Sulfoxides, Pummerer rearrangement

Pummerer rearrangement. Sulfoxides are converted into a-siloxy sulfides, in which the new 0-C bond is anti to the original S-0 bond. Accordingly, the rearrangement of chiral sulfoxides is enantioselective. The method is applicable to synthesis of /3-lactam precursors. ... 

Sharpless and Masumune have applied the AE reaction on chiral allylic alcohols to prepare all 8 of the L-hexoses. ° AE reaction on allylic alcohol 52 provides the epoxy alcohol 53 in 92% yield and in >95% ee. Base catalyze Payne rearrangement followed by ring opening with phenyl thiolate provides diol 54. Protection of the diol is followed by oxidation of the sulfide to the sulfoxide via m-CPBA, Pummerer rearrangement to give the gm-acetoxy sulfide intermediate and finally reduction using Dibal to yield the desired aldehyde 56. Homer-Emmons olefination followed by reduction sets up the second substrate for the AE reaction. The AE reaction on optically active 57 is reagent... 

An intramolecular version of enolate Michael addition to enantiomerically pure vinylic sulfoxides is represented by reaction of a cyclopentenone sulfoxide with dichloroketene (Scheme 5)90 this type of additive Pummerer rearrangement has been developed by Marino and coworkers91 into a highly effective way of constructing variously substituted lactones in very high enantiomeric purity (equation 43). 

Cyclization of the sulfoxide 1248 with TMSOTf 20/DlPEA affords a 4 1 mixture of the tetrahydroquinolines 1249 and 1250, in 97% yield, and HMDSO 7 [49]. On heating of the sulfoxide 1251 to 80 °C Brook rearrangement then Sila-Pummerer rearrangement-cyclization gives, via 1252, 17% 1253 [50] (Scheme 8.19). 

The differing nucleophilicity of acetate and trifluoroacetate anion determined the manner in which naphtho[l,8-/yt]-l,5-dithiocinc sulfoxide 127 rearranged on treatment with acetic and trifluoroacetic anhydrides. In both cases, the reaction proceeded through formation of a disulfonium dication 128, but the final products were different. When acetic anhydride was used, the reaction afforded the corresponding a-acetylsulfide 130, a normal product of the Pummerer rearrangement, while trifluoroacetic anhydride caused isomerization with formation of dithioacetal 132 (see Scheme 16) <1995HAC559>. 

Heating of the sulfoxide 31 causes a Pummerer rearrangement generating the ylide 32, which could be trapped with dimethyl acetylenedicarboxylate (DMAD) giving the dihydrothiophene derivative 33 <06HC648>. 

Monosulfoxide 13 undergoes the Pummerer rearrangement when treated with acetic anhydride in the presence of sodium acetate.85 The experiments with tetradeuterated and 180-labeled sulfoxide confirm intermediate formation of a dication.86 The ratio of 2,8,8-trideuteriated to 4,4,6,6-tetradeuteriated product 37 is equal to the intramolecular isotope effect ku k0 =1.7 (Scheme 21).85... 

Reaction of -dimethylthiobenzene sulfoxide 56 with trifluoroacetic anhydride results in a mixture of sulfide 65 and the corresponding mono- and disubstituted products of the Pummerer rearrangement 63, 64 via intermediate disulfonium dication 62 (Scheme 23).88... 

The unsaturated sulfinyl compound 105 can be converted into the iodooxathiane 107 either directly by AModosuccinimide or via the sulfoxide 106, providing the first example of an iodonium-promoted Pummerer rearrangement <00H(52)465>. 

Recently, new examples of asymmetric induction in the Pummerer reaction of chiral sulfoxides have been described. Oae and Numata (301) reported that the optically active a-cyanomethyl p-tolyl sulfoxide 275 undergoes a typical Pummerer rearrangement upon heating with excess of acetic anhydride at 120°C, to give the optically active a-acetoxy sulfide 276. The optical purity at the chiral a-carbon center in 276, determined by means of H- NMR spectroscopy using a chiral shift reagent, was 29.8%. 

Tetrahydrothiophene-fused Cgg can be generated by its reaction with the thio-carbonyl ylide precursor bis(trimethylsilylmefhyl) sulfoxide 262 [314, 315]. Thermal sila-Pummerer rearrangement leads in situ to the ylide 263, which is readily added to CgQ (Scheme 4.45). 

Further elaboration of the sulfur cycloadducts could be achieved by the use of a Pummerer rearrangement in the syntheses of 5-(hydroxymethyl)prolines. Oxidation of adduct 298 to sulfoxide 299, followed by treatment with TEA in DCM and quenching with either methanol or benzyl alcohol, delivered the Pummerer products 300 in 57% yield for R = Me and 38% for R = Bn as single diastereoisomers. Raney Ni desulfurization and Pearlman s catalyst mediated hydrogenolysis, for R = Bn furnished the final enantiopure proline derivative (Scheme 3.99). 

Formaldehyde anion synthon ( CHO). The anion of 1 (n-BuLi, THF, 0°) is readily alkylated, particularly by primary halides. The products can he converted into aldehydes under very mild conditions. Oxidation with m-chloroperbenzoic acid gives an unstable sulfoxide, which undergoes an sila-Pummerer rearrangement to an acetal. Addition of water liberates the free aldehyde. Epoxides can also be used as electrophiles.2 3 Example ... 

Dihydrofurans can be prepared efficiently by a Michael addition of (3-ketoesters to alkenyl sulfoxides followed by a Pummerer rearrangement (Scheme 36) (92JCS(Pi)945). 

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