Carbanions dithiane

The carbanions derived from thioacetals, however, are typical -synthons. Most frequently used are 1,3-dithianes and C -silylated thioethers (see p. 33f. D. Seebach, 1969, 1973 B.-T. Grobel, 1974,1977). In these derivatives the proton is removed by butyllithium in THF. 

The pA of 1,3-dithiane is 36.5 (Cs" ion pair in THF). The value for 2-phenyl-1,3-dithiane is 30.5. There are several factors which can contribute to the anion-stabilizing effect of sulfur substituents. Bond dipole effects contribute but carmot be the dominant factor because oxygen substituents do not have a comparable stabilizing effect. Polarizability of sulfur can also stabilize the carbanion. Delocalization can be described as involving 3d orbitals on sulfur or hyperconjugation with the a orbital of the C—S bond. MO calculations favor the latter interpretation. An experimental study of the rates of deprotonation of phenylthionitromethane indicates that sulfur polarizability is a major factor. Whatever the structural basis is, there is no question that thio substituents enhance... 

The pivotal step in this sequence is an electrophilic substitution on indole. Although the use of l,3-dithian-2-yl carbanions is well documented, it has been shown only recently that 1,3-dithian-2-yl carbenium ions can be used in a Priedel-Crafts type reaction. This was accomplished initially using 2-methoxy-l,3-dithiane [1,3-Dithiane, 2-methoxy-] or 2-metlioxy-l,3-dithiolane [1,3-Dithiolane, 2-methoxy-] and titanium tetrachloride [Titanate(l —), tetrachloro-] as the Lewis acid catalyst.9 2-Substituted lysergic acid derivatives and 3-substituted indoles have been prepared under these conditions, but the method is limited in scope by the difficulties of preparing substituted 2-methoxy-1,3-dithianes. l,3-Dithian-2-yl carbenium ions have also been prepared by protonation of ketene dithioacetals with trifluoroacetic acid,10 but this reaction cannot be used to introduce 1,3-dithiane moieties into indole. 

Carbanions generated from 1,3-dithianes also react with epoxides to give the expected products. 

Other carbanionic groups, such as acetylide ions, and ions derived from a-methylpyridines have also been used as nucleophiles. A particularly useful nucleophile is the methylsulfinyl carbanion (CH3SOCHJ), the conjugate base of DMSO, since the P-keto sulfoxide produced can easily be reduced to a methyl ketone (p. 549). The methylsulfonyl carbanion (CH3SO2CH2 ), the conjugate base of dimethyl sulfone, behaves similarly, and the product can be similarly reduced. Certain carboxylic esters, acyl halides, and DMF acylate 1,3-dithianes (see 10-10. )2008 Qxj(jatjye hydrolysis with NBS or NCS, a-keto aldehydes or a-... 

Pyridyl-l,3-dithianes (50) result from the reaction of picolyl lithium reagents with 1,2-dithiolanes in the presence of HMPT. An initial ring opening is followed by reaction at the carbanion site with a second mole of dithiolane <96PS(112)101>. 

Sulfur compounds are useful as nucleophilic acyl equivalents. The most common reagents of this type are 1,3-dithianes, which on lithiation provide a nucleophilic acyl equivalent. In dithianes an umpolung is achieved on the basis of the carbanion-stabilizing ability of the sulfur substituents. The lithio derivative is a reactive nucleophile toward alkyl halides and carbonyl compounds. 11... 

The lone pair in the dithiane carbanion C can assume either an equatorial or axial position in the ring as shown below ... 

An example where the presence of a counterion makes a difference between the gas phase and solution phase pathways involves the intriguing carbanion produced on deprotonation of 1,3-dithiane at C-2. In solution, this species, almost invariably produced by reaction of the dithiane with butyllithium, is widely used as an acyl anion equivalent in synthetic chemistry. Its importance for the present work is that this is a configurationally stable lithiated species in solution the carbanion stays sp -hybridized, and the lithium prefers the equatorial position, even to the extent of driving a terr-butyl group on the same acidic C-2 carbanion to the axial position in the lithiocarbon species. The carbanion is thought to be stabilized primarily by orbital overlap with the C-S antibonding orbitals, as opposed to more conventional polar and 7t-resonance stabilization. ... 

Sulfonyl carbanions react readily with oxiranes, usually on the less hindered site With 2,3-disubstituted oxiranes, harsher conditions have to be used ° the addition of HMPA and/or BF3 Et20 can enhance the rate and the yield of the reaction, as in the case of lithiated dithianes. The reaction has been widely employed in organic... 

A 1,3-dithiane is a weak proton acid (pKa = 32) which can be deprotonated by strong bases such as n-butyllithium. The resulting carbanion is stabilized by the electron withdrawing effect of the two sulphur atoms. 

From the synthetic point of view, the most important a-sulfinyl carbanions appear to be those derived from dithioacetal S-oxides which are a synthon for acyl anions65. However, the yields of the alkylation reaction were found to be low. In spite of the fact that dithiane S-oxides have been intensively studied66 63, their synthetic applications are limited,... 

The difficult step of alkylation with BuLi could be improved by using PTC. In fact, when R is alkyl, the acidity of the hydrogen atom in the 1,3-dithiane 183 is too high and the carbanion is not formed. On the other hand, Lissel280 has been able to carry out the alkylation step under PT conditions when R is an electron-withdrawing group, e.g., COzEt. 

With Functionalized Carbanions. Other nucleophilic carbanions, such as lithio-dithiane or sodiomalonate or acetylene anion react easily with epoxides. 

With Dithiane. Dithiane is one of the most popular functionalized carbanion used for the ring opening of epoxides. This reaction has been studied by different groups [31,56], The anion of bis(phenylthio)methane has been successfully used for the opening of epoxides derived from furanose [56]. This method is an excellent way to prepare formyl derivatives that are suitable for chain extension by olefination. Alternatively formyl derivatives can be reduced to hydroxymethyl derivatives. A recent application of epoxide 33... 

As with epoxides, carbanions can add in a 1,4 fashion to enones or nitrosugars. Nitromethane anion has been used [64], Dithiane anion has been successfully used in the addition to nitroolefins [65] and to enones [66], Accordingly, C-5 branched-chain glucose derivatives 47 and 48 have been prepared from nitroolefin 46 (Scheme 20) [67,68], Sugar-derived enones have been also used as acceptors in free radical reactions to trap alkyl radicals as well as anomeric radicals (see Schemes 29 and 30). 

Furfuryl compounds with an anion stabilizing substituent such as a phenyl, a trimethylsilyl, or a 1,3-dithiane group yield the 2-furfuryl carbanion when treated with butyllithium. A facile ring cleavage then ensues (79JA2208,78JOC4235). 

The widespread use of compounds derived from the 1,3-dithiane carbanion or its homologues as acyl anion equivalents (for applications see Section 4.2.1.1) followed the pioneering works of Corey and Seebach on nucleophilic acylation (for reviews, see [43] and [44]). 

Diethyl-3,5-octadiene 174 Dithiane oxides alkylation of 84 carbanions of 84 Dithianes alkylation of 76,79 as acyl anion equivalents 75 carbanions of 76,79 cleavage of 14-18.76,79 desulfurization of 78 oxidation of 23... 

Dithioacetals (see also dithianes and dithiolanes) alkylation of 98 as acyl anion equivalents 75 carbanions of 87,97-102 cleavage of 14-18,98,102 desulfurization of 78 metal-catalysed coupling 127 reaction with Grignard reagents 127 reductive lithiation of 89 synthesis of 12-19,97-102 Dithioacids synthesis of 40... 

The use in organic synthesis of carbanions stabilized by one or more adjacent thioether groups is now a well-established technique [272-275]. A landmark in this development was the work of Corey and Seebach on 1,3-dithianes [276]. They pointed out the use of the anions of 1,3-dithianes as... 

It should be noted with (3), (4), (13) and (14) only hard lithium nucleophiles are tolerated, while for (5), (6), (7) and (15) the range of useful lithium nucleophiles, e.g. including lithio-l,3-dithianes and lithium enolates, is broader. In addition, none of these Michael acceptors react with organocuprates, Grig-nard reagents or stabilized carbanions. 

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