Alkylative deoxygenation

Another group of compounds converting oxiranes to olefins consists of lithium-alkyls deoxygenation here is accompanied by the introduction of the alkyl group (Eq. 107). ... 

There are a number of alternative methods for the synthesis of 1,2-diols and their derivatives that do not proceed via the coupling of two carbonyl groups. Ketyl radicals can be generated by the alkylative deoxygenation of carboxylic acids, and in the presence of TiCls coupled to give 1,2-diols (equation 111). However, yields are limited (22-33%) and complex product mixtures are often formed. 

Alkylative deoxygenation of epoxidesf This transformation to alkenes is actu ally quite common and not limited to s-BuLi. 

As with other alkyllithiums, 1 can react with epoxides in an alkylative deoxygenation reaction to provide an allyl alcohol. At least 2 equiv of the alkyllithium are required as ring opening occurs from the a-lithioepoxide, whose formation requires the first equivalent of the alkyllithium to act as a base. With functionalized epoxides such as 4, subsequent reactions can also occur as illustrated in eq 9. An analogous reaction is observed with 3,4-epoxytetrahydrofurans to give 1,2-diols. ... 

Photolysis of pyridazine IV-oxide and alkylated pyridazine IV-oxides results in deoxygenation. When this is carried out in the presence of aromatic or methylated aromatic solvents or cyclohexane, the corresponding phenols, hydroxymethyl derivatives or cyclohexanol are formed in addition to pyridazines. In the presence of cyclohexene, cyclohexene oxide and cyclohexanone are generated. 

N-alkylation, 4, 236 Pyrrole, 2-formyl-3,4-diiodo-synthesis, 4, 216 Pyrrole, 2-formyl-1-methyl-conformation, 4, 193 Pyrrole, 2-formyl-5-nitro-conformation, 4, 193 Pyrrole, furyl-rotamers, 4, 546 Pyrrole, 2-(2-furyl)-conformation, 4, 32 Pyrrole, 2-halo-reactions, 4, 78 Pyrrole, 3-halo-reactions, 4, 78 Pyrrole, 2-halomethyl-nucleophilic substitution, 4, 274 reactions, 4, 275 Pyrrole, hydroxy-synthesis, 4, 97 Pyrrole, 1-hydroxy-cycloaddition reactions, 4, 303 deoxygenation, 4, 304 synthesis, 4, 126, 363 tautomerism, 4, 35, 197 Pyrrole, 2-hydroxy-reactions, 4, 76 tautomerism, 4, 36, 198... 

Rajanikanth and Ravindranath44 have recently published a deoxygenation reaction for sulphoxides that uses metallic lithium in refluxing dimethoxyethane. Dialkyl and alkyl phenyl sulphoxides were reduced cleanly in yields around 70%, even if sterically hindered, but benzyl sulphoxides gave mixtures of products. For example, benzyl phenyl sulphoxide gave frans-stilbene (33%), benzyl phenyl sulphide (20%) and diphenyl disulphide (47%). These products can be rationalized by reaction pathways such as in equation (17) ... 

The low reactivity of alkyl and/or phenyl substituted organosilanes in reduction processes can be ameliorated in the presence of a catalytic amount of alkanethiols. The reaction mechanism is reported in Scheme 5 and shows that alkyl radicals abstract hydrogen from thiols and the resulting thiyl radical abstracts hydrogen from the silane. This procedure, which was coined polarity-reversal catalysis, has been applied to dehalogenation, deoxygenation, and desulfurization reactions.For example, 1-bromoadamantane is quantitatively reduced with 2 equiv of triethylsilane in the presence of a catalytic amount of ferf-dodecanethiol. 

As mentioned above (303) (Scheme 3.90, Eq. 1), bis-trifluoromethyl thioketene has the deoxygenating ability toward alkyl nitronates, which is also based on cycloaddition to the C=S bond. 

Fuostifoline (47), a furo[3,2-a]carbazole, was isolated from Murraya euchrestifolia. Timdri s total synthesis of 47 commenced with alkylation of bromocresol 43 with bromoacetaldehyde diethyl acetal and P4Oio-promoted cyclization to furnish 5-bromo-7-methylbenzofuran (44) [47]. The Suzuki coupling of boronic acid 45, derived from 44, with o-bromonitrobenzene yielded biaryl 46. Nitrene generation, achieved via deoxygenation of nitro compound 46 using triethyl phosphite, was followed by cyclization to fuostifoline (47). 

Several examples have been reported of rearrangements of arsine oxides (51) to esters, initiated by alkyl halides.42 43 Reactions of tertiary arsine oxides with thiols (52) cause deoxygenation.44... 

In Yamada s retrosynthetic analysis (Scheme 11), elisabethin C (26) is traced back to lactone 64 which would be converted into 26 by deoxygenation and chain elongations. Key intermediate 64 could be obtained by a stereoselective Dieckmann cyclization. The required ester lactone precursor 65 would be accessible from 66 by a series of oxidation reactions. Further disconnection would lead to commercially available (+)-carvone (67). Stereoselective successive alkylation of 67 and reduction of the enone should deliver 66 [30]. 

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