Iron-Catalysed Remote C(sp3)-H Azidation of O-Acyl Oximes and N -Acyloxy Imidates

The azido group occupies an important position in modern organic chemistry, broadly used as amine surrogates and as anchors in bioconjugation. Despite their importance, examples of selective direct azidation of inert C(sp3)–H bonds remain limited and often require strong oxidative conditions. Herein, we highlight the use of O-acyl oximes and N-acyloxy imidates as directing groups for the selective iron-catalysed azidation of C(sp3)–H bond with trimethylsilyl azide, giving access to various γ-azido ketones and β-azido alcohols in moderate to excellent yields. The iron catalyst is assumed to play a dual role in these catalytic processes: as a reductant to generate the reactive iminyl and imidate radicals, respectively, and as a redox centre to mediate the azido transfer to the translocated carbon radical.

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Azidation of Partially Protected Carbohydrate Derivatives: Efficient Suppression of Acyl Migration

Synlett ◽

10.1055/s-0040-1707137 ◽

2020 ◽

Vol 31 (15) ◽

pp. 1491-1496

Author(s):

Leonid O. Kononov ◽

Elena V. Stepanova ◽

Alexander I. Zinin ◽

Polina I. Abronina ◽

Alexander O. Chizhov

Keyword(s):

Organic Chemistry ◽

Phase Transfer ◽

Acyl Migration ◽

Hydroxyl Group ◽

Azido Group ◽

Protective Group ◽

Reaction Conditions ◽

Free Hydroxy Group ◽

Efficient Suppression ◽

Protective Groups

Although azidation by nucleophilic substitution is widely used in organic chemistry, it has a limitation for partially protected carbohydrate derivatives under typical reaction conditions used for azidation (heating with NaN3, phase-transfer catalyst (optional), DMF or DMSO) as it can cause substantial migration (70%) of O-acyl protective groups. Several approaches, including the use of a temporary protective group for the unprotected hydroxyl group, to avoid acyl migration have been compared. Addition of excess of ethyl trifluroacetate effectively suppressed benzoyl migration but inhibited substitution of the chlorine atom with the azido group. The most robust procedure involved addition of excess n-butyl formate to the reaction mixture. When this protocol was followed, migration of benzoyl groups in lactose derivatives with free hydroxy group at C-3′ or C-4′ was reduced to 4%, with the yield of the target, partially protected derivatives with an azido group in the aglycone approaching 92%.

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Themed collection: Synthetic approaches to natural products via catalytic processes

Organic Chemistry Frontiers ◽

10.1039/c8qo90009d ◽

2018 ◽

Vol 5 (4) ◽

pp. 529-530

Author(s):

Louis Fensterbank ◽

Shuanhu Gao ◽

Armen Zakarian

Keyword(s):

Organic Chemistry ◽

Natural Products ◽

Catalytic Processes ◽

Synthetic Approaches

Guest editors Louis Fensterbank, Shuanhu Gao and Armen Zakarian introduce this Organic Chemistry Frontiers themed collection entitled “Synthetic approaches to natural products via catalytic processes”.

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