InCl3-CH3CN-H2O: an efficient catalyst-solvent combination for the synthesis of Perlin aldehydes and related compounds. Application in the synthesis of unnatural l-azasugars

InCl₃-CH₃CN-H₂O has been found to be an efficient catalyst-solvent combination for the synthesis of Perlin aldehydes and related compounds. While acetylated glycals afforded the Perlin aldehydes directly with InCl₃ and water, benzylated glycals on the other hand provided the hemiacetals under identical condition. The methodology reports a non-mercurial approach to Perlin aldehydes. Noteworthy is that this reaction is more facile as well as highly selective with glycals possessing a hydroxyl as a leaving group than with a benzyloxy group. Extension of this reaction to 2-C-hydroxymethyl glycals resulted in the formation of the corresponding hemiacetals, which were further transformed in to unsaturated azasugars with an exo-methylene group at C-2 position. Glycosidase inhibition studies reveal that these compounds display selectivity in inhibiting glucosidases rather than galactosidases.     

Homogeneous azidophenylselenylation of glycals using TMSN3-Ph2Se2-PhI(OAc)2

An improved preparative method for homogeneous azidophenylselenylation of glycals is described consisting of reaction with TMSN₃ and Ph₂Se₂ in the presence of PhI(OAc)₂. The use of TMSN₃ instead of NaN₃ as in the heterogeneous procedure, allowed both a reduced reaction time and a scale-up that was not possible in the case of the azidophenylselenylation of substituted glycals using NaN₃.     

An improved synthesis of pyrimidine- and pyrazole-based acyclo-C-nucleosides as carbohybrids

The synthesis of pyrimidine- and pyrazole-based acyclo-C-nucleosides as carbohybrids was optimized and developed. The synthesis of acyclic polyol-fused pyrimidines was achieved in good to excellent yield with high purity by the cyclocondensation of 2-C-formyl glycals and various amidines using K₂CO₃ as inorganic base in co-solvent system. In comparison, the syntheses of pyrazole-based acyclo-C-nucleosides were accomplished simply by the cyclocondensation of 2-C-formyl glycals with hydrazine hydrate at room temperature and with phenyl hydrazine at refluxing temperature in ethanol.     

Indium trichloride promoted stereoselective synthesis of O-glycosides from trialkyl orthoformates

A novel, highly stereoselective method for O-glycosylation of glycals and glycosylbromides is developed using orthoformates as acceptors in the presence of InCl₃ to afford the corresponding O-glycopyranosides in 66-94% yield. Both perbenzyl and peracetyl glycals afford the corresponding 2,3-unsaturated-O-glycosides with high α-selectivity. Stoichiometric amounts of orthoformates are sufficient to bring about this transformation instead of large excesses of alcohols.     

Direct Ferrier rearrangement on unactivated glycals catalyzed by indium(III) chloride

Anhydrous InCl₃ has been shown to efficiently catalyze the Ferrier rearrangement by a direct allylic substitution of the hydroxyl group at C-3 position of glycals to afford the corresponding 2,3-unsaturated glycosides in high yields at ambient temperature. This methodology obviates the need for protecting and/or activating the C-3 hydroxyl group of glycals. The reaction works in equal ease with both 4,6-di-O-benzyl-d-glucal and 4,6-di-O-benzyl-d-galactal. The mildness of InCl₃ makes this approach compatible for glycosyl acceptors with acid labile groups. The generality of the reaction has been demonstrated with a diversity of alcohols, phenols, and sugar nucleophiles.     

Stereoselective synthesis of 2-C-methylene glycosides and disaccharides via direct allylic substitution of hydroxy group in benzylated glycals

InCl₃ efficiently catalyzes allylic substitution of the hydroxy group of 2-C-hydroxymethyl glycals to afford a diversity of 2-C-methylene alkyl and aryl glycosides as well as disaccharides in high yields. This protocol surpasses the existing methods for the synthesis of 2-C-methylene glycosides as it obviates the need for functionalizing the allylic hydroxy group of glycals. The interest of this methodology relies on the extremely mild conditions required even with a free hydroxyl group at the allylic position of the glycals and that too only with a catalytic amount of InCl₃. The reaction is fast (30 min.), stereoselective and is compatible with a variety of oxygenated nucleophiles including those possessing acid-labile groups. A mechanistic investigation on the direct formation of an α,α-(1→1)linked disaccharide derivative from 2-C-hydroxymethyl galactal reveals that the reaction proceeds through a domino Ferrier rearrangement followed by a facile 1,3-alkoxy migration.     

Reactions of glycals with xenon fluoride: an improved synthesis of 2-deoxy-2-fluorosaccharides

The 1,2-double bond in acetylated glycals has been fluorinated with XeF₂ in the presence of BF₃ to give 1,2-deoxy-1,2-difluorosaccharides. A mechanism for this reaction has been proposed. This method represents an improvement in the synthesis of 2-deoxy-2-fluorosaccharides.     

Ferric Sulphate Hydrate–Catalyzed,Microwave‐Assisted Synthesis of 2,3‐Unsaturated O‐Glycosides via the Ferrier Reaction

Fe₂(SO₄)₃ · xH₂O catalyzes the Ferrier reaction of per‐O‐acetylated/benzylated glycals with alcohols to give 2,3‐unsaturated α‐glycosides in a few minutes under microwave irradiation.     

An efficient synthesis of 1-cyano-2,3-unsaturated sugars via the reaction of glycals with Et2AlCN

The reaction of glycals 1a-d with Et₂AlCN in benzene at room temperature leads to formation of the corresponding 1-cyano-2,3-unsaturated sugars 2a-d and 3a-d in good to excellent yields.     

Niobium(V) chloride catalyzed microwave assisted synthesis of 2,3-unsaturated O-glycosides by the Ferrier reaction

NbCl₅ catalyzes the Ferrier reaction of per-O-acetylated glycals with primary, secondary, allylic, benzylic and monosaccharide alcohols to give 2,3-unsaturated α-glycosides in short reaction times under microwave irradiation conditions.