Regio- and Stereoselectivity of Diethylaluminum Azide Opening of Trisubstituted Epoxides and Conversion of the 3° Azidohydrin Adducts to Isoprenoid Aziridines

Abstract: The regioisomer ratios (3 degrees,2 degrees /2 degrees,3 degrees ), and in some cases the stereochemistry, of vicinal azidohydrins formed in reactions of 11 trisubstituted terpene epoxides with Et(2)AlN(3) in toluene are reported. The more highly substituted azide usually predominated (3 degrees,2 degrees /2 degrees,3 degrees ratios >or= 40:1 to 2.5-1) in accord with a Markovnikov orientation and an S(N)1-like transition state. Reversed regioisomer ratios were observed with 6,7-epoxygeranyl acetate (1:2.5) and… Show more

“…Protection of the hydroxyl group in geraniol (2) by acetyl chloride in pyridine gave 3 in 84% yield. Selective epoxidation of 3 at the double bond between C-6, C-7 with m-chloroperoxybenzoic acid afforded 4 (72%), and the ring cleavage reaction was undertaken with periodic acid to afford aldehyde 5 (80%) [27,28]. Next, protection of the aldehyde group of 5 gave acetal 6 in 90% yield, and removal of the acetyl group of 6 with anhydrous potassium carbonate afforded alcohol 7 in 82% yield.…”

Construction of the 1,2-Dialkenylcyclohexane Framework via Ireland-Claisen Rearrangement and Intramolecular Barbier Reaction: Application to the Synthesis of (±)-Geijerone and a Diastereoisomeric Mixture with Its 5-Epimer

“…Protection of the hydroxyl group in geraniol (2) by acetyl chloride in pyridine gave 3 in 84% yield. Selective epoxidation of 3 at the double bond between C-6, C-7 with m-chloroperoxybenzoic acid afforded 4 (72%), and the ring cleavage reaction was undertaken with periodic acid to afford aldehyde 5 (80%) [27,28]. Next, protection of the aldehyde group of 5 gave acetal 6 in 90% yield, and removal of the acetyl group of 6 with anhydrous potassium carbonate afforded alcohol 7 in 82% yield.…”

Construction of the 1,2-Dialkenylcyclohexane Framework via Ireland-Claisen Rearrangement and Intramolecular Barbier Reaction: Application to the Synthesis of (±)-Geijerone and a Diastereoisomeric Mixture with Its 5-Epimer

“…Excellent yields of the desired β-azido alcohols are obtained with a reversal of regioselectivity indicating attack at the less substituted carbon of the aliphatic oxiranes (Entries 2-7, Table 2), while styrene oxide (Entry 1, Table 2), as an aryl oxirane formed the major product as 2-azido-2-phenylethanol, by the attack of azide nucleophile at the benzylic position, this is due to the formation of a stable benzyl carbocation during mechanism, is evidenced by electronic factors [25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40], whereas in the case of aliphatic oxiranes (Entries 2-7, Table 2), steric factors predominate over electronic factors, thereby facilitating attack at the less hindered carbon atom of the oxirane ring. Furthermore, oxiranes derived from cycloalkenes, such as 7-oxabicyclo [4.1.0]heptanes (Entry 2, Table 2), reacted smoothly in SN2 fashion to afford the corresponding azidohydrine; and the reaction was completely anti-sterioselective, thus resulting in trans isomer only.…”

“…However, the azide opening is promoted by traditional homogeneous systems as metal chlorides [25,26], salts [27] and alkyl metal azides [28][29][30][31][32]. Some heterogeneous catalysts, relying on the use of traditional solid acids such as amberlite IRA-400 supported azide [33].…”

SO3H-Carbon derived from glycerol: An efficient and recyclable catalyst for smooth and regioselective azidolysis of oxiranes in water

“…In fact, the same experiment carried out in exactly the same conditions but using bare silica instead of acid-functionalized silica gave very poor yields. The three different limonene 1,2-epoxide opening products (entries 7-9) [19][20][21], which exclusively gave the trans-diaxial hydroxyether [22], were subjected to a series of NMR studies. [23] 92/84 100/68 2 styrene epoxide EtOH [23] 88/82 99/64 3 styrene epoxide iPrOH [23] 86/81 98/68 4 cyclohexene oxide MeOH [23] 100/100 100/89 5 cyclohexene oxide EtOH [23] 100/100 100/83 Figure 2).…”

Intensification of organic reactions with hybrid flow reactors