With Swern oxidant

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-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-... 

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). 

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]. 

A magnesium enolate of 99 is susceptible to aldol condensation with 4-pentenal, and the crude product can be directly protected to give its ethyl carbonate 100. a-Hydroxylation of the carbonyl group yields the hydroxyl carbonate 101. Reduction of the carbonyl group generates a triol, and this compound can be simultaneously converted to carbonate 102. Swern oxidation of 102 gives ketone 103, which can be rearranged25 to produce lactone product 104 (Scheme 7-32). 

Treatment of the alcohol 211 with f-butyklimethylsilyl triflate and 2,6-lutidine affords disiloxyester 212 with high yield. Reduction of the ester function of 212 with DIBAL followed by Swern oxidation gives the corresponding aldehyde 213, and subsequent alkylation with MeMgBr and Swern oxidation produce methyl ketone 214 (Scheme 7-70). 

Acyl nitroso compounds (3, Scheme 7.2) contain a nitroso group (-N=0) directly attached to a carbonyl carbon. Oxidation of an N-acyl hydroxylamine derivative provides the most direct method for the preparation of acyl C-nitroso compounds [10]. Treatment of hydroxamic acids, N-hydroxy carbamates or N-hydroxyureas with sodium periodate or tetra-alkyl ammonium periodate salts results in the formation of the corresponding acyl nitroso species (Scheme 7.2) [11-14]. Other oxidants including the Dess-Martin periodinane and both ruthenium (II) and iridium (I) based species efficiently convert N-acyl hydroxylamines to the corresponding acyl nitroso compounds [15-18]. The Swern oxidation also provides a useful alternative procedure for the oxidative preparation of acyl nitroso species [19]. Horseradish peroxidase (HRP) catalyzed oxidation of N-hydroxyurea with hydrogen peroxide forms an acyl nitroso species, which can be trapped with 1, 3-cyclohexanone, giving evidence of the formation of these species with enzymatic oxidants [20]. 

The potentiality of the present methodology is demonstrated by the synthesis of y-undecalactone, as shown in Scheme 18 [37,47], The treatment of the THP-protected cu-hydroxyalkyl iodide with the anion of methoxybis(trimethylsilyl) methane gave the corresponding alkylation product. Acidic deprotection of the hydroxyl group followed by Swern oxidation produced the aldehyde. The aldehyde was allowed to react with heptylmagnesium bromide, and the resulting alcohol was protected as tm-butyldimethylsilyl ether. The electrochemical oxidation in methanol followed by the treatment with fluoride ion afforded the y-undeealactone. 

The bromoallene (-)-kumausallene (62) was isolated in 1983 from the red alga Laurencia nipponica Yamada [64a], The synthesis of the racemic natural product by Overman and co-workers once again employed the SN2 -substitution of a propargyl mesylate with lithium dibromocuprate (Scheme 18.22) [79]. Thus, starting from the unsymmetrically substituted 2,6-dioxabicyclo[3.3.0]octane derivative 69, the first side chain was introduced by Swern oxidation and subsequent Sakurai reaction with the allylsilane 70. The resulting alcohol 71 was protected and the second side chain was attached via diastereoselective addition of a titanium acetylide. The synthesis was concluded by the introduction of two bromine atoms anti-selective S -substitution of the bulky propargyl mesylate 72 was followed by Appel bromination (tetrabromo-methane-triphenylphosphine) of the alcohol derived from deprotection of the bromoallene 73. 

The conversion of 5 to 6 is a Swern oxidation. The O of DMSO is nucleophilic, and it reacts with oxalyl chloride. Cl- then comes back and displaces O from S to give a S electrophile. The OH of 5 is then deprotonated, whereupon it attacks S, displacing CL. Then deprotonation of a Me group and a retro-hetero-ene reaction occur to give the ketone. 

The derivatives 24 were synthesised by the acylation of trans-2-aminocy-clopentanol (n=l) or frans-2-aminocyclohexanol (n=2) with 3,3-ethylene-dioxydodecanoic acid in the presence of EDC, DMAP and DIPEA followed by acidolysis with THF in DCM. The cycloalkanone analogues 25 were obtained by Swern oxidation of the corresponding cycloalkanols 24 (Scheme 10). 

Oxidation of alcohol to the corresponding aldehyde or ketone using NCS/DMS, followed by treatment with a base. Cf. Swern oxidation. 

The present method offers a more efficient and convenient two-step route to the parent a,B-unsaturated acylsilane derivative. The first step in the procedure involves the conversion of allyl alcohol to allyl trimethylsilyl ether, followed by metalation (in the same flask) with tert-butyllithiura at -75°C. Protonation of the resulting mixture of interconverting lithium derivatives (2 and 3) with aqueous ammonium chloride solution furnishes (1-hydroxy-2-propenyl)trimethylsilane (4), which is smoothly transformed to (1-oxo-2-propenyl)trimethylsilane by Swern oxidation. The acylsilane is obtained in 53-68% overall yield from allyl alcohol in this fashion. 

The synthesis of valsartan (2) by Novartis/Ciba-Geigy chemists is highlighted in Scheme 9.5. Biphenylbenzyl bromide 18 is converted to biphenyl acetate 19 in the presence of sodium acetate in acetic acid. Hydrolysis of 19 followed by Swern oxidation delivered the biphenyl aldehyde 20, which underwent reductive amination with (L)-valine methyl ester (21) to give biphenyl amino acid 22. Acylation of 22 with penta-noyl chloride (23) afforded biphenyl nitrile 24, which is reacted with tributyltin azide to form the tetrazole followed by ester hydrolysis and acidihcation to provide valsartan (2). [See Biihlmayer et al. (1994, 1995).]... 

Tezacitabine is synthesized from the cytidine protected at 4 -OH, 5 -OH and 4-NH2. Swern oxidation provides a ketone, which is converted to a gem-fluoro-sulfonyl olefin with the anion of sulfonylfluorophosphonate. Reduction of the sulfonyl group is achieved with BusSnH (Fig. 33) [92]. 

Amino-1-fluoro-propylidence)-cyclopentanecarbonitriles (55), i//[CF=C] iso-stere of 2-cyanopyrrolidides, were prepared from 56, an intermediate in the synthesis of 50 (Scheme 19) [65]. A better route was conversion of the primary alcohol (58), another intermediate in the synthesis of 50, to the aldehyde (59) through Swern oxidation followed by treatment with hydroxylamine-O-sulfonicacid (Scheme 10). Both pairs of diastereomer u-55 and 1-55 exhibited inhibitory activity against DPP IV. u-55 and 1-55 also were very stable in buffer (pH 7.6) as assessed by UV-vis spectroscopy over the range of 190-1,100 nm at 30 and 50°C (Scheme 20). 

Thus, the N,N-dibenzyl-protected aminonitrile 55 was prepared via Swern oxidation of N,N-dibenzylaminoethanol 54 followed by treatment with the enantio-pure amine auxiliary (S,S)-53 and HCN, resulting in the formation of a 3 2 epimeric mixture of the aminonitriles 55 in 55% yield, from which the single dia-stereomers could be isolated by chromatography. After lithiation with LDA, addition to the requisite (E)-a, P-unsaturated esters and hydrolysis of the aminonitrile moiety with silver nitrate, the desired a-amino keto esters R)-S6 were obtained with yields of 65-81% and enantiomeric excesses ee of 78-98%, which could be improved to ee > 98% by a simple recrystallization. Since the amino ketone functionality can be cleaved oxidatively, the 5-amino-4-oxo-esters 56 could be transformed to the corresponding succinic half-esters 57 with hydrogen peroxide in methanol in good to excellent yields (68-90%) (Scheme 1.1.15). 

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