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Ketones stereocontrol

Paterson I, Tillyer RD. High rr-face selectivity in anti aldol reactions of E-enol borinates from chiral alkoxy-methyl ketones stereocontrolled synthesis of a C24—C32 polyol subunit of rapamycin. J. Org. Chem. 1993 58 4182 184. [Pg.314]

Ketone 13 possesses the requisite structural features for an a-chelation-controlled carbonyl addition reaction.9-11 Treatment of 13 with 3-methyl-3-butenylmagnesium bromide leads, through the intermediacy of a five-membered chelate, to the formation of intermediate 12 together with a small amount of the C-12 epimer. The degree of stereoselectivity (ca. 50 1 in favor of the desired compound 12) exhibited in this substrate-stereocontrolled addition reaction is exceptional. It is instructive to note that sequential treatment of lactone 14 with 3-methyl-3-butenylmagnesium bromide and tert-butyldimethylsilyl chloride, followed by exposure of the resultant ketone to methylmagnesium bromide, produces the C-12 epimer of intermediate 12 with the same 50 1 stereoselectivity. [Pg.239]

It was anticipated that two of the three stereochemical relationships required for intermediate 12 could be created through reaction of the boron enolate derived from imide 21 with a-(benzyloxy)ace-taldehyde 24. After conversion of the syn aldol adduct into enone 23, a substrate-stereocontrolled 1,2-reduction of the C-5 ketone car-... [Pg.490]

The completion of the synthesis of the polyol glycoside subunit 7 requires construction of the fully substituted stereocenter at C-10 and a stereocontrolled dihydroxylation of the C3-C4 geminally-disub-stituted olefin (see Scheme 10). The action of methyllithium on Af-methoxy-Af-methylamide 50) furnishes a methyl ketone which is subsequently converted into intermediate 10 through oxidative removal of the /j-methoxybenzyl protecting group with DDQ. Intermediate 10 is produced in an overall yield of 83 % from 50) , and is a suitable substrate for an a-chelation-controlled carbonyl addition reaction.18 When intermediate 10 is exposed to three equivalents of... [Pg.502]

The first element of stereocontrol in aldol addition reactions of ketone enolates is the enolate structure. Most enolates can exist as two stereoisomers. In Section 1.1.2, we discussed the factors that influence enolate composition. The enolate formed from 2,2-dimethyl-3-pentanone under kinetically controlled conditions is the Z-isomer.5 When it reacts with benzaldehyde only the syn aldol is formed.4 The product stereochemistry is correctly predicted if the TS has a conformation with the phenyl substituent in an equatorial position. [Pg.68]

The overall transformation of this sequence corresponds to the aldol addition of an aldehyde with a cyclic ketone. The actual aldol addition frequently proceeds with low stereocontrol, so this sequence constitutes a method for stereoselective synthesis of the aldol adducts. The reaction has been done with several Lewis acids, including SnCl4, BF3, and Ti(0-/-Pr)3Cl. [Pg.886]

The Baylis-Hillman reaction of TV-protected 3-substituted 4-formylazetidin-2-ones with methyl vinyl ketone has been used to prepare intermediates from which highly functionalised P-lactams fused to medium rings were obtained by radical, stereocontrolled methods <99CC1913>. [Pg.82]

Fu and Dosa139 report the enantioselective addition of diphenylzinc to a range of aryl-alkyl and dialkyl ketones with good to excellent stereocontrol. Addition of 1.5 eq. of MeOH in the presence of a catalytic amount of (+)-DAIB 135 results in enhanced enantioselectivity and improved yield (Scheme 2-53). Table 2-16 gives the results of this reaction. [Pg.118]

The reactions of allylmetal reagents with carbonyl compounds and imines have been extensively investigated during the last two decades [1], These carbon—carbon bondforming reactions possess an important potential for controlling the stereochemistry in acyclic systems. Allylmetal reagents react with aldehydes and ketones to afford homo-allylic alcohols (Scheme 13.1), which are valuable synthetic intermediates. In particular, the reaction offers a complementary approach to the stereocontrolled aldol process, since the newly formed alkenes may be readily transformed into aldehydes and the operation repeated. [Pg.451]

Typical electrophiles that attack olefins like Br+ (Eq. 64)105) and (OH)+ (Eq. 65) 105) do lead to electrophilic addition with ring enlargement101 a). Most interesting is the ability for electrophiles that normally do not attack olefins to also react. Thus, an oxycarbonium ion generated from an acetal smoothly alkylates the double bond of this composite functional group in an overall highly stereocontrolled 1,1,2-trialkylation of a simple ketone as illustrated in Eq. 66 106). The chemo- and... [Pg.49]

Diastereoselective aldol condensations.1 The aldol condensation of a chiral ethyl ketone such as 2 with aldehydes catalyzed by Bu2BOTf gives a mixture of all four possible diastereomeric adducts with little or no stereocontrol. In contrast, reactions catalyzed by either (+)- or (- )-l are highly diastereoselective. By proper choice of (+)- and (- )-l and of (+)- and (- )-2, each one of the four possible 1,2-yyn-diastereomers can be obtained in high purity. [Pg.139]

Stereocontrolled oxy-Cope rearrangement. 1,2-Addition of a chiral vinyl-lithium reagent to a chiral (3,-y-unsaturated ketone could give rise to at least eight... [Pg.185]

Okamura and Nakatani [65] revealed that the cycloaddition of 3-hydroxy-2-py-rone 107 with electron deficient dienophiles such as simple a,p-unsaturated aldehydes form the endo adduct under base catalysis. The reaction proceeds under NEtj, but demonstrates superior selectivity with Cinchona alkaloids. More recently, Deng et al. [66], through use of modified Cinchona alkaloids, expanded the dienophile pool in the Diels-Alder reaction of 3-hydroxy-2-pyrone 107 with a,p-unsaturated ketones. The mechanistic insight reveals that the bifunctional Cinchona alkaloid catalyst, via multiple hydrogen bonding, raises the HOMO of the 2-pyrone while lowering the LUMO of the dienophile with simultaneous stereocontrol over the substrates (Scheme 22). [Pg.163]

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]

The introduction of umpoled synthons 177 into aldehydes or prochiral ketones leads to the formation of a new stereogenic center. In contrast to the pendant of a-bromo-a-lithio alkenes, an efficient chiral a-lithiated vinyl ether has not been developed so far. Nevertheless, substantial diastereoselectivity is observed in the addition of lithiated vinyl ethers to several chiral carbonyl compounds, in particular cyclic ketones. In these cases, stereocontrol is exhibited by the chirality of the aldehyde or ketone in the sense of substrate-induced stereoselectivity. This is illustrated by the reaction of 1-methoxy-l-lithio ethene 56 with estrone methyl ether, which is attacked by the nucleophilic carbenoid exclusively from the a-face —the typical stereochemical outcome of the nucleophilic addition to H-ketosteroids . Representative examples of various acyclic and cyclic a-lithiated vinyl ethers, generated by deprotonation, and their reactions with electrophiles are given in Table 6. [Pg.885]

The control of reactivity to achieve specific syntheses is one of the overarching goals of organic chemistry. In the decade since the publication of the third edition, major advances have been made in the development of efficient new methods, particularly catalytic processes, and in means for control of reaction stereochemistry. For example, the scope and efficiency of palladium- catalyzed cross coupling have been greatly improved by optimization of catalysts by ligand modification. Among the developments in stereocontrol are catalysts for enantioselective reduction of ketones, improved methods for control of the... [Pg.970]

More recently, the same group achieved a simple, highly stereocontrolled total synthesis of (+)-hirsutic acid (Scheme LXXIX) ". This chirally directed effort developed subsequent to reaction of dl-728 with (+)-di-3-pinanylborane, alkaline hydrogen peroxide oxidation, chromatography, PCC oxidation, and hydrogenolysis. The dextrorotatory hydroxy ketone 729 was nicely crafted into keto aldehyde 730 from which 720 was readily obtained. Once again, the Wacker oxidation played an instrumental role in annulation of the third five-membered ring. The remainder of the asymmetric synthesis was completed as before. [Pg.71]


See other pages where Ketones stereocontrol is mentioned: [Pg.27]    [Pg.306]    [Pg.27]    [Pg.306]    [Pg.66]    [Pg.234]    [Pg.425]    [Pg.445]    [Pg.551]    [Pg.761]    [Pg.293]    [Pg.276]    [Pg.165]    [Pg.167]    [Pg.231]    [Pg.307]    [Pg.230]    [Pg.5]    [Pg.369]    [Pg.519]    [Pg.398]    [Pg.65]    [Pg.69]    [Pg.72]    [Pg.26]    [Pg.117]    [Pg.66]    [Pg.228]    [Pg.237]    [Pg.183]    [Pg.214]    [Pg.328]    [Pg.198]    [Pg.351]    [Pg.293]    [Pg.322]   
See also in sourсe #XX -- [ Pg.133 ]




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