1 article(s) from Hocek, Michal
Solution-state conformations of D-glucose.
Jump to Scheme 1
Enzymatic synthesis of oligosaccharides.
Jump to Scheme 2
Enzymatic synthesis of a phosphorylated glycoprotein containing a mannose-6-phosphate (M6P)-termina...
Jump to Scheme 3
A) Selected GTs-mediated syntheses of oligosaccharides and other biologically active glycosides. B)...
Jump to Scheme 4
Enzymatic synthesis of nucleosides.
Jump to Scheme 5
Fischer glycosylation strategies.
Jump to Scheme 6
The basis of remote activation (adapted from ).
Jump to Scheme 7
Classic remote activation employing a MOP donor to access α-anomeric alcohols, carboxylates, and ph...
Jump to Scheme 8
Synthesis of monoprotected glycosides from a (3-bromo-2-pyridyloxy) β-D-glycopyranosyl donor under ...
Jump to Figure 1
Plausible mechanism for the synthesis of α-galactosides. TBDPS = tert-butyldiphenylsilyl.
Jump to Scheme 9
Synthesis of the 6-O-monoprotected galactopyranoside donor for remote activation.
Jump to Scheme 10
UDP-galactopyranose mutase-catalyzed isomerization of UDP-Galp to UDP-Galf.
Jump to Scheme 11
Synthesis of the 1-thioimidoyl galactofuranosyl donor.
Jump to Scheme 12
Glycosylation of MeOH using a self-activating donor in the absence of an external activator. a) Syn...
Jump to Scheme 13
The classical Lewis acid-catalyzed glycosylation.
Jump to Scheme 14
Unprotected glycosyl donors used for the Lewis acid-catalyzed protecting group-free glycosylation r...
Jump to Figure 2
Four-step synthesis of the phenyl β-galactothiopyranosyl donor.
Jump to Scheme 15
Protecting-group-free C3′-regioselective glycosylation of sucrose with α–F Glc.
Jump to Scheme 16
Synthesis of the α-fluoroglucosyl donor.
Jump to Scheme 17
Protecting-group-free glycosyl donors and acceptors used in the Au(III)-catalyzed glycosylation.
Jump to Figure 3
Synthesis of the mannosyl donor used in the study .
Jump to Scheme 18
The Pd-catalyzed stereoretentive glycosylation of arenes using anomeric stannane donors.
Jump to Scheme 19
Preparation of the protecting-group-free α and β-stannanes from advanced intermediates for stereoch...
Jump to Scheme 20
Selective anomeric activating agents providing donors for direct activation of the anomeric carbon.
Jump to Figure 4
One-step access to sugar oxazolines or 1,6-anhydrosugars.
Jump to Scheme 21
Enzymatic synthesis of a chitoheptaose using a mutant chitinase.
Jump to Scheme 22
One-pot access to glycosyl azides , dithiocarbamates , and aryl thiols using DMC activation and sub...
Jump to Scheme 23
Plausible reaction mechanism.
Jump to Scheme 24
Protecting-group-free synthesis of anomeric thiols from unprotected 2-deoxy-2-N-acetyl sugars.
Jump to Scheme 25
Protein conjugation of TTL221-PentK with a hyaluronan hexasaccharide thiol.
Jump to Scheme 26
Jump to Scheme 27
Direct two-step one-pot access to glycoconjugates through the in situ formation of the glycosyl azi...
Jump to Scheme 28
DMC as a phosphate-activating moiety for the synthesis of diphosphates. aβ-1,4-galactose transferas...
Jump to Scheme 29
Triazinylmorpholinium salts as selective anomeric activating agents.
Jump to Figure 5
One-step synthesis of DBT glycosides from unprotected sugars in aqueous medium.
Jump to Scheme 30
Postulated mechanism for the stereoselective formation of α-glycosides.
Jump to Scheme 31
DMT-donor synthesis used for metal-catalyzed glycosylation of simple alcohols.
Jump to Scheme 32
Protecting group-free synthesis of glycosyl sulfonohydrazides (GSH).
Jump to Figure 6
The use of GSHs to access 1-O-phosphoryl and alkyl glycosides. A) Glycosylation of aliphatic alcoho...
Jump to Figure 7
A) Proposed mechanism of glycosylation. B) Proposed mechanism for stereoselective azidation of the ...
Jump to Scheme 33
Mounting GlcNAc onto a sepharose solid support through a GSH donor.
Jump to Scheme 34
Lawesson’s reagent for the formation of 1,2-trans glycosides.
Jump to Scheme 35
Protecting-group-free protein conjugation via an in situ-formed thiol glycoside .
Jump to Scheme 36
pH-Specific glycosylation to functionalize SAMs on gold.
Jump to Scheme 37
Protecting-group-free availability of phenolic glycosides under Mitsunobu conditions. DEAD = diethy...
Jump to Figure 8
Accessing hydroxyazobenzenes under Mitsunobu conditions for the study of photoswitchable labels. DE...
Jump to Scheme 38
Stereoselective protecting-group-free glycosylation of D-glucose to provide the β-glucosyl benzoic ...
Jump to Scheme 39
Direct synthesis of pyranosyl nucleosides from unactivated and unprotected ribose using optimized M...
Jump to Figure 9
Direct synthesis of furanosyl nucleosides from 5-O-monoprotected ribose in a one-pot glycosylation–...
Jump to Figure 10
Synthesis of ribofuranosides using a monoprotected ribosyl donor via an anhydrose intermediate.
Jump to Figure 11
C5′-modified nucleosides available under our conditions.
Jump to Figure 12
Plausible reaction mechanism for the formation of the anhydrose.
Jump to Scheme 40
Direct glycosylation of several aliphatic alcohols using catalytic Ti(Ot-Bu)4 in the presence of D-...
Jump to Figure 13
Access to glycosides using catalytic PPh3 and CBr4.
Jump to Figure 14
Access to ribofuranosyl glycosides as the major product under catalytic conditions. aLiOCl4 (2.0 eq...
Jump to Figure 15
Beilstein J. Org. Chem. 2017, 13, 1239–1279, doi:10.3762/bjoc.13.123
Subscribe to our Latest Articles RSS Feed.
Register and get informed about new articles.
Follow the Beilstein-Institut