Enantioselectivity carbonyl ylides

Scheme 7.39 Enantioselective carbonyl ylide cycloaddition using a continuous-flow system.

The intermolecular version of the above described reaction has also been reported [92]. In the first example the reaction of a rhodium catalyst carbonyl ylide with maleimide was studied. However, only low enantioselectivities of up to 20% ee were obtained [92]. In a more recent report Hashimoto et al. were able to induce high enantioselectivities in the intermolecular carbonyl ylide reaction of the... 

Carbonyl ylides continue to be targets of opportunity because of their suitability for trapping by dipolar addition. High enantiocontrol has been achieved in the process described by Eq. 16 [109], but such high enantioselectivity is not general [110] and is dependent on those factors suggested by Scheme 11. Using achiral dirhodium(II) catalysts, Padwa and coworkers have developed a broad selection of tandem reactions of which that in Eq. 17 is illustrative [111] these... 

Intramolecular ylide formation with the lactone carbonyl oxygen (53) in 145 provided a carbonyl ylide 146 that was trapped with Al-phenyl maleimide to give cycloadduct 147. Likewise (54), carbonyl yhde 149, derived from ester 148, suffers intramolecular cycloaddition with the tethered alkene to deliver acetal 150 in 87% yield. An enantioselective version of this process has also been described (Scheme 4.33). 

After completing his initial intramolecular cycloaddition, Hodgson utilized conditions that had been optimized for the intermolecular cycloaddition of DMAD with simple cyclic carbonyl ylides used by Hashimoto and co-workers (139). Hodgson et al. (140) found that the reaction indeed gave excellent overall chemical yield, but the enantioselectivity dropped to 1%, giving essentially a racemic mixture. It appeared that ee ratios were sensitive to the electronic nature of the dipole. Hodgson chose to screen several binaphthol derived rhodium catalysts of the type developed by McKervey and Pirrung, due in part to the reports of... 

Hashimoto and co-workers (206,207) recently published enantioselectivities of up to 92% ee in carbonyl ylide cycloadditions to acetylenic esters in the presence of a chiral rhodium catalyst (Scheme 11.58). 

These principles of activation and induction of asymmetry apply primarily to reactions of nitrones. For the reactions of other 1,3-dipoles, the catalyst-induced control of the enantioselectivity may in some cases be achieved by other principles. For the metal-catalyzed reactions of azomethine ylides, carbonyl ylides, and nitrile... 

Good yields of the bridged tetrahydropyran-3-one 38 are obtained when the a-diazoketones 37 are decomposed by chiral Rh(II)-catalysts in the presence of DMAD. It is proposed that an enantioselective intermolecular 13-dipolar cycloaddition follows the generation of a carbonyl ylide which is bound to the rhodium (Scheme 21) <99JA1417>. 

Hodgson and co-workers have studied the intramolecular cascade carbonyl ylide formation-cycloaddition with chiral Rh(ii) catalysts.After screening a series of chiral Rh(ii) catalysts, high enantioselectivity was achieved in the reaction of 98 by using the Rh(ii) catalyst with binaphthyl phosphate-derived chiral ligands dirhodium(ii) tetrakis[(i )-6,6 -didodecylbinaphtholphosphate] [Rh2(i -DDBNP)4] (Equation (13)). 

A promising synthetic transformation is the reaction of carbenoid intermediates with heteroatoms to form ylides that are capable of undergoing further transformations [5,6]. Enantioselective transformations in which the ylide intermediates undergo either 1,2- or 2,3-sigmatropic rearrangement were briefly reviewed in the previous issue (Vol. II, pp. 531-532) and several recent examples have appeared [37]. A major breakthrough has been made in the enantioselective transformation of carbonyl ylides derived from capture of the metal carbenoid intermediates by carbonyl groups. The carbonyl ylides have been ex-... 

Enandoselective tandem carbonyl ylide formation-cycloaddition of a-diazo- -keto esters is achieved in hexane with [Rh2(5-DOSP)4] (1 mol %) at room temperature to give the corresponding cycloadducts with moderate enantioselectivity [73] (Eq. 8A.49). 

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. 

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