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Alkenes chiral dipolarophiles

In synthetic efforts toward the DNA reactive alkaloid naphthyridinomycin (164), Gamer and Ho (41) reported a series of studies into the constmction of the diazobicyclo[3.2.1]octane section. Constmction of the five-membered ring, by the photolytic conversion of an aziridine to an azomethine ylide and subsequent alkene 1,3-dipolar cycloaddition, was deemed the best synthetic tactic. Initial studies with menthol- and isonorborneol- tethered chiral dipolarophiles gave no facial selectivity in the adducts formed (42). However, utilizing Oppolzer s sultam as the chiral controlling unit led to a dramatic improvement. Treatment of ylide precursor 165 with the chiral dipolarophile 166 under photochemical conditions led to formation of the desired cycloadducts (Scheme 3.47). The reaction proceeded with an exo/endo ratio of only 2.4 1 however, the facial selectivity was good at >25 1 in favor of the desired re products. The products derived from si attack of the ylide... [Pg.199]

The relative rate constants (fe ) do not account for the fact that approach of the nitrile oxide to the 7i-bond can occur from both olefinic diastereofaces with two regioisomeric modes of reaction (Scheme 6.14). In the case of achiral 1-alkenes, only one regioisomer is formed. With chiral dipolarophiles, preference for one of the two is usually found (diastereodifferentiation). The relative diastereofacial reactivity (fejH) is used to evaluate this effect (121). With ethylene, there are four possibilities of attack (two for each face corresponding to the different regio-isomers), and the of each is set as 0.25. In diastereodifferentiating cycloadditions, such as those with a-chiral alkenes, the major isomer generally results... [Pg.378]

Most of the efforts towards the stereocontrolled synthesis of 4,5-dihydroisoxazoles were based on the use of chiral alkenes as dipolarophiles. Among these, the reactions of chiral acyclic olefins featuring an allylic stereocenter are of interest from both the practical and theoretical points of view 1 25,1 37 - 157. (More recent examples can be found in references 356-387.)... [Pg.765]

Menthol [(—)-l] has been used as a chiral ligand for aluminum in Lewis acid catalyzed Diels-Alder reactions with surprising success2 (Section D.l.6.1.1.1.2.2.1). The major part of its application is as a chiral auxiliary, by the formation of esters or ethers. Esters with carboxylic acids may be formed by any convenient esterification technique. Esters with saturated carboxylic acids have been used for the formation of enolates by deprotonation and subsequent addition or alkylation reactions (Sections D.l.1.1.3.1. and D.l.5.2.3.), and with unsaturated acids as chiral dienes or dienophiles in Diels-Alder reactions (Section D. 1.6.1.1.1.), as chiral dipolarophiles in 1,3-dipolar cycloadditions (Section D.l.6.1.2.1.), as chiral partners in /(-lactam formation by [2 + 2] cycloaddition with chlorosulfonyl isocyanate (SectionD.l.6.1.3.), as sources for chiral alkenes in cyclopropanations (Section D.l.6.1.5.). and in the synthesis of chiral allenes (Section B.I.). Several esters have also been prepared by indirect techniques, e.g.,... [Pg.125]

To control the stereochemistry of 1,3-dipolar cycloaddidon reacdons, chiral auxiliaries are introduced into either the dipole-part or dipolarophile A recent monograph covers this topic extensively ° therefore, only typical examples are presented here. Alkenes employed in asymmetric 1,3-cycloaddidon can be divided into three main groups (1) chiral allyhc alcohols, f2 chiral amines, and Hi chiral vinyl sulfoxides or vinylphosphine oxides. [Pg.251]

Dipolarophiles D5. Electron-deficient alkenes based on acrolein and its analogs are widely used as dipolarophiles. To carry out asymmetrical 1,3-dipolar cycloadditions between various nitrones and acrolein, the bis-titanium catalyst (543) (Fig. 2.37) was used as the chiral Lewis acid (Table 2.22) (754a). [Pg.331]

A diastereoselective dipolar cycloaddition of chiral nitrone 80 with alkene dipolarophiles afforded imidazo[ 1,2-3]-isoaxazole (Scheme 9). The conversion via N-O reduction of this ring system with Raney-Ni in methanol gave the corresponding pyrrolo[l,2-A imidazole in 66% yield. The structure has been confirmed by X-ray diffraction crystal stmcture analysis <2000SL967>. [Pg.53]

The number of investigations on the enantioselective dipolar cycloaddition of nitronates is still rather limited. In the case of simple alkyl nitronates, the facial selectivity is controlled solely by the steric environment about the two faces of the chiral unit. For example, the reaction of steroid dipolarophile 270 proceeds with the nitronate approaching the Re face of the alkene (Eq. 2.23) (234). The facial selectivity is controlled by the C(19) methyl group, which blocks the Si face of the dipolarophile. Similarly, exposure of 279 to ethyl acrylate at 40 °C for 24 h, provides a single nitroso acetal (Scheme 2.21) (242). The facial selectivity is presumed to arise from steric shielding by the menthol group, however the full stereostructure has not been established. [Pg.146]

The direct cycloaddition adduct was oxidized, resulting in the hydroxylated isoxazoline product (316). Better selectivities were obtained in 1,3-dipolar cycloadditions of 204 with nitrile oxides (317,318). The 1,3-dipolar cycloadditions proceeded with concomitant loss of the boron group to give the isoxazoline products in up to 74% ee (318). The alkene 204 was also tested in reactions with nitrones. The reactions proceeded with poor yields, but high selectivities were observed in two cases (318). Gilbertson et al. (319) investigated the use of chiral ot,p-unsaturated hexacarbonyldiiron acyl complexes 205 as dipolarophiles in reactions with nitrones. Selectivities of up to >92% de were observed. The iron moiety was removed oxidatively after the cycloaddition and the thioester was hydrolyzed. [Pg.860]

Results of a similar study on the enantiospecific synthesis of a glycosidase inhibitor, using chiral (3-benzyloxy acrylamide, show that even electron-rich alkenes can serve as dipolarophiles. A large influence of the polarity of the solvent is observed the greater the polarity the greater is the diastereoselectivity. Thus, DMF and acetonitrile are found to be the best solvents. On the basis of these observations, the desired enantiomerically pure glycosidase inhibitor, (3R. 4R)-4-(hydroxymethyljpyrrolidin-3-ol, could be prepared in two steps in 87% overall yield.436... [Pg.324]

The game is certainly not over, very recently catalytic enantioselective intermolecular cycloadditions of 2-diazo-3,6-diketoester of type 68 derived carbonyl ylides with alkene dipolarophiles have been developed [57]. Relying on chiral rhodium(II) clusters I and II, Hodgson et al. obtained very high enantioselectivities (up to 92% ee on 69) with norbornene as a trap, as disclosed in Scheme 31. [Pg.276]

Homochiral 4,5-dihydroimidazolium ylides 595 derived from chiral l-benzyl-4-phenyl-2-imidazoline 594, undergo diastereoselective endo 1,3-dipolar cycloaddition with a range of alkene dipolarophiles to form hexahydropyrrolo[l,2- t]-imidazoles 596. These reactions are best carried out in one pot by refluxing a mixture of 594, bromoacetate, and a dipolarophile in the presence of DBU (Scheme 142) <1996TL1707, 1998J(P1)2061>. Bicyclic adducts 596 are readily converted into enantiopure pyrrolidines in a two-step procedure <1996TL1711>. An intramolecular system (597 to 598) provided a rapid assembly of 2,3,4-trisubstituted pyrrolidines <1997TL1647>. [Pg.230]

Azomethine ylides are very important 1,3-dipoles, and they are usually used to react with alkenes leading to the formation of the highly substituted pyrrolidine derivatives [17]. A novel and practical process for the 1,3-dipolar cycloaddition of azomethine ylides with alkenes had been reported by j0rgensen and coworkers [18]. They proposed that a dipol-chiral base ion pair would be generated between a-imino ester-metal complex and a cinchona alkaloid, and subsequent cycloaddition with dipolarophile would take place in a stereoselective manner (Scheme 10.13). [Pg.308]

The reactions of diazoalkanes 9.21 with alkenes lead to pyrazolines 9.22, which are thermally transformed into cyclopropanes. Similar transformations occur during thermal reactions of diazoesters. The use of diazoesters of chiral alcohols did not give useful results, so chiral residues have been introduced on the olefin dipolarophile. Meyers and coworkers [327] carried out the reaction of diazomethane 9.21 (R = R = H) and diazopropane 9.21 (R = R = Me) with chiral lactams 1.92 (R = i-Pr or ferf-Bu, R = Me). These 1,3-dipolar cycloadditions are regioselective, but only CH2N2 leads to an interesting stereoselectivity (Figure 9.9). Morever, when the RM substituent of lactam 1.92 is H, the reaction is no longer stereoselective. [Pg.526]

Better diastereoselectivities were achieved with dipolarophiles such as unsaturated esters that bear a chiral auxiliary297-298. For instance, cycloaddition of the EVE-azomethine ylide, generated from the following imine by metalation, with the chiral alkene (27 )-2-(2-methoxycar-bonylethenyl)-3-phenyl-l,3-diazabicyclo[3.3.0]octane affords the pyrrolidine derivative as a single regio- and stereoisomer297. [Pg.777]


See other pages where Alkenes chiral dipolarophiles is mentioned: [Pg.298]    [Pg.658]    [Pg.497]    [Pg.449]    [Pg.468]    [Pg.193]    [Pg.2]    [Pg.64]    [Pg.158]    [Pg.386]    [Pg.12]    [Pg.74]    [Pg.167]    [Pg.310]    [Pg.633]    [Pg.1125]    [Pg.358]    [Pg.566]    [Pg.161]    [Pg.202]    [Pg.131]    [Pg.244]   
See also in sourсe #XX -- [ Pg.387 , Pg.388 , Pg.389 , Pg.390 , Pg.391 , Pg.392 , Pg.835 , Pg.836 , Pg.837 , Pg.838 , Pg.839 , Pg.840 , Pg.841 , Pg.842 , Pg.843 ]

See also in sourсe #XX -- [ Pg.387 , Pg.388 , Pg.389 , Pg.390 , Pg.391 , Pg.392 ]




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Alkenes chiral

Chiral Dipolarophiles

Chirality alkenes

Dipolarophile

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