Yb(OTf)3-catalyzed C-glycosylation: highly stereoselective synthesis of C-pseudoglycals

Zinc tetrafluoroborate catalyzed α-stereoselective synthesis of pseudoglycals: efficient synthesis of digitoxin α-L-amicetose

We report here an efficient, fast, and cost-effective strategy for synthesizing pseudoglycals by the reaction of glycals with alcohols or nucleophiles using zinc tetrafluoroborate. This mild, transition metal-free approach allowed the α-selective synthesis of pseudoglycals using a wide range of acceptors containing various protecting groups/functionalities. This method is exemplified by the synthesis of digitoxin α-L-amicetose, a known potential cardiac glycoside anticancer agent. The improved 3-step synthesis from L-rhamnal afforded an overall yield of 54%, thus representing a significant improvement over the previous method.

Ferrier Glycosylation Mediated by the TEMPO Oxoammonium Cation

The TEMPO oxoammonium cation has been proven to be both an efficient oxidizing reagent and an electrophilic substrate frequently found in organic reactions. Here, we report that this versatile chemical reagent can also be used as an efficient promoter for C- and N-glycosylation reactions through a Ferrier rearrangement with moderate to high yields. This unprecedented reactivity is explained in terms of a Lewis acid activation of glycal by TEMPO+ forming a type of glycal-TEMPO+ mesomeric structure, which occurs through an extended vinylogous hyperconjugation toward the π*(O═N+) orbital [LP(O1) → π*(C1═C2), π*(C1═C2) → σ*(C3-O3), and LP(O6) → π*(O═N+)]. This enables the formation of the respective Ferrier glycosyl cation, which is trapped by various nucleophiles. The extended hyperconjugation (or double hyperconjugation) toward the π*(O═N+) orbital, which confers the Lewis acid character of the TEMPO cation, was supported by natural bond orbital analysis at the M06-2X/6-311+G** level of theory.

Efficient carbon-Ferrier rearrangement on glycals mediated by ceric ammonium nitrate: Application to the synthesis of 2-deoxy-2-amino-C-glycoside

A carbon-Ferrier rearrangement on glycals has been performed by using ceric ammonium nitrate to obtain products in moderate to good yields with high selectivity. The versatility of this method has been demonstrated by applying it to differently protected glycals and by employing several nucleophiles. The obtained C-allyl glycoside has been utilized for the synthesis of a orthogonally protected 2-amino-2-deoxy-C-glycoside.

A facile Er(OTf)3-catalyzed synthesis of 2,3-unsaturated O- and S-glycosides

Er(OTf)(3) is a useful catalyst for the Ferrier rearrangement furnishing high yields of O- and S-glycosides. The transformation has wide applicability, cleaner reaction profiles, mild reaction conditions, and high stereoselectivity and the catalyst, which is also commercially available, can be recovered and reused.

Design, total synthesis, and biological evaluation of neodysiherbaine A derivative as potential probes

To enable studies to elucidate the detailed biological function of dysiherbaine and neodysiherbaine A, potent and subunit-selective agonists for ionotropic glutamate receptors, the derivative with a hydroxymethyl substituent at the C10 position has been developed. Preliminary biological evaluation of the analogue showed that a C10 hydroxymethyl substituent produced significant alterations in binding affinities for the ionotropic glutamate receptor subtypes.

Protic Acid (HClO4 Supported on Silica Gel)-Mediated Synthesis of 2,3-Unsaturated-O-glucosides and a Chiral Furan Diol from 2,3-Glycals

Perchloric acid supported on silica gel acts as an excellent reagent system in converting glucals into 2,3-unsaturated-O-glucosides in good to excellent yields in short reaction time with good alpha selectivity. Primary, secondary, and allylic alcohols, phenols, and thiols react with 3,4,6-tri-O-acetyl glucal with equal ease. In addition to this, a chiral furan diol is obtained from unprotected D-glucal or D-galactal in good yields.