Lithium ynolates 4 + 2 cycloaddition

The cycloaddition of the /V-2-methoxvphenvI aldimines with lithium ynolates (for a review see [134]) has been reported to give (3-lactams enolates, that... 

In a new benzannulation procedure, the 4 + 2-cycloaddition of lithium ynolates (131) with (trialkylsilyl)vinylketenes (132) yields, via an intermediate 3-(oxido)dienyl-ketene (133), the highly substituted phenols (134), which can be converted to ben-zofurans and benzopyrans (Scheme 37).135 The reaction of buta-2,3-dienoate with vinylketenimine yields the expected Diels-Alder adduct together with an unexpected aniline formed by a competing 2 + 2-cycloaddition.136 The first example of a... 

A. Formal [2 + 2] Cycloaddition of Lithium Ynolates with Aldehydes and... 

Multisubstituted five-membered aromatic heterocycles are synthesized via this cascade protocol (equation 34). The cycloadditions of a-acyloxyketones 78a with lithium ynolates afford /3-lactone lithium enolates 79a, which spontaneously cyclize to give bicyclic compounds 80a. These intermediates, which are stable enough to be isolated, are treated with TsOH under heating to provide substituted furans 81a via decarboxylation and dehydration. Thiophenes (e.g. 81b) are also synthesized by the analogous scheme via intermediate 80b using a-acylthioketones (78b) as a substrate. In the synthesis of pyrroles using a-acylaminoketones as a substrate, the cyclization proceeded at —20 °C, and the -lactone was subsequently ring-opened via /3-elimination to furnish pyrroles in one-pot (equation 35). ... 

The anionic inverse electron-demand 1,3-dipolar cycloaddition of nitrones 95 with lithium ynolates (equation 41) proceeds at 0°C to afford the substituted isoxazolidinones 97. The relative configuration is determined during the protonation step of the initial isoxazolidinone enolate adduct 96. With a thermodynamically controlled protonation, the trans products are mainly produced. The in situ alkylation of the resulting enolate adduct 96 furnishes the trisubstituted isoxazolidinone 98 with high diastereoselectivity. The isoxazolidinones are easily converted into /3-amino acids (99, 100) in good yield . 

Asymmetric cycloadditions of the chiral non-racemic nitrones 101 and 103 afford the isoxazolidinones 102 and 104 respectively, with high diastereoselectivity. This process can lead to an efficient asymmetric synthesis of /3-amino acids (equations 42 and 43) . This is the first example of asymmetric reactions with ynolates. It is noteworthy that the ynolates show higher reactivity and stereoselectivity than the corresponding lithium ester enolates and demonstrate the high potential of lithium ynolates in asymmetric reactions. 

The y-lactam 110 is prepared by the reaction of the lithium silyl-substituted ynolate 105 with the aziridine 108 activated by a p-toluenesulfonyl group. The initial product is the enolate 109, which can be acidified to yield the a-silyl-y-lactam 110. Intermediate 109 can be trapped by aldehydes to afford the a-alkylidene-y-lactams 111 via a Peterson reaction (equation 45) . These reactions may be considered to be formal [3 + 2] cycloadditions as well as tandem reactions involving nucleophilic ring opening and cyclization. 

Although the Michael addition of metal ynolates to a,/ -unsaturated carbonyl compounds is expected to give six-membered cycloadducts, 1,2-addition to carbonyl groups usually precedes 1,4-addition. The cycloaddition of the lithium-aluminum ate complex of silyl-substimted ynolate 112 with ethyl benzylideneacetoacetate (113), which is doubly activated by the ester and keto functions, gives the y-lactone 114 via a [4 4- 2] type cycloaddition (equation 46). Diethyl benzylidenemalonate (115) affords the uncyclized ketene 116 by reaction with 112 (equation 47). This could be taken as evidence for a stepwise mechanism for equation 46. ... 

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