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Stereogenic center formation aldehydes

The lower diastereoselectivity found with aldehyde 15 (R = CH3) can be explained by the steric influence of the two methyl substituents in close vicinity to the stereogenic center, which probably diminishes the ability of the ether oxygen to coordinate. In contrast, a significant difference in the diastereoselectivity was found in the additions of phenyllithium and phenylmagnesium bromide to isopropylidene glyceraldehyde (17)58 (see also Section 1.3.1.3.6.). Presumably the diastereo-sclcctivity of the phenyllithium addition is determined by the ratio of chelation-controlled to nonchelation-controlled attack of the nucleophile, whereas in the case of phenylmagnesium bromide additional chelation with the / -ether oxygen may occur. Formation of the -chelate 19 stabilizes the Felkin-Anh transition state and therefore increases the proportion of the anZz -diastereomeric addition product. [Pg.52]

The diastereofacial selectivity of Lewis acid promoted reactions of allylsilancs with chiral aldehydes has been thoroughly investigated58. Aldehydes with alkyl substituted a-stereogenic centers react with a mild preference for the formation of Cram products, this preference being enhanced by the use of boron trifluoride-diethyl ether complex as catalyst58. [Pg.348]

In a chiral aldehyde or a chiral ketone, the carbonyl faces are diastereotopic. Thus, the addition of an enolate leads to the formation of at least one stereogenic center. An effective transfer of chirality from the stereogenic center to the diastereoface is highly desirable. In most cases of diastereoface selection of this type, the chiral aldehyde or ketone was used in the racemic form, especially in early investigations. However, from the point of view of an HPC synthesis, it is indispensable to use enantiomerically pure carbonyl compounds. Therefore, this section emphasizes those aldol reactions which are performed with enantiomerically pure aldehydes. [Pg.563]

Note also the stereochemistry. In some cases, two new stereogenic centers are formed. The hydroxyl group and any C(2) substituent on the enolate can be in a syn or anti relationship. For many aldol addition reactions, the stereochemical outcome of the reaction can be predicted and analyzed on the basis of the detailed mechanism of the reaction. Entry 1 is a mixed ketone-aldehyde aldol addition carried out by kinetic formation of the less-substituted ketone enolate. Entries 2 to 4 are similar reactions but with more highly substituted reactants. Entries 5 and 6 involve boron enolates, which are discussed in Section 2.1.2.2. Entry 7 shows the formation of a boron enolate of an amide reactions of this type are considered in Section 2.1.3. Entries 8 to 10 show titanium, tin, and zirconium enolates and are discussed in Section 2.1.2.3. [Pg.67]

Another attractive domino approach starts with an aldol reaction of preformed enol ethers and carbonyl compounds as the first step. Rychnovsky and coworkers have found that unsaturated enol ethers such as 2-237 react with different aldehydes 2-238 in the presence of TiBr4. The process consists of an aldol and a Prins-type reaction to give 4-bromotetrahydropyrans 2-239 in good yields, and allows the formation of two new C-C-bonds, one ring and three new stereogenic centers (Scheme 2.56) [131]. In the reaction, only two diastereomers out of eight possible isomers were formed whereby the intermediate carbocation is quenched with a bromide. [Pg.83]

Zr-catalyzed enantio-selective intramolecular diene cyclizations with allylic alcohol and ether substrates afford carbocycles bearing quaternary carbon stereogenic centers the unexpected formation of the aldehyde product 19 is noteworthy. [Pg.187]

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 enantiomerically-pure intermediate 1 was prepared from the dioxolanone 4, available in three steps from L-malic acid. Lewis acid-mediated homologation converted 4, a 4 1 mixture of diastereomers, into 5 as a single diastereomer. After establishment of the alkenyl iodide, it necessary to maintain the lactone in its open form. A solution was found in the formation of the Weinreb amide. The final stereogenic center was established by Brown allylation of the derived aldehyde. The alkene metathesis to form 1 was carried out with the commercially-available Schrock Mo catalyst. The authors did not comment on the relative efficacy of alternative alkene metathesis catalysts. [Pg.82]

The Morita-Baylis-Hillman (MBH) reaction is the formation of a-methylene-/ -hydroxycarbonyl compounds X by addition of aldehydes IX to a,/ -unsaturated carbonyl compounds VIII, for example vinyl ketones, acrylonitriles or acrylic esters (Scheme 6.58) [143-148]. For the reaction to occur the presence of catalytically active nucleophiles ( Nu , Scheme 6.58) is required. It is now commonly accepted that the MBH reaction is initiated by addition of the catalytically active nucleophile to the enone/enoate VIII. The resulting enolate adds to the aldehyde IX, establishing the new stereogenic center at the aldehydic carbonyl carbon atom. Formation of the product X is completed by proton transfer from the a-position of the carbonyl moiety to the alcoholate oxygen atom with concomitant elimination of the nucleophile. Thus Nu is available for the next catalytic cycle. [Pg.182]

The reaction sequence depicted in Scheme 6.58 also illustrates several problems associated with the MBH reaction. Addition to aldehyde IX can be slow, and side-reactions such as base-induced polymerization of the a,//-unsaturated carbonyl compound can occur. Furthermore, generation of diastereomeric (i.e. E/Z) enolates can complicate matters if enantioselective addition to the aldehyde component is desired. In principle, formation of a stereogenic center at the aldehydic carbonyl C-atom can be steered by (i) use of a chiral a,/ -unsaturated carbonyl compound [149, 150] (ii) use of a chiral aldehyde and (iii) use of a chiral nucleophilic cata-... [Pg.182]

In a similar manner, aldehydes can also be enantioselectively alkylated by this procedure. However, the enantiomeric excess obtained is much lower (47%). A special application of this method is the enantioselective alkylation of aldehydes for the construction of quaternary stereogenic centers. An example is the formation of the chiral quaternary carbon in 4-methyl-4-phenylcyclohex-2-en-1-one in high enantiomeric excess using this methodology (eq 4). ... [Pg.57]

The tandem Cope-Cltdsen rearrangement of triene (96 equation 14) creates a product with three new stereogenic centers. Only two of the four possible stereoisomers are formed, namely, aldehydes (100) and (98) in a 78 22 ratio. The factors that control the stereochemistry are the chair-like versus boat-like transition state of the Cope rearrangement (96 giving 97) and the formation of the carbon-carbon bond in... [Pg.884]

Silyl enol ethers react with aldehydes in the presence of chiral boranes or other additives " to give aldols with good asymmetric induction (see the Mukaiyama aldol reaction in 16-35). Chiral boron enolates have been used. Since both new stereogenic centers are formed enantioselectively, this kind of process is called double asymmetric synthesis Where both the enolate derivative and substrate were achiral, carrying out the reaction in the presence of an optically active boron compound ° or a diamine coordinated with a tin compound ° gives the aldol product with excellent enantioselectivity for one stereoisomer. Formation of the magnesium enolate anion of a chiral amide, adds to aldehydes to give the alcohol enantioselectively. [Pg.1348]


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See also in sourсe #XX -- [ Pg.315 ]




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