Wittig condensation protection

The other stereoselective synthesis/281 shown in Scheme 8, foresees conversion of Boc-L-Asp-OtBu 20 into the related (3-aldehyde 22 via the Weinreb amide 21 and its reduction with diisobutylaluminum hydride (DIBAL-H). Wittig condensation of 22 with the ylide derived from (3-carboxypropyl)triphenylphosphonium bromide using lithium hexamethyldisilaza-nide at —78 to 0°C, produces the unsaturated compound 23 which is catalytically hydrogenated to the protected L-a-aminosuberic acid derivative 24. Conversion of the co-carboxy group into the 9-fluorenylmethyl ester, followed by TFA treatment and reprotection of the M -amino group affords Boc-L-Asu(OFm)-OH (25). 

The basic nature of methylenetriphenylphosphorane caused D-homoannulation of 17a-acetyloestr-4-en-17/3-ol (294) before effecting a Wittig condensation the mixed 17-methylene-D-homoandrostanes (295) were formed. When the 17/3-OH group was protected by acetylation, an intramolecular Claisen condensation occurred in polar solvents under Wittig conditions, giving the spiro-lactone (296) and a... 

Seebach completed the first synthesis of optically active 9 as depicted in Scheme 4.2. ° Protected alcohol 10, available from an optically active p-hydroxy butyric ester, was alkylated with 2-lithio-1,3-dithiane. Deprotonation of this material followed by formylation with DMF then afforded 11. Chain extension to the unsaturated ester was accomplished via a Wittig condensation and deprotection to produce the monomeric unit 12 in 57% overall yield from 10. Double lactonization under Mitsunobu conditions (DEAD-PhjP) afforded a 60%... 

The syntheses of carbocyclic analogs of phosphononucleosides (29) and (30a-c) have been reported. Phosphonic acid (29) was obtained by introduction of the benzoylated thymine on the 2(4-hydroxycyclopent-2-enyl)ethyl phosphonic acid diisopropyl ester under Mitsunobu conditions while (30a-c) were prepared by building-up the base around a phosphono-cyclopentylamine moi-ety. The vinylphosphonate derivatives of uridine, cytidine and cytosine ara-binoside (31a-c) have been prepared by Wittig condensation of [(diethoxyphos-phinyl)methylidene]triphenylphosphorane with the appropriately protected 5-aldehydic nucleoside derivatives. Dihydroxylation of the novel vinyl phosphon-ates offered the dihydroxylated phosphonate derivatives (32a-c). Each of these novel compounds was evaluated as substrates for the enzyme nucleotide monophosphate kinase, and their toxicity to K562 cells. All analogues were found to be poorly phosphorylated by the kinase and exhibited poor in vivo toxicity. ... 

Recently, improved procedures have been developed [17] for the synthesis of the phosphonium bromide 30. Addition of the hydroxyaldehyde 29 to NBS/dimethylsulphide in CH2CI2 at -20°C provided (all- )-8-bromo-2,7-dimethylocta-2,4,6-trienal (31) in 86% yield. Reaction of 31 with triphenylphosphine in ethyl acetate furnished the phosphonium bromide 30 in 88% yield. In most applications carried out so far, the phosphonium salts 30 and 32 (prepared from 33 and 31) have been transformed to the corresponding dimethylacetals 27 and 28, prior to their use in Wittig condensations. However, protection of the aldehyde function of 30 is not always necessary [17]. Direct Wittig reaction between 30 and 34 afforded the Ci6-ketoaldehyde 35 in 43% yield. 

Good Z-selectivities were observed for the reaction of aldehydes with carboxy ylides prepared from the corresponding phosphonium salt and LHMDS. This strategy has been extensively used in the total synthesis of prostaglandins, monohydroxy-eicosatetraenoic acids (HETE), and leukotrienes. Eor instance, the Wittig condensation between aldehyde 5 and car-boxy phosphonium salt 6 in the presence of LHMDS provided 49% yield of the TBDPS-protected 10(5)-HETE methyl ester 7 (eq42). ... 

The selective intermolecular addition of two different ketones or aldehydes can sometimes be achieved without protection of the enol, because different carbonyl compounds behave differently. For example, attempts to condense acetaldehyde with benzophenone fail. Only self-condensation of acetaldehyde is observed, because the carbonyl group of benzophenone is not sufficiently electrophilic. With acetone instead of benzophenone only fi-hydroxyketones are formed in good yield, if the aldehyde is slowly added to the basic ketone solution. Aldols are not produced. This result can be generalized in the following way aldehydes have more reactive carbonyl groups than ketones, but enolates from ketones have a more nucleophilic carbon atom than enolates from aldehydes (G. Wittig, 1968). 

Finally, the necessity arose for the synthesis of pentulose 21, labeled with, 3C on the central carbons, C-2 and C-3, for an independent biosynthetic study, which is reported in Section III.5.27 The doubly labeled ester 34 (Scheme 14) is readily available by a Wittig- Homer condensation of benzyloxyacetaldehyde with commercially available triethylphosphono-(l,2-l3C2)acetate. Chirality was introduced by the reduction of ester 34 to the allylic alcohol, which produced the chiral epoxide 35 by the Sharpless epoxidation procedure. This was converted into the tetrose 36, and thence, into the protected pentulose 37 by the usual sequence of Grignard reaction and oxidation. 

A second convergent synthesis of haliclamine A (64) was achieved in a stepwise sequence from cyclopropyl(thiophen-2-yl)methanone (76) (Scheme 7) [37]. The protected thiophene 77 was condensed with formyl-piperidine to give 78, suitable for a Wittig olefination with 79. After desulfurization of the product 80, the deprotected alcohol 82 was subjected to homoallylic rearrangement using MesSiBr in the presence of ZnBr2. The re-... 

Dietary /1-carotene, a nutritionally important source of vitamin A, exhibits a protective effect against cancer risk31,32. The deuteriated compound, 10,10, 19,19,19,19, 19, 19 -2H8-/S-carotene, 32, has been obtained33 by double condensation of the C-15 Wittig salt 33 with the symmetrical C10 dial 2,7-dimethyl-2,4,6-octatrienedial, 34 (equation 13) for the study of /J-carotene metabolism in humans. 

Several condensed systems, especially those combined with pyridine rings, show biological activity, e.g., in the field of crop protection and as anti-virus and anti-cancer compounds. Aza-Wittig reactions in particular should make several novel heterocyclic rings available. The aza-Wittig reaction of iminophosphoranes has to be considered as a major principle in modern synthetic chemistry, as was wisely foreseen by Staudinger and Meyer as early as 1919. 

A pentopyranoside-fused butenolide is the key intermediate for the synthesis of the natural micotoxin patulin [226, 227]. Its synthesis involves Wittig olefination of a 3,4-di-O-protected arabinopyran-2-uloside, followed by protecting group removal and dehydration (Scheme 47). In other research, the glucopyranosid-2-uloside 190 was converted into the butenolide derivative 191 by aldol condensation with diethyl malonate and transesterification [228]. The latter was shown to be prone to autoxi-dation, leading to 192. Subsequent Michael addition with hydroxide ion, followed by decarboxylation, furnishes C-branched-chain sugar 193. 

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