Reaction Swem oxidation

The aldehyde function at C-85 in 25 is unmasked by oxidative hydrolysis of the thioacetal group (I2, NaHCOs) (98 % yield), and the resulting aldehyde 26 is coupled to Z-iodoolefin 10 by a NiCh/CrCH-mediated process to afford a ca. 3 2 mixture of diaste-reoisomeric allylic alcohols 27, epimeric at C-85 (90 % yield). The low stereoselectivity of this coupling reaction is, of course, inconsequential, since the next operation involves oxidation [pyridinium dichromate (PDC)] to the corresponding enone and. olefination with methylene triphenylphosphorane to furnish the desired diene system (70-75% overall yield from dithioacetal 9). Deprotection of the C-77 primary hydroxyl group by mild acid hydrolysis (PPTS, MeOH-ClHhCh), followed by Swem oxidation, then leads to the C77-C115 aldehyde 28 in excellent overall yield. 

Stilbenes, photocyclization of, 30, 1 StiUe reaction, 50, 1 Stobbe condensation, 6, 1 Substitution reactions using organocopper reagents, 22, 2 41, 2 Sugars, synthesis by glycosylation with sulfoxides and sulfinates, 64, 2 Sulfide reduction of nitroarenes, 20, 4 Sulfonation of aromatic hydrocarbons and aryl halides, 3, 4 Swem oxidation, 39, 3 53, 1... 

Sulfonylurea formation, isocyanate, 65, 66 Sulfuration, see also Lawesson benzoxazine, 471 lithio thiophene, 586 phenothiazine, 532, 533 Suzuki reaction, see Coupling Swem oxidation, 18... 

The reaction here is a variant of the Swem oxidation (see Chapters 5 and 14)... 

Swem oxidation of /1-amino alcohols has been shown to be a useful alternative to metal-based oxidants, which may be chelated by the substrate.115 A - VIethylpyrrolidine, A-ethylpiperidine. or triethylamine proved optimal as bases. The reaction, although successful for /1-secondary amino alcohols, gave products that readily polymerized. 

In 2002, the asymmetric synthesis of 3-substituted 3-hydroxy-p-lactams has been reported to be realized by metal-mediated l,3-butadien-2-ylation reactions between 1,4-dibromo-2-butyne and optically pure azetidine-2,3-diones [64]. This latter starting material was prepared via Staudinger reaction followed by sequential transesterification and Swem oxidation (Scheme 15), [65]. 

The Swem Oxidation of alcohols avoids the use of toxic metals such as chromium, and can be carried out under very mild conditions. This reaction allows the preparation of aldehydes and ketones from primary and secondary alcohols, resp. Aldehydes do not react further to give carboxylic acids. A drawback is the production of the malodorous side product dimethyl sulphide. 

Reduction of the olefinic bond in 12 and Swem oxidation of the free carbinol function provided ketone 53, onto which installation of the methyl group was performed by reaction with methylmagnesium chloride in THF. After protection of the resulting tertiary alcohol as a TBS-ether, fully protected triol 54 was obtained with a useful 80% diastereomeric excess. Acetonide deblocking and oxidative fission of the diol formed led to aldehyde 55, ready for the planned cyclization step. Exposure of aldehyde 55 to TBSOTTDIPEA reagent system smoothly resulted in formation of the desired bicyclic adducts 56 and 57 which were isolated in a 82% combined yield (60 40 ratio). 

In the pioneering work by Wilcox and Gaudino, a straightforward route to the carbocyclic analogue of D-fructofuranose, 64, and its 6-phosphate derivative was delineated [14a,b]. As shown in Scheme 9, the first move consisted of Wittig olefination of benzyl-protected arabinose 60 with carboxy-tert-butylmethylene triphenyl phosphorane to deliver unsaturated ester 61, which was then cleverly elaborated into dibromide 62 via a reaction cascade encompassing Swem oxidation of the secondary OH, ester hydrolysis, diastereoselective addition of dibromomethyl lithium, and carboxylic acid methylation. 

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