Carbonyl ylides ester derivation

Intramolecular ylide formation with the lactone carbonyl oxygen (53) in 145 provided a carbonyl ylide 146 that was trapped with (V-phenyl maleimide to give cycloadduct 147. Likewise (54), carbonyl ylide 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). 

Finally, it is important to mention that there are other related publications in which porphyrin macrocycles are not directly used as dipolarophiles but are transformed into new derivatives that can react with carbonyl ylides via ACE (alkene cyclobutene epoxide) reactions. This idea arose in 1997, when Russell and co-workers found that fused ester-activated cyclobutene epoxides 86 can be ring-opened to give carbonyl ylides 87, and that these can be trapped stereospecifically by ring-strained alicyclic dipolarophiles, such as 2,5-norbomadiene, to form hetero-bridged norbomanes 88 in good yields, through ACE transformations (Scheme 31) <97CC1023>. 

Photolytic decomposition of diazirine (25) in the presence of ethyl acetate led to the formation of the ester derived carbonyl ylide (26). Trapping of the ylide with diethyl fumarate led to the formation of the dihydrofuran 28, generated by dehydrochlorination of the initial cycloadduct 27. It occurred with a rate constant... 

Wenkert and Khatuya (51) examined the competition between direct insertion of a carbene into furan (via cyclopropanation) and ylide formation with reactive side-chain functionality such as esters, aldehydes, and acetals. They demonstrated the ease of formation of aldehyde derived carbonyl ylides (Scheme 4.30) as opposed to reaction with the electron-rich olefin of the furan. Treatment of 3-furfural (136) with ethyl diazoacetate (EDA) and rhodium acetate led to formation of ylide 137, followed by trapping with a second molecule of furfural to give the acetal 138 as an equal mixture of isomers at the acetal hydrogen position. 

Ester derivatives are also capable of forming carbonyl ylides and can undergo traditional cycloaddition with activated alkenes and alkynes and can even undergo reactions with heterodipolarophiles. Padwa was able to generate ester derived... 

A further study on six-membered ylide formation examined the use of an aliphatic ester in place of a ketone as the Lewis base donor for carbonyl ylide formation. Although the same keto-substituted system underwent an intramolecular cyclization readily, the ester derivative gave no cycloaddition products. Padwa and co-workers (37,76) points to the major electronic differences between the two carbonyl groups to rationalize the disparity in carbonyl ylide formation. 

Carbonyl ylides possess versatile reactivities, among which the 1,3-dipolar cycloaddition is the most common and important reaction. The reaction sequence of ylide formation and then 1,3-dipolar cycloaddition can occur in either inter- or intramolecular manner. When the reaction occurs intermolecularly, the overall reaction is a one-pot three-eomponent process leading to oxygen-containing five-membered cyclic compounds, as demonstrated by the example shown in Scheme 8. A mixture of diazo ester 64, benzaldehyde, and dimethyl maleate, upon heating to reflux in CH2CI2 in the presence of 1 mol% rhodium(ii) perfluorobutyrate [Rh2(pfb)4], yields tetrahedrofuran derivative 65 in 49% yield as single diastereomer. " ... 

Summary. Intra- and intermolecular carbene or carbenoid reactions resulting from the photochemical and Cu(I)-, Rh(II)-, or Ru(I)-catalyzed decomposition of a-diazo-a-silylacetic esters are described. Among the products reported are (alkoxysilyl)ketenes, silaheterocycles, 1-trialkylsilylcyclopropane-l-carboxylates, and products derived from transient carbonyl ylides. 

The N-metallated azomethine ylides having a wider synthetic potential are N-lithiated ylides 141, derived from the imines of a-amino esters, lithium bromide, and triethylamine, and 144 from the imines of a-aminonitriles and LDA (Section II,G). Ester-stabilized ylides 144 undergo regio- and endo-selective cycloadditions, at room temperature, to a wide variety of unsym-metrically substituted olefins bearing a carbonyl-activating substituent, such as methyl acrylate, crotonate, cinnamate, methacrylate, 3-buten-2-one, ( )-3-penten-2-one, ( )-4-phenyl-3-buten-2-one, and ( )-l-(p-tolyl)-3-phenyl-propenone, to give excellent yields of cycloadducts 142 (88JOC1384). 

The utility of an ester-derived five-membered ring carbonyl ylide dipole has been demonstrated in the first total synthesis of the biologically active natural product, ( )-epoxysorbicillinol (76) [90], a novel vertinoid polyke-tide possessing an epoxide functionality. The rhodivun(II)-catalyzed decom-... 

Hashimoto and co-workers have shown the enantioselective 1,3-dipolar cycloaddition of the ester-derived carbonyl ylides using chiral dirhodium(II) carboxylates [110]. The ester-derived carbonyl ylide from the a-diazo ketone 98 in the presence (1 mol%) of Rh2(S-PTTL)4 99 as the catalyst afforded the cycloadduct 100 with 93% ee (Scheme 30). 

Methylenation of carboxylic acid derivatives The Tebbe reagent 3 is extremely valuable as a reagent for the methylenation of carboxylic acid derivatives, which is generally unsuccessful using phosphorus ylides. Esters and lactones are readily transformed into enol ethers (Table 4.3), especially when a Lewis base such as THE is present in the reaction mixture. In the methylenation of a,j8-unsaturated esters, the internal olefin is not involved in the reaction, and the configuration of the double bond is maintained (entry 4). When carbonyl compounds bearing a terminal double bond are subjected to the methylenation, significantly lower yields are observed (entries 6 and 11), which may be attributable to competitive formation of a titanacycle from titanocene-methylidene 4 and the terminal olefin. 

A successful asymmetric organocatalytic based C=0 reduction with the Hantzsch ester was not reported until very recently. Terada and Toda developed a relay catalysis that combined Rh(ll) and a chiral phosphoric acid catalyst in a one-pot reaction (Scheme 32.15). In this reaction sequence, a rhodium carbene (I) forms in the first step and is followed with an intramolecular cyclization to afford carbonyl ylide intermediate II or oxidopyrylium III. These intermediates are protonated by 7 to yield the chiral ion pair between isobenzopyrylium and the conjugate base of 7 (IV). Intermediate IV is further reduced in situ by Hantzsch ester Id to produce the isochroman-4-one derivative 67, which is finally trapped with benzoyl chloride to afford the chiral product 68. Surprisingly, the reaction sequence proceeds well to give racemic product even without the addition of chiral 7, while giving rise to the desired product with high enantioselectivity in the presence of chiral Br0nsted acid 7 [38]. 

SCHEME 7.22 Carbonyl ylide formation/intermolecular cycloadditions of ester-derived carbonyl ylides with DMAD. 

They also reported high levels of enantioselection for the inter-molecular cycloadditions of ester-derived carbonyl ylides with DMAD (up to 93% ee, Rh2(S-PTTL)4) (Scheme 7.22) [58] and a-diazo ketone-derived carbonyl ylides with aromatic aldehydes (up to 92% ee, Rh2(S-BTPV)4) (Scheme 7.21) [59]. Dirhodium (II) tetrakis[A -tetrachIorophthaIoyI-(S)-ferf-Ieucinate], Rh2( 5-TCPTTL)4, was found to be an exceptionally effective catalyst for tandem carbonyl ylide formation/cycloaddition reactions of... 

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