Urea–hydrogen peroxide prompted the selective and controlled oxidation of thioglycosides into sulfoxides and sulfones

A practical method for the selective and controlled oxidation of thioglycosides to corresponding glycosyl sulfoxides and sulfones is reported using urea–hydrogen peroxide (UHP). A wide range of glycosyl sulfoxides are selectively achieved using 1.5 equiv of UHP at 60 °C while corresponding sulfones are achieved using 2.5 equiv of UHP at 80 °C in acetic acid. Remarkably, oxidation susceptible olefin functional groups were found to be stable during the oxidation of sulfide.

Glycosyl sulfoxides and sulfones are prepared from the corresponding sulfides using various oxidizing reagents [5][6][7]10]. Al- though a number of oxidation methods were developed for the oxidation of simple organic sulfides to corresponding sulfoxides and sulfones [14][15][16], there are only limited reports available for the preparation of glycosyl sulfoxides and sulfones from corresponding thioglycosides [5][6][7][17][18][19][20][21][22][23]. Moreover, there is no report available where a given oxidant is suitable for controlled oxidation of thioglycosides to glycosyl sulfoxides and sulfones selectively by altering the reaction conditions. It is also observed that thioglycoside oxidation suffers from low yields, poor selectivity (i.e., sulfoxide vs sulfone), use of inconvenient reaction conditions and expensive oxidants, intolerance of other oxidation susceptible functional groups, etc. Thus, developing a mild and efficient method for the controlled oxidation of sulfides to corresponding glycosyl sulfoxides and sulfones, is of great interest.
The utility of hydrogen peroxide-solid adducts in organic synthesis is well explored [24]. Most of them are found to be stable which can be easily handled and stored. One such solid adduct is urea-hydrogen peroxide (UHP) which is considered to be a safer and efficient alternative to high concentrated aqueous hydrogen peroxide solution [25]. In addition, UHP is also commercially available, inexpensive and nontoxic. The application of UHP as oxidant is well explored in various solution-as well as solid-phase organic syntheses [25][26][27][28]. In fact, we have recently reported the oxidation of arylboronic acids into corresponding phenols by using UHP as a selective oxidizing agent [29]. In continuation to our effort in developing green methodologies [29][30][31][32][33], here we disclose an efficient and practical method for the conversion of glycosyl sulfides into sulfoxides and sulfones in a selective and controlled manner using urea-hydrogen peroxide in acetic acid.

Results and Discussion
Initially, phenyl-2,3,4,6-tetra-O-acetyl-1-thio-β-D-glucopyranoside (1) was chosen as a substrate for the optimization study and oxidation was performed in various solvents at different temperatures in the presence of urea-hydrogen peroxide (UHP) ( Table 1). Polar aprotic solvents such as dichloromethane and acetonitrile gave a negligible amount of corresponding sulfoxide (1a) while no sulfone (1b) was detected at room temperature even after 6 hours ( Table 1, entries 1 and 2). However, protic solvents such as methanol, ethanol, tert-butanol and acetic acid were found to be relatively efficient media for the oxidation when compared with dichloromethane and acetonitrile (Table 1, entries 3-6). Among them, acetic acid gave 37% of the glycosyl sulfoxide (1a) after 6 h at room temperature with one equiv of UHP (Table 1, entry 6) while alcoholic solvents gave a low yield. When we increased the amount of UHP to 1.5 equiv, the reaction provides only 64% of the desired sulfoxide at room temperature (Table 1, entry 7). Therefore, the reaction was further investigated at elevated temperatures using 1.5 equiv of UHP (Table 1, entries 8 and 9) in acetic acid. Interestingly, the reaction was driven to completion with the desired sulfoxide (1b) in 92% yield within 2 h at 60 °C (Table 1, entry  9). It is also worth noting that less than 5% of the corresponding sulfone was detected in the crude product by 1 H NMR under these conditions.
Considering the importance of glycosyl sulfones, we further investigated the suitable conditions for the direct oxidation of sulfide to sulfone using UHP in acetic acid. For this, we have tried the reactions with an increased amount of UHP and elevated temperature (Table 1, entries 10-12). It was observed that with 1.5 to 2.0 equiv of UHP at 80 °C, the reaction yields a mixture of sulfoxide 1a and sulfone 1b (Table 1, entries [10][11] in different ratio. However, by increasing the amount of UHP to 2.5 equiv, sulfide 1 is fully converted to the corresponding sulfone 1b in an excellent yield, i.e., 93% in 10 h at 80 °C (Table 1, entry 12).
With optimized conditions in hand (Table 1, entries 9 and 12), a controlled oxidation of various glycosyl sulfides to corresponding sulfoxides and sulfones was studied with urea-hydrogen peroxide in acetic acid (Table 2). For this study, a series of αand β-thioglycosides, 1-19 were initially prepared by using literature procedures (see Supporting Information File 1). In addition, structurally diverse aglycone moieties were selected in order to study the breadth and scope of the current methodology. Initially, the oxidation of O-acetylated and benzoylated phenyl and p-tolyl thioglucopyranosides was examined ( Table 2, entries 1-4). These aryl sulfides underwent oxidation very efficiently to provide the corresponding sulfoxides 1a-4a in excellent yields, i.e., 85-93% under optimized conditions. Similarly,  corresponding glycosyl sulfones 1b-4b were also achieved in 91-94% yield by simply altering the reaction conditions as described in the optimization study.
We further examined the oxidation of O-acetyl-(Ac) and benzoyl-(Bz) protected benzyl thioglucopyranosides, which showed a good selectivity during the controlled oxidation with UHP and provided >87% and >89% of the desired sulfoxides (5a and 6a) and sulfones (5b and 6b), respectively ( Table 2, entries 5 and 6). Similar to phenyl and benzyl sulfides, alkyl sulfides such as ethyl, n-hexyl and cyclohexyl glycosyl sulfides were also successfully oxidized in a controlled and selective manner with equal efficiency ( Table 2, entries 7-12).
Having studied the oxidation of electron deficient thioglucopyranosides, we further investigated the oxidation of O-benzyl protected 4-methylphenyl thioglycoside 13 under optimized conditions ( Table 2, entry 13). This substrate was found to be more reactive than O-acetylated and benzoylated thioglycosides and gave the sulfoxide in a good yield within 1.5 h. However, corresponding sulfone was obtained in a moderated yield due to instability which undergoes partial amount of decomposition.
In general, olefins functional groups are known to undergo epoxidation or dihydroxylation with different oxidizing agents (e.g. m-CPBA, t-BuOOH, oxone, etc.) [34]. Therefore, the scope of this methodology was further investigated with oxidation of allyl group protected thioglycoside 14 ( Table 2, entry  14). Remarkably, allyl groups were found to be very stable during the oxidation while sulfide underwent selective oxidation to corresponding sulfoxide and sulfone in 89% and 91%, respectively. Further, we have studied the oxidation of protected glucosamine thioglycoside (

Conclusion
In conclusion, we have developed a practical method for the selective and controlled oxidation of thioglycosides to corresponding glycosyl sulfoxides and sulfones using the stable, inexpensive and commercially available oxidant urea-hydrogen peroxide (UHP). Glycosyl sulfoxides were achieved using 1.5 equiv of UHP at 60 °C while sulfones were achieved using 2.5 equiv of UHP at 80 °C. Remarkably, oxidation susceptible olefin functional groups were found to be stable during the sulfide oxidation.