Search results for "Chemical glycosylation"

showing 4 items of 4 documents

Glycosyl azides as building blocks in convergent syntheses of oligomeric lactosamine and Lewisx saccharides

1997

Abstract Oligosaccharides containing type 2 lactosamine repeating units, e.g. neo-lacto-octaose and trimeric Lewis x derivatives, are constructed using neo-lactosamine azide building blocks. The azido group provides a favorable protection of the anomeric position which is stable to versatile protecting group manipulations and glycosylation reactions. On the other hand, glycosyl azides can be converted into glycosyl fluorides via a 1,3-dipolar cycloaddition with di- tert -butyl-acetylenedicar☐ylate and subsequent treatment of the resulting N -glycosyl triazoles with hydrogen fluoride-pyridine complex. Activation of the lactosamine fluorides with Lewis acids affords the possibility to extend …

AzidesMagnetic Resonance SpectroscopyGlycosylationChemistryStereochemistryMolecular Sequence DataOrganic ChemistryClinical BiochemistryChemical glycosylationDisaccharideLewis X AntigenPharmaceutical ScienceAmino SugarsBiochemistrychemistry.chemical_compoundCarbohydrate SequenceDrug DiscoveryCarbohydrate ConformationMolecular MedicineGlycosylLewis acids and basesAzideGlycosyl donorProtecting groupMolecular BiologyBioorganic & Medicinal Chemistry
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A new method of anomeric protection and activation based on the conversion of glycosyl azides into glycosyl fluorides

1993

Glycosyl azides provide reliable anomeric protection stable to conditions for hydrolytic removal of ester groups, for reductive opening or release of acetalic diol protection, for the introduction of ether-type protection, and for glycosylation processes. The utility of this anomeric protection is further enhanced as glycosyl azides may be converted into glycosyl fluorides, which can be activated for glycosylation reactions. To this end, glycosyl azides have been subjected to 1,3-dipolar cycloaddition with di-tert-butyl acetylenedicarboxylate. On treatment with hydrogen fluoride-pyridine complex the N-glycosyl triazole derivatives directly give glycosyl fluorides.

AzidesMagnetic Resonance Spectroscopyanimal structuresAnomerGlycosylationOptical RotationMolecular Sequence DataCarbohydrate synthesismacromolecular substancesBiochemistryKoenigs–Knorr reactionAnalytical ChemistryFluoridesStructure-Activity Relationshipchemistry.chemical_compoundCarbohydrate ConformationOrganic chemistryGlycosylGlycosidesGlycosyl donorMolecular StructureOrganic ChemistryChemical glycosylationGlycosyl acceptorGeneral Medicinecarbohydrates (lipids)Carbohydrate Sequencechemistrylipids (amino acids peptides and proteins)Carbohydrate Research
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N-Glycosyl Amides as Glycosyl Donors in Stereoselective Glycosylation Reactions

2004

Due to their high stability, N-glycosyl amides have so far not been considered as glycosyl donors for glycosylation reactions. Two new procedures for the cleavage of the anomeric amide functionality under mild reaction conditions and further stereoselective in situ conversions of the activated glycosyl donors with alcohols and amines to give β-configured O- and N-glycosides are described in this article.

Reaction conditionsanimal structuresAnomerGlycosylationStereochemistryChemical glycosylationOrganic ChemistryGeneral Medicinemacromolecular substancesCleavage (embryo)Koenigs–Knorr reactionCatalysiscarbohydrates (lipids)chemistry.chemical_compoundchemistryAmidelipids (amino acids peptides and proteins)GlycosylStereoselectivityGlycosyl donorSynthesis
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N-Glycosyl Amides: Removal of the Anomeric Protecting Group and Conversion into Glycosyl Donors.

2003

chemistry.chemical_classificationGlycosylationAnomerMolecular StructureStereochemistryChemical glycosylationGlycosideGeneral ChemistryGeneral MedicineAmidesCatalysischemistry.chemical_compoundchemistryOrganic chemistryGlycosylGlycosidesGlycosyl donorProtecting groupChemInform
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