Radical Zinc-Atom Transfer Based Multicomponent Approaches to 3-Alkylidene-Substituted Tetrahydrofurans

 

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Abstract

A domino 1,4-addition/alkyne carbozincation sequence based on a radical zinc-atom transfer process is disclosed. Two efficient multicomponent approaches to 3-alkylidenetetrahydrofurans from β-(propargyloxy)enoates bearing pendant alkynes (including ynamides) have been established: one involving the direct addition of dialkylzincs, and the second involving the dimethylzinc-mediated addition of alkyl iodides. Both sequences utilize the stereoselective formation of intermediate alkylidenezincs well suited for in situ functionalization with electrophiles.

1 Introduction

2 1,4-Addition/Cyclization of Dialkylzincs on β-(Propargyl­oxy)enoates

2.1 β-(Propargyloxy)enoates with a Pendant Terminal Alkyne

2.2 β-(Propargyloxy)enoates with a Pendant Substituted Alkyne

2.3 β-(Propargyloxy)enoates with a Pendant Ynamide

3 1,4-Addition/Cyclization of Alkylzinc Halides on β-(Propargyloxy)enoates

4 Dialkylzinc-Mediated 1,4-Addition/Cyclization of Alkyl Iodides on β-(Propargyloxy)enoates

5 Conclusion; Current and Future Work

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Reductive zincation of a vinyl radical has also been suggested to account for the formation of allenoates following zinc-mediated radical addition to propiolates, see ref. 17.

See the supporting information in ref. 24.

When CH₂Cl₂ was used as solvent, the Z/E ratio of product 5ha might not fully represent the diastereoselectivity of the zinc-atom transfer since in addition to these two diastereomers, a third tetrahydrofuran side product having incorporated a butyl residue was detected (∼20% yield in the crude) but could not be fully identified. In any case the diastereoselectivity of the reaction between 1h and Bu₂Zn in CH₂Cl₂ should at best be mediocre.

See the Supporting Information.

• Supplementary Material