Directed C−H Bond Oxidation of Bridged Cycloalkanes Catalyzed by Palladium(II) Acetate

Abstract: We have developed a synthesis of 1,2-substituted adamantane carboxylic acids and further bridged cycloalkanes (cage compounds) by palladium acetate-catalyzed C-H bond oxidation. Acetoxylation of cycloalkane framework was performed using picolylamide as a directing group. Modification of the substrate, ligand design and variation of reaction conditions enabled us to study the mechanism of acetoxylation of aliphatic compounds. Post-functionalization reactions and cleavage of the directing group were developed. F… Show more

“…The oxidation of the palladacycle to the corresponding C-O bond is proposed to proceed via concerted demetalation-oxidation (CDO) or oxidation of Pd(II) complex to Pd(IV). 56 Scheme 39 Acetoxylation of a adamantanecarboxylic acid derivative to give the depicted stereoisomers formed in this reaction; stereoisomers with acetoxy groups facing each other are not formed A method for the alkynylation of aliphatic carboxylic acid derivatives and amino acid derivatives was developed using a perfluorinated aniline as the directing group (Scheme 40). 57 For the adamantane-1-carboxylic acid derivative 85, monoethynylation of the scaffold was observed in 53% yield.…”

Directed C–H Functionalization of the Adamantane Framework

“…The oxidation of the palladacycle to the corresponding C-O bond is proposed to proceed via concerted demetalation-oxidation (CDO) or oxidation of Pd(II) complex to Pd(IV). 56 Scheme 39 Acetoxylation of a adamantanecarboxylic acid derivative to give the depicted stereoisomers formed in this reaction; stereoisomers with acetoxy groups facing each other are not formed A method for the alkynylation of aliphatic carboxylic acid derivatives and amino acid derivatives was developed using a perfluorinated aniline as the directing group (Scheme 40). 57 For the adamantane-1-carboxylic acid derivative 85, monoethynylation of the scaffold was observed in 53% yield.…”

Directed C–H Functionalization of the Adamantane Framework

“…Hrdina with coworkers developed Pd(II)-catalyzed acetoxylation of C(sp 3 )-H bonds adjacent to the amide moiety in bridged cage compounds such as adamantane derivatives 35. [40] Acetoxylation was performed using S C H E M E 4 γ-C-H acyloxylation of free amines using transient directing group (TDG) and bystanding oxidant and α-C(sp 3 )-H acetoxylation of Tröger's bases various bidentate DGs, with picolilamide providing the highest yields of desired products 36 (Scheme 7). The selectivity of mono-acetoxylation depended significantly on the reaction conditions and the nature of added base.…”

Recent progress in catalytic acyloxylation of C(sp³)‐H bonds

“…[5] Regioselective functionalization of two neighbouring carbons, a methine and a methylene units, are possible when a former substituent already present in the adamantane framework is able to assist the second CÀ H activation acting as directing group in typically a metal catalysed process (Figure 1B). [6] Despite this, the number of protocols already established to access 1,2-disubstituted adamantane derivatives is comparatively quite reduced. [7] Even more scarce are the examples in which the adjacent di-functionalization of heptacyclo [6.6.0.0 2,6 .0 3, 13 .0 4,11 .0 5,9 .0 10,14 ] tetradecane (HCTD, 10), the D 2d -symmetric isomer of 2 in which all carbons are part of five-membered rings, has been achieved.…”

“…[6] Despite this, the number of protocols already established to access 1,2-disubstituted adamantane derivatives is comparatively quite reduced. [7] Even more scarce are the examples in which the adjacent di-functionalization of heptacyclo [6.6.0.0 2,6 .0 3, 13 .0 4,11 .0 5,9 .0 10,14 ] tetradecane (HCTD, 10), the D 2d -symmetric isomer of 2 in which all carbons are part of five-membered rings, has been achieved. The routes available proceed through oxidative opening of the cage and without exception deliver product mixtures and marginal yields.…”

Towards an Effective Synthesis of Difunctionalized Heptacyclo [6.6.0.0^2,6.0^3,13.0^4,11.0^5,9.0^10,14]tetradecane: Ligand Effects on the Cage Assembly and Selective C−H Arylation Reactions