Ketenes thiols

Nucleophilic Addition. Reagents with labile hydrogen atoms, such as alcohols, thiols, phenols, carboxyHc acids and amines, add to ketenes giving the corresponding carboxyHc acid derivatives (1) as shown ia Figure 1 (38). Not many are of practical importance, as there are better ways to such... 

General Reaction Chemistry of Sulfonic Acids. Sulfonic acids may be used to produce sulfonic acid esters, which are derived from epoxides, olefins, alkynes, aHenes, and ketenes, as shown in Figure 1 (10). Sulfonic acids may be converted to sulfonamides via reaction with an amine in the presence of phosphoms oxychloride [10025-87-3] POCl (H)- Because sulfonic acids are generally not converted directiy to sulfonamides, the reaction most likely involves a sulfonyl chloride intermediate. Phosphoms pentachlotide [10026-13-8] and phosphoms pentabromide [7789-69-7] can be used to convert sulfonic acids to the corresponding sulfonyl haUdes (12,13). The conversion may also be accompHshed by continuous electrolysis of thiols or disulfides in the presence of aqueous HCl [7647-01-0] (14) or by direct sulfonation with chlorosulfuric acid. Sulfonyl fluorides are typically prepared by direct sulfonation with fluorosulfutic acid [7789-21-17, or by reaction of the sulfonic acid or sulfonate with fluorosulfutic acid. Halogenation of sulfonic acids, which avoids production of a sulfonyl haUde, can be achieved under oxidative halogenation conditions (15). 

As with alcohols, ketenes add thiols to give thiol esters (R2C=C=0- - RSH-R2CHCOSR). 

Addition of thiol acids to alkenes addition of thiols to ketenes... 

The enolates of other carbonyl compounds can be used in mixed aldol reactions. Extensive use has been made of the enolates of esters, thiol esters, amides, and imides, including several that serve as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, titanium, and tin derivatives have all been widely used. The silyl ethers of ester enolates, which are called silyl ketene acetals, show reactivity that is analogous to silyl enol ethers and are covalent equivalents of ester enolates. The silyl thioketene acetal derivatives of thiol esters are also useful. The reactions of these enolate equivalents are discussed in Section 2.1.4. 

Unsaturated acyl derivatives of oxazolidinones can be used as acceptors, and these reactions are enantioselective in the presence of chiral to-oxazoline catalysts.321 Silyl ketene acetals of thiol esters are good reactants and the stereochemistry depends on the ketene acetal configuration. The Z-isomer gives higher diastereoselectivity than the Zf-isomer. 

Alkylidenemalonate esters are also good acceptors in reactions with silyl ketene acetals of thiol esters under very similar conditions.322... 

The condensation of activated thiols onto adjacent nitriles is a common method for the preparation of amine-substituted thiophenes. A three component condensation was utilized to prepare a-aminothiophene 11 <00TL1597>. An alternate method for preparing amino-substituted thiophenes involved the treatment of ketene S,JV-acetal 12 with an activated carbonyl compound 13 which gave thiophene 14 <00JOC3690>. This type of reaction has also been utilized to prepare building blocks for the synthesis of fused thiophenes <00JHC363>. 

The thermolysis of isopropylidene 2-azacycloalkylidenemalonates (468, R2 = R4 = H, n = 0-2) gave unstable ketenes (1641), which were reacted with alcohols, thiols, and protic amines to afford Z-enamino ester derivatives (1642) in 63-98% yields (81TL963). 

Thiol esters RC(0)SR have been prepared by nucleophilic cleavage of polystyrene-bound /V-acylsulfonamides with mixtures of a thiol and sodium thiophenolate [377] or LiBr [378], or by treatment of Wang or PAM resin bound carboxylic esters with ethanethiol in the presence of a Lewis acid (AlMe2Cl or AlMe3, DCM, 20 °C, 3 h [379,380]). The latter method can also give rise to the formation of orthoesters RC(SEt)3 and ketene thioacetals, which can, however, be hydrolyzed to the desired thiol esters by treatment with TFA [379]. 

Alcohols can also be prepared from support-bound carbon nucleophiles and carbonyl compounds (Table 7.4). Few examples have been reported of the a-alkylation of resin-bound esters with aldehydes or ketones. This reaction is complicated by the thermal instability of some ester enolates, which can undergo elimination of alkoxide to yield ketenes. Traces of water or alcohols can, furthermore, lead to saponification or transesterification and release of the substrate into solution. Less prone to base-induced cleavage are support-bound imides (Entry 2, Table 7.4 see also Entry 3, Table 13.8 [42]). Alternatively, support-bound thiol esters can be converted into stable silyl ketene acetals, which react with aldehydes under Lewis-acid catalysis (Entries 3 and 4, Table 7.4). 

Support-bound C-nucleophiles have also been successfully added to imines. Poly-styrene-bound thiol esters can be converted into ketene acetals by O-silylation, and then alkylated with imines in the presence of Lewis acids. Further examples include Mannich reactions of support-bound alkynes and indoles (Table 10.10). Some Man-nich-type products (e.g. 3-(aminomethyl)indoles, 2-(aminomethyl)phenols, (3-amino ketones) are unstable and can decompose upon treatment with acids. 3-(Amino-... 

Thiol esters RC(0)SR are stronger acylating agents than simple alkyl esters, and have been prepared on solid phase mainly as synthetic intermediates. The preparation of thiol esters as intermediates for the synthesis of support-bound thiols is discussed in Section 8.1. Further examples of the preparation of thiol esters on insoluble supports include the aldol addition of ketene thioacetals to polystyrene-bound aldehydes... 

Ketenes easily add water,alcohols, amines and thiols to give derivatives of phosphorylated carboxylic acids ( -7). Phosphorylated ketenes undergo reactions of cyclo"aadition to vinyl ethers,diazomethane,styrene, cyclopentadiene, etc. From phosphorylated ketenes other phosphorylated cumulenes can be obtained,for example allenes,isocyanates,ketenimines... 

Carbonyl transposition.1 Tetrafluoroboric acid is the most effective acid for rearrangement of a-hydroxy ketene dithioketals to a,p-unsaturated thiol esters. This rearrangement is particularly useful for rearrangement of the tertiary allylic alcohols formed by addition of organometallic reagents to a-keto ketene dithioketals, which are readily available by reaction of ketone enolates with carbon disulfide followed by alkylation with methyl iodide. 

The cycloaddition of chiral (-)menthylcarbodiimide with prochiral ketenes affords chi-rally selective cycloadducts In the reaction of an optically active alcohol with dicy-clohexylcarbodiimide complete inversion of the configuration occurs after hydrolysis. " Treatment of arenesulfenic acids with alcohols, thiols or secondary amines in the presence of optically active carbodiimides affords the corresponding optically active arenesulfenic acid derivatives. DCC is used to convert an optically active selenoxide into the corresponding optically active selenimide with TsNHa. ... 

The reaction of thiol esters with lithium ynolates (equation 67) takes place by a route different than the one shown in equation 65 for alcohol esters. Thiol esters (162) undergo a two-carbon homologation to S-keto thiol esters 165 in good yield. Intermediates 163 undergo a two-step rearrangement to a S-keto thiol ester enolate (165), via elimination of lithium thiolate to yield a ketene (164), followed by the nucleophilic attack of the thiolate on 164. Finally, the homologated S-keto thioester (165 ) is obtained on acidification of the reaction mixture . ... 

The requisite a-diazo thiol esters are conveniently prepared by using the "detrifluoroacetylative" diazo transfer strategy previously developed in our laboratory. Cycloadditions are best carried out by using as little as 0.006 equiv of rhodium(II) acetate to promote the thia-Wolff rearrangement. Reactions involving the more nucleophilic ketenophiles proceed smoothly in refluxing dichloromethane (40°C), while cycloadditions with less reactive partners are best accomplished in 1,2-dichloroethane (83°C). As is standard for ketene cycloadditions, the optimal protocol involves slowly adding a solution of the diazo thiol ester to a solution of the ketenophile and catalyst in order to minimize competitive ketene dimerization. 

Examples of the application of this chemistry to the preparation of cyclobutanones, cyclobutenones, and P-lactams are presented in the Table. The mesityl thiol ester has proven to be particularly effective in reactions with less ketenophilic alkenes, although with the more reactive ketenophiles nearly identical results are obtained using either the mesityl a-diazo thiol ester or the more readily available thiophenyl ester. In the case of readily available ketenophiles, the reaction is best conducted using excess alkene, alkyne, or imine, but in other cases the cycloaddition can be carried out with excess diazo thiol ester. The efficiency of the reaction with unactivated alkenes is especially notable, and compares favorably with results obtained previously employing dichloroketene. For example, addition of dichloroketene to methylenecyclohexane is reported to proceed in 55% yield," while up to 81% of the desired [2-1-2] cycloadduct is produced in the reaction of (mesitylthio)ketene with this olefin under our conditions. 

Ynamines are obtained by thiol elimination from ketene 5, A -acetals (1-aIkylthio-l-dialkylaminoalkenes) in 40-50% yields on treatment with LiNEt, at 20 °C or with NaNHo in boiling piperidine, or by leading them over solid NaNH.j at 150-165 °C. In the first two procedures the formed ynamines are fractionally distilled from the reaction mixture (equation 83) . When elimination is effected with KNHj in HMPT, aqueous work-up leads to the hydration of the ynamine. Therefore, 1,2-dibromo-ethane is added to the reaction mixture. It functions as a proton donor for the... 

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