Tertiary amine-catalyzed (3+3) annulations of δ-acetoxy allenoates: Substrate scope, synthetic application and mechanistic insight

Acetoxy allenoates as emerging synthons in annulation/cycloaddition reactions

In contrast to the normal allenoates (2,3-butadienoates) that undergo phosphine/amine addition generating dipolar-type intermediates, acetoxy allenoates that contain a facile-leaving -OAc group create electrophilic diene-phosphonium/ammonium intermediates rendering the reactivity pattern vastly different in the two cases. This review highlights the fascinating chemistry of acetoxy allenoates and related substrates. The diene-phosphonium/ammonium intermediate thus formed from acetoxy allenoate [substituted 5-acetoxypenta-2,3-dienoate or 2-(acetoxymethyl)buta-2,3-dienoate] participates in a plethora of cycloaddition/annulation reactions with bisnucleophiles generating multifunctional hetero- or homo-cycles in very few steps. Thus the electron-withdrawing effect of the phosphonium as well as carboxylate groups, making the diene-phosphonium/ammonium intermediates quite electrophilic, has been pivotal to the growth and significant interest during the last 10-15 years in this emerging class of substrates as revealed in this article. A comparison of this chemistry with that of (acetoxy)(acyl)allenes and allenyl acetates is also made briefly.

Asymmetric [4 + 2] cycloaddition synthesis of 4H-chromene derivatives facilitated by group-assisted-purification (GAP) chemistry

In this work, we present a strategy for the preparation of functionalized 4H-chromene derivatives via a Cs₂CO₃-catalyzed [4 + 2] cycloaddition of enantiopure chiral salicyl N-phosphonyl imines with allenoates. Fifteen examples were achieved in excellent yields and diastereoselectivity. The products were purified simply by washing the crude mixture with hexanes following the Group-Assisted Purification (GAP) chemistry/technology to bypass traditional separation methods. The absolute configuration was unambiguously determined by X-ray structure analysis.

A new asymmetric method for the synthesis of highly functionalized 4H-chromenes was developed via Group-Assisted Purification (GAP) chemistry and shown in good to high yield and excellent diastereoselectivity.