Knoevenagel condensation/ketalization cascade

A further small tweaking of the reaction conditions involves great changes a further new cascade channel is breaking. This is accomplished by modulation of the nucleophilicity of the activated methylene compounds applied. When used with isocyanoacetate 87 instead of cyanoacetates 86 as a methylene-activated component, an Ugi-like multicomponent cascade reaction is observed. This reaction was first detected by deployment of ethyl isocyanoacetate 87 in reactions of ribose and proline. In these experiments, proline—once the catalyst in the Knoevenagel condensation/ketalization/oxa-Michael cascade reactions—is directly incorporated into the product. As a result of that, seven-membered lactone 89 is formed. This sharp difference is demonstrated in Scheme 2.18 [40]. 

Similar to the mechanism described in Scheme 2.16, a Knoevenagel reac-tion/ketalization cascade of hydroxyacetone with 1,3-dicarbonyl compounds is assumed. In Scheme 2.16, a Knoevenagel condensation/ketalization reaction is depicted. This sequence allows a subsequent oxa-Michael addition, which yields the corresponding C-glycosides. In contrast, a Knoevenagel addition/ketalization occurs under the reaction condition described in Scheme 2.28, which is followed by an intramolecular retro-Claisen step. As a result of that, the corresponding esters were obtained (Scheme 2.29). 

In the amine-catalyzed reactions, a Knoevenagel addition/ketalization/ intramolecular retro-Claisen cascade is detected (Scheme 2.32). The retro-Claisen step is enabled by the ketalization of the Knoevenagel addition product Q. The ketalization of the Knoevenagel product (Q S) is initiated by the hydroxyl groups of the carbohydrate moiety, as in-house NMR-experiments suggest (formation of intermediate ketal structure K in Knoevenagel condensation/ketalization/oxa-Michael cascade reaction Scheme 2.16). Products derived from this reaction sequence (Scheme 2.16)... 

Based on these findings obtained, a Knoevenagel/ketalization/oxa-Michael cascade reaction can be assumed (Scheme 2.16). In the first step of the reaction cascade, an E -selective Knoevenagel reaction of the carbohydrate takes place (I in Scheme 2.16). This condensation process is followed by a stereoselective ketalization dictated by the configuration of the 2-hydroxy group of the carbohydrate (K). Subsequent Reside attack of the 4-hydroxy group gives an access to fused tetrahydrofiiran structure L. Structure L is identical with that of compound 74, which is obtained when used... 

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