Enol sulfonates reactions

Reactions of vinylogous amides with methanesulfonyl chloride also led to the formation of six-membered rings. Here the initial attack on oxygen produces a zwitterionic intermediate which can collapse to an enol sulfonic acid lactone (383,469). 

In the first step an S03 molecule is inserted into the ester binding and a mixed anhydride of the sulfuric acid (I) is formed. The anhydride is in a very fast equilibrium with its cyclic enol form (II), whose double bonding is attacked by a second molecule of sulfur trioxide in a fast electrophilic addition (III and IV). In the second slower step, the a-sulfonated anhydride is rearranged into the ester sulfonate and releases one molecule of S03, which in turn sulfonates a new molecule of the fatty acid ester. The real sulfonation agent of the acid ester is not the sulfur trioxide but the initially formed sulfonated anhydride. In their detailed analysis of the different steps and intermediates of the sulfonation reaction, Schmid et al. showed that the mechanism presented by Smith and Stirton [31] is the correct one. 

Substituted cyclopropyl rings conjugated with a triple bond system have recently received attention as C5 building blocks. The procedure described here is a modification of the decarboxylation-elimination reaction for the preparation of a.3 acetylenic acids from enol sulfonates of acyl malonates. Addition of aqueous alkali to the enol sulfonate of diethyl cyclopropyl carbonyl malonate gives cycl opropyl propiol ic acid, but the yield is 1 ow. 

The major advantages of this procedure over the enol sulfonate procedure lie in the availability of diethyl 2-chloro-2-cyclopropylethene-l,l-dicarboxylate from the corresponding acylmalonate and phosphorus oxychloride, and the fast, homogeneous, decarboxyl ative elimination reaction of the triethylamine salt of the half-ester in dry organic solvents. The conditions described here, with slight modifications (overnight treatment), have been used for a variety of g-chloro alkyl idene/aryl idene malonates as shown in Table I. 

The isolation of pyruvaldehyde enol ethers rather than glyceraldehyde structures during mild acidic hydrolysis may indicate that the latter structures are not stable in their free form but tend to lose water to produce pyruvaldehyde enol ether structures. Such structures may therefore be formed in lignin during technical processes carried out under mild acidic conditions such as the production of TMP. Pyruvaldehyde enol ether structures absorb UV-light above 300 nm and may thus contribute to the photo-yellowing process. Under conditions simulating the production of CTMP, on the other hand, it was previously shown that these types of structures are rapidly and completely eliminated presumably by sulfonation reactions (75). 

It is possible to enhance the rate of a Claisen rearrangement, especially in the enolate Claisen reaction. Denmark et al. showed that other carbanionic centers accelerate the Claisen rearrangement (as in Table 11.23).467 Generation of the anion of sulfone 631 (sec. 8.6.A) with various bases led to acceleration of the reaction relative to the thermal reaction of 631 and also influenced the syn/anti ratio (632/633). In general, a donor group at the allyl position accelerates the rate and the presence of an amino stabilizing group increases the rate even more. 

With secondary and tertiary allylic halides or sulfonates, reaction of an enolate anion may give mixtures of products formed by competing attack at the a- and y-positions (1.6). Addition of the enolate anion to a TT-allylpalladium complex provides an alternative method for allylation (see Section 1.2.4). 

A number of other asymmetric enolate protonation reactions have been described using chiral proton sources in the synthesis of a-aryl cyclohexanones. These include the stoichiometric use of chiral diols [68] and a-sulfinyl alcohols [69]. Other catalytic approaches involve the use of a BlNAP-AgF complex with MeOH as the achiral proton source, [70] a chiral sulfonamide/achiral sulfonic acid system [71,72] and a cationic BINAP-Au complex which also was extended to acyclic tertiary a-aryl ketones [73]. Enantioenriched 2-aryl-cyclohexanones have also been accessed by oxidative kinetic resolution of secondary alcohols, kinetic resolution of racemic 2-arylcyclohexanones via an asymmetric Bayer-Villiger oxidation [74] and by arylation with diaryhodonium salts and desymmetrisation with a chiral Li-base [75]. 

An improved procedure for the chlorosulfonation of substituted diaryl sulfones involves heating the appropriate 4,4 -dialkyl or dihalodiaryl sulfone with chlorosulfonic acid (2-4 equivalents) at 140-150 °C and subsequent treatment with thionyl chloride (6-10 equivalents). The action of chlorosulfonic acid on propiophenone (ethyl phenyl ketone 226) results in a novel cyclization reaction yielding 3-chloro-2-methylbenzothiophene-1,1-dioxide 227 (Scheme 2). The reagent similarly caused smooth cyclization of Mannich bases 228, the reaction again proceeding via the enolic sulfonic acid to yield the cyclic sulfone 229 (Equation 72). ... 

In further modifications of these norprogestins, reaction of norethindrone with acetic anhydride in the presence of p-toluene-sulfonic acid, followed by hydrolysis of the first-formed enol acetate, affords norethindrone acetate (41). This in turn affords, on reaction with excess cyclopentanol in the presence of phosphorus pentoxide, the 3-cyclopentyl enol ether (42) the progestational component of Riglovic . Reduction of norethindrone affords the 3,17-diol. The 33-hydroxy compound is the desired product since reactions at 3 do not show nearly the stereoselectivity of those at 17 by virtue of the relative lack of stereo-directing proximate substituents, the formation of the desired isomer is engendered by use of a bulky reducing agent, lithium aluminum-tri-t-butoxide. Acetylation of the 33,173-diol iffords ethynodiol diacetate, one of the most potent oral proves tins (44). ... 

There have been two general approaches to the direct asymmetric epoxidation of carbonyl-containing compounds (Scheme 1.2) ylide-mediated epoxidation for the construction of aryl and vinyl epoxides, and a-halo enolate epoxidation (Darzens reaction) for the construction of epoxy esters, acids, amides, and sulfones. 

Stable enolates such as diethyl malonate anions react with allyl sulfones (or acetates) in the presence of nickel complexes to give a mixture of the a- and /-product83. The regioselectivity is generally poor in the nickel-catalyzed reaction, but the molybdenum-catalyzed reaction is selective for alkylation at the more substituted allylic site, thereby creating a quaternary carbon center84. 

The reaction of the enamines of cyclohexanones with a,ft-unsaluraled sulfones gives mixtures resulting from attack of the enamine at the a- and /(-carbons of the oc,/ -unsaturated sulfone. The ratio of x- and /1-adducts is dependent upon the reaction solvent, the geometry and structure of the sulfone1 4. The diastereoselectivity of these reactions is also poor. The reaction of lithium enolates of cyclic ketones with ( )-[2-(methylsulfonyl)ethenyl]benzene, however, gives bicyclic alcohols, as single diastereomers, that result from initial -attack on the oc,/ -unsaturated sulfone5. 

Phenyl 2-(trimethylsilyl)ethynyl sulfone (118) can act as a vinyl cation synthon (equations 93 and 94)78 79. Thus, the reaction of enolates with 118 and subsequent desulfonylation of the adduct gives a-vinyl ketone, such as 119 and 120. 

Other leaving groups are sometimes used. Sulfates, sulfonates, and epoxides give the expected products. Acetals can behave as substrates, one OR group being replaced by ZCHZ in a reaction similar to 10-101. Ortho esters behave similarly, but the product loses R OH to give an enol ether. ... 

---