Oxidations Swern oxidation

Related reactions Dess-Martin oxidation, Jones oxidation, Ley oxidation, Oppenauer oxidation, PTitzner-Moffatt oxidation, Swern oxidation ... 

This reaction is related to the Dess-Martin Oxidation, Swern Oxidation, and Pfitzner-Moffatt Oxidation. 

While the five-membered cyclic alkoxysilane moiety has been found to tolerate a wide range of chemical transformations (OSO4 oxidation, Swern oxidation, Horner-Emmons alkenation, protection conditions such as Tr/py+ BF4 and Mel/NaH, and catalytic hydrogenation), the carbon-silicon bond can be cleaved efficiently by tetra- -butylammonium fluoride in DMF (eq 7). ... 

The 6-endo activated epoxy alcohol cyclization process was also expected to play a central role in the annulation of pyran ring G of the natural product (see Scheme 22). Silylation of the free secondary hydroxyl group in compound 131 furnishes, after hydrobora-tion/oxidation of the double bond, compound 132. Swern oxidation of alcohol 132 produces an aldehyde which reacts efficiently with (ethoxycarbonylethylidene)triphenylphosphorane in the presence of a catalytic amount of benzoic acid in benzene at 50 °C, furnishing... 

Swern oxidation of N-unsubstituted aziridine-2-carboxylate 210 (Scheme 3.77) resulted in the formation of 2H-azirine 211 in >90% yield [95] Similar oxidation of 212 (Scheme 3.78) afforded azirine 213 in 60% yield [66]. 

Swern oxidation of N-unsubstituted aziridine-2-phosphonates resulted in the formation of both 2H-azirine-2-phosphonates and 2H-azirine-3-phosphonates [81, 83]. Treatment of ds-aziridine-2-phosphonate 226 (Scheme 3.84) with DM SO/ (COCl)2/Et3N afforded azirine-phosphonates 227 and 228, with the former predominating [81]. Under similar conditions, however, trans-aziridine-2-phospho-... 

Silyl enol ethers, 23, 77, 99-117,128 Silyl enolates, 77 Silyl peroxides, 57 Silyl triflate, 94 Silyl vinyl lithium, 11 (E)-l -Silylalk-1 -enes, 8 Silylalumimum, 8 Silylation, 94 reductive, 26 a-C-Silylation, 113 O-Silylation.99,100 / -SilyIketone, 54 non-cydic, 55 Silylmagnesium, 8 Silyloxydienes, 112 Sodium hexamethyldisilazide, 89 Sodium thiosulphate pentahydrate, 59 Stannylation, see Hydrostannylation Stannylethene, 11 (Z)-Stilbene, 70 (E)-Stilbene oxide, 70 /3-Styryltrimethylsilane, 141 Swern oxidation. 84,88... 

A highly remarkable and entirely unexpected conversion of aziridine esters 21 into azirine esters 22 was accomplished by subjecting the aziridine to a Swern oxidation (Scheme 11). 

The regiochemistry of this elimination reaction resembles that observed by Davis et al. (see Scheme 9) [23]. The special nature of the bonds in three-mem-bered rings is probably responsible for this exclusive regiochemistry. It is of interest to note that 3,3-dimethylaziridine-2-carboxylic ester indeed leads to the corresponding 3H-azirine ester upon Swern oxidation here there is, of course, no choice. 

The Swern oxidation was also employed by Davis and McCoull [251 for the synthesis of 2iT-azirinephosphonates 27 and 28 from the corresponding aziridines 26 (Scheme 14). Interestingly, in this case a mixture of the regioiso-meric azirines is obtained, whereby the proton abstraction adjacent to the phos-... 

A range of 6-substituted 2-amino-e-caprolactams 66 has been synthesized by a sequence published by Robl et al. for investigating the generation of peptidomimetics. After Swern oxidation of the dipeptide 63, the corresponding... 

Whereas the original Moffat-Pfitzner oxidation employs dicyclohexylcarbodiimide to convert DMSO into the reactive intermediate DMSO species 1297, which oxidizes primary or secondary alcohols via 1298 and 1299 to the carbonyl compounds and dicyclohexylurea [78-80], subsequent versions of the Moffat-Pfitzner oxidation used other reagents such as S03/pyridine [80a, 83] or oxalyl chloride [81-83] to avoid the formation of dicyclohexylurea, which is often difficult to remove. The so-called Swern oxidation, a version of the Moffat-Pfitzner oxidation employing DMSO/oxalyl chloride at -60°C in CH2CI2 and generating Me2SCl2 1277 with formation of CO/CO2, has become a standard reaction in preparative organic chemistry (Scheme 8.31). 

Preparatively useful procedures based on acetic anhydride,25 trifluoroacetic anhydride,26 and oxalyl chloride27 have been developed. The last method, known as the Swern oxidation, is currently the most popular. 

A number of modifications were made to meet scale-up requirements. In the preparation of the common intermediate, LiBH4 was used in place of LiAlH4 in Step A-2 and a TEMPO-NaOCl oxidation was used in place of Swern oxidation in Step A-3. Some reactions presented difficulty in the scale-up. For example, the boron enolate aldolization in Step B-l gave about 50% yield on the 20- to 25-kg scale as opposed to greater than 75% on a 50-g scale. The amide formation in Step B-3 was modified to eliminate the use of trimethylaluminum, and the common intermediate 17 could be prepared on a 30-kg scale using this modified sequence. The synthesis of the C(l)-C(6) segment V was done by Steps C-l to C-5 in 66% yield on the scale of several kg. 

The drug candidate 1 was prepared from chiral cyclopentanol 10 as shown in Scheme 7.3. Reaction of 10 with racemic imidate 17, prepared from the corresponding racemic benzylic alcohol, in the presence of catalytic TfOH furnished a 1 1 mixture of diastereomers 18 and 19 which were only separated from one another by careful and tedious chromatography. Reduction of ester 18 with LiBH4 and subsequent Swern oxidation gave aldehyde 20 in 68% yield. Reductive animation of 20 with (R)-ethyl nipecotate L-tartrate salt 21 and NaBH(OAc)3 and subsequent saponification of the ester moiety yielded drug candidate 1. 

The second synthesis of crystalline 43 was reported by Mori as summarized in Scheme 62 [93]. The building block (4.R,5S)-A was prepared by an enzymatic process, while another building block C was synthesized via Sharpless asymmetric epoxidation. Coupling of A with C gave D, which was cyclized under Op-polzer s conditions to give crystalline E. When E was oxidized with Dess-Martin periodinane or tetra(n-propyl)ammonium perruthenate or Jones chromic acid, crystalline 43 was obtained. Swern oxidation or oxidation with 2,2,6,6-tetramethylpiperidin-1 -oxyl of E afforded only oily materials. Accordingly, oxidation of E to 43 must be executed extremely carefully. A synthesis of oily 43 was reported by Gil [94]. 

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