigated to date have been quaternary derivatives (23) of A -methyl ephedrine. These salts have been used to catalyse two-phase metal boro-hydride reductions of ketones, and the chiral tetra-alkylammonium borohydride ion pair does accelerate this reaction " in organic solvents. However, either no asymmetric reduction is observed, " or low optical purity of products is achieved (less than 15% enantiomer excess). - A low chiral selectivity is also observed in... [Pg.410]

A more eflicient and general synthetic procedure is the Masamune reaction of aldehydes with boron enolates of chiral a-silyloxy ketones. A double asymmetric induction generates two new chiral centres with enantioselectivities > 99%. It is again explained by a chair-like six-centre transition state. The repulsive interactions of the bulky cyclohexyl group with the vinylic hydrogen and the boron ligands dictate the approach of the enolate to the aldehyde (S. Masamune, 1981 A). The fi-hydroxy-x-methyl ketones obtained are pure threo products (threo = threose- or threonine-like Fischer formula also termed syn" = planar zig-zag chain with substituents on one side), and the reaction has successfully been applied to macrolide syntheses (S. Masamune, 1981 B). Optically pure threo (= syn") 8-hydroxy-a-methyl carboxylic acids are obtained by desilylation and periodate oxidation (S. Masamune, 1981 A). Chiral 0-((S)-trans-2,5-dimethyl-l-borolanyl) ketene thioketals giving pure erythro (= anti ) diastereomers have also been developed by S. Masamune (1986). [Pg.62]

In this chapter the addition of carbon nucleophiles to simple a,j8-unsaturated sulfoxides, a-sulfinyl-a,/ -unsaturated ketones and a-sulfmyl-a,/ -unsaturated lactones will be discussed separately, in most cases the asymmetric induction arises from the chirality at sulfur. [Pg.1041]

Fluoboric acid is also an efficacious promoter of cyclic oxo-carbenium ions (Scheme 4.24) bearing an activated double bond which, in the presence of open-chain and cyclic dienes, rapidly undergo a Diels-Alder reaction [91]. Chiral a, -unsaturated ketones bearing a -hydroxy substituents, protected as acetals, react with various dienes in the presence of HBF4, affording Diels-Alder adducts that were isolated as alcohols by hydrolysis of the acetal group by TsOH. Some examples of reactions with isoprene are reported in Table 4.23. The enantios-electivity of the reaction is dependent on the size of the substituent R on the of-carbon high levels of asymmetric induction were observed with R = z-Pr (90 1) and R = t-Bu (150 1) and low levels with R = Me (2.7 1) and R = Ph (3.0 1). Scheme 4.24 shows the postulated reaction mechanism. [Pg.187]

The titanium reagent also dimethylates aromatic aldehydes." Triethylaluminum reacts with aldehydes, however, to give the mono-ethyl alcohol, and in the presence of a chiral additive the reaction proceeds with good asymmetric induction." A complex of Me3Ti-MeLi has been shown to be selective for 1,2 addition with conjugated ketones, in the presence of nonconjugated ketones." ... [Pg.1210]

Optically active ketone (6) was needed for a study of asymmetric induction It could be made from acid (7) by a Friedel Crafts route or from nitrile (8) by Grignard addition, but neither of these compounds could be made by alkylation as the branchpoint is on the 3 carbon ( in each). The 1,3 C-C disconnection, e.g. (6b) is not good as it destroys the chiral centre. [Pg.139]

Catalytic enantioselective nucleophilic addition of nitroalkanes to electron-deficient alke-nes is a challenging area in organic synthesis. The use of cinchona alkaloids as chiral catalysts has been studied for many years. Asymmetric induction in the Michael addition of nitroalkanes to enones has been carried out with various chiral bases. Wynberg and coworkers have used various alkaloids and their derivatives, but the enantiomeric excess (ee) is generally low (up to 20%).199 The Michael addition of methyl vinyl ketone to 2-nitrocycloalkanes catalyzed by the cinchona alkaloid cinchonine affords adducts in high yields in up to 60% ee (Eq. 4.137).200... [Pg.118]

Catalytic enantioselective crossed aldehyde-ketone benzoin cyclizations of ketoaldehydes, such as 13, readily obtained from an aryl nitrile oxide and a 1,3-diketone, were studied in order to perform the synthesis of complex molecules. Significant asymmetric induction was observed with chiral triazolium salts such as 14, in the presence of DBU as base, leading to compound 15 in high yield and with 99% ee in favor of the R enantiomer <06AG(E)3492>. [Pg.289]

Two reports have been made of the preparation of P-chiral phosphine oxides through reaction of chiral f-butylphenylphosphine oxide treated with LDA and electrophiles. The electrophiles included aldehydes,355 ketones,355 and benzylic-type halides.356 Optically active a-hydroxyphosphonate products have also been generated from aldehydes and dialkyl phosphites using an asymmetric induction approach with LiAl-BINOL.357... [Pg.62]

The results of the study of the last-mentioned reaction, DCA-PhCOCH3 —> 167, provided a surprise. X-Ray analyses of the structure of the clathrate before and after partial reaction, and of the final product, 167, showed that the prochiral Re face of the ketone, initially the face more distant from the to-be-attacked host, and not the close-lying Si face, is the one that adds to the steroid. A rationalization of this extraordinary sterochemical effect, which results in formation of a new chiral center with quantitative asymmetric induction, has been proposed (241). [Pg.201]

Asymmetric induction using catalytic amounts of quininium or A-methyl-ephedrinium salts for the Darzen s reaction of aldehydes and ketones with phenacyl halides and chloromethylsulphones produces oxiranes of low optical purity [3, 24, 25]. The chiral catalyst appears to have little more effect than non-chiral catalysts (Section 12.1). Similarly, the catalysed reaction of sodium cyanide with a-bromo-ketones produces epoxynitriles of only low optical purity [3]. The claimed 67% ee for the phenyloxirane derived from the reaction of benzaldehyde with trimethylsul-phonium iodide under basic conditions [26] in the presence of A,A-dimethyle-phedrinium chloride was later retracted [27] the product was contaminated with the 2-methyl-3-phenyloxirane from the degradation of the catalyst. [Pg.539]

Several early reports of high asymmetric induction during the hydride reduction of ketones under the influence of chiral catalysts [e.g. 1,2] have been discredited [3-6]. [Pg.541]

The optical yield was found to be very sensitive to structural modifications of the achiral agent. For example, use of the more bulky FV or Bu substituents in the 3,5-positions of phenol resulted in lower optical yields. In some cases a reversal of the sense of asymmetric induction was observed. Systematic variation of reaction conditions using the best achiral component, 3,5-xylenol, established that optimum results were obtained in ether solvent at about - 15°C. There was also a minor but definite influence of the rate of addition of ketone as well as an effect of concentration on optical yield, with a slower rate being advantageous. The results of reduction of aryl alkyl ketones are shown in Table 9, along with comparative results of reduction with similar chiral auxiliary reagents. [Pg.266]

Recently, the improved chiral ethyl ketone (5)-141, derived in three steps from (5)-mandelic acid, has been evaluated in the aldol process (115). Representative condensations of the derived (Z)-boron enolates (5)-142 with aldehydes are summarized in Table 34b, It is evident from the data that the nature of the boron ligand L plays a significant role in enolate diastereoface selection in this system. It is also noteworthy that the sense of asymmetric induction noted for the boron enolate (5)-142 is opposite to that observed for the lithium enolate (5)-139a and (5>139b derived from (S)-atrolactic acid (3) and the related lithium enolate 139. A detailed interpretation of these observations in terms of transition state steric effects (cf. Scheme 20) and chelation phenomena appears to be premature at this time. Further applications of (S )- 41 and (/ )-141 as chiral propionate enolate synthons for the aldol process have appeared in a 6-deoxyerythronolide B synthesis recently disclosed by Masamune (115b). [Pg.85]

In ketones having a chiral cluster next to the carbonyl carbon reduction with lithium aluminum hydride gave one of the two possible diastereomers, erythro or threo, in larger proportions. The outcome of the reduction is determined by the approach of the reducing agent from the least hindered side (steric control of asymmetric induction) [828]. With lithium aluminum hydride as much as 80% of one diasteromer was obtained. This ratio is higher with more bulky reducing hydrides [837]. [Pg.112]

Subsequently, List reported that although the method described above was not applicable to the reduction of a,P-unsaturated ketones, use of a chiral amine in conjunction with a chiral anion provided an efficient and effective procedure for the reduction of these challenging substrates [210]. Transfer hydrogenation of a series of cyclic and acyclic a,P-unsaturated ketones with Hantzsch ester 119 could be achieved in the presence of 5 mol% of valine tert-butyl ester phosphonate salt 155 with outstanding levels of enantiomeric control (Scheme 64). A simple mechanistic model explains the sense of asymmetric induction within these transformations aUowing for reliable prediction of the reaction outcome. It should also be noted that matched chirality in the anion and amine is necessary to achieve high levels of asymmetric induction. [Pg.330]

The development of enantioselective aldol reactions has been widely studied in conjunction with the synthesis of natural products. Highly enantioselective aldol reactions have been achieved by employing chiral enolates of ethyl ketones and propionic acid derivatives.(1) On the other hand, achieving high asymmetric induction in the asymmetric aldol reaction of methyl ketones is still a problem.(2)... [Pg.290]

As mentioned, the present methodology affords an effective means for the synthesis of optically active aldols. A high level of asymmetric induction was observed with a wide range of ketones such as methyl, ethyl and O-methoxy. Furthermore, when (1S,2R)-norephedrine is employed as a chiral auxiliary, it is always the si-face of aldehydes that is attacked by the tin(II) enamine. [Pg.294]

See other pages where Asymmetric induction chiral ketones is mentioned: [Pg.106]    [Pg.247]    [Pg.247]    [Pg.334]    [Pg.73]    [Pg.1222]    [Pg.46]    [Pg.247]    [Pg.38]    [Pg.327]    [Pg.343]    [Pg.1173]    [Pg.220]    [Pg.10]    [Pg.59]    [Pg.1450]    [Pg.249]    [Pg.53]    [Pg.542]    [Pg.237]    [Pg.241]    [Pg.67]    [Pg.88]    [Pg.441]    [Pg.23]    [Pg.28]    [Pg.147]    [Pg.283]    [Pg.328]    [Pg.336]    [Pg.290]   
See also in sourсe #XX -- [ Pg.62 , Pg.106 ]



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Asymmetric chirality

Asymmetrical ketones

Chiral asymmetric induction

Chiral ketones

Chirality induction

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