Of thioacetals

A-2-Oxazoline-5-one (2091 when treated with thioacetic acid yields the corresponding thiazoline-5-one (210) (Scheme 107) (458. 461). These results have been questioned recently (365) however, it appears in the later report that a large excess of thioacetic acid was used instead o-f the stoichiometric amount previously used. 

The condensation of thioacetic acid with amino acids under drastic conditions provides a useful new synthesis of thiazoles (Scheme 146) (668, 669). Instead of the amino acid, Af-acyl <279) or N-thioacylamino acids (278) are used. 

At low temperature a 1 1 adduct of thioacetic acid and an enamine could be prepared (709). The previously described reaction of aminomethylene ketones with hydrogen peroxide was extended to bisaminomethylene compounds. However, acylated cyclohexenamines led to cyclopentane-carboxamides (770), Trichloromethyl adducts of enamines and the rearranged amine derivatives were described in a further study (777). 

Another example of resort to heteroatoms to obtain both oral potency and a split between androgenic and anabolic activities Ls tiomestrone (99). Trienone, 98, prepared in much the same way as 23, undergoes sequential 1,6 and 1,4 conjugate addition of thioacetic acid under either irradiation or free radical catalysis to afford the compound containing two sulfur atoms. 

A mixture of approximately 11 parts of 17o-(2-carboxyethyl)-17(3-hydroxyandrosta-4,6-dien-3-one lactone and 10 parts of thioacetic acid is heated at 85° to 95°C for h hour. Excess thioacetic acid is removed by vacuum distillation at this point, and the residue is twice recrystallized from methanol, affording 7o-acetylthio-17o-(2-carboxyethyl)-17(3-hy-droxyandrost-4-en-3-one lactone, melting at approximately 134° to 135°C. Heated above this melting point, the product solidifies and melts again at approximately 201° to 202°C (with decomposition). 

When aldol reactions of thioacetates are mediated with the following computer-designed bromoborolane [available in 26% yield from ( )-menthone] /(-hydroxy thioesters are obtained in 85-96.7% ee. The yields range from 60 90%t,4c. 

The keto function is frequently deoxygenated via Ra-Ni-mediated desulfurization of thioacetals 412 14 That is, the ketone group can be removed from compound (36) by thioketalization followed by desulfurization with Ra-Ni (81 mmol Ni/mmol) in MeOH for 20 minutes (Scheme 4.118).415... 

The parent hexathiaadamantane (185) is obtained preparatively when a solution of formic acid and hydrochloric acid in nitrobenzene is allowed to stand for several weeks in a hydrogen sulfide atmosphere the product which separated is almost insoluble in all common solvents and purification presents a problem. Only large volumes of dimethyl sulfoxide at reflux serve for recrystallization.224 The reaction of thioacetic acid with formic acid in the presence of zinc chloride gives tetramethyl-(186), monomethyl-, dimethyl-and trimethylhexathiaadamantane derivatives (187).225 Other variations include the reaction of thioacetic acid with a /i-diketone,226 and the use of boron trifluoride227 or aluminum chloride as a catalyst.228... 

A report on the deprotection of thioacetals with clayan (80-89%) soon followed [46],... 

Aggarwal et al.108 reported excellent results with the catalytic asymmetric epoxidation of aldehydes. As shown in Scheme 4-52, a series of thioacetals 137 was prepared from hydroxy thiol 136 and the corresponding carbonyl compound. Among them, compound 138, derived from 136 and acetaldehyde, proved to be the best catalyst for asymmetric epoxidation of aldehydes. 

This reaction is very sensitive to water because in the presence of water and a metal salt (such as copper salt) the thioacetal tends to decompose, and this may reduce the amount of thioacetal available for epoxidation. When water is excluded from all the reagents, the reaction can be carried out in the presence of a catalytic amount of thioacetal. Otherwise, a stoichiometric amount of thioacetal compound is required. Scheme 4 53 summarizes the epoxidation of aldehydes using 138 as the chiral-inducing reagent. Excellent enantioselectivities are obtained in most cases. 

Scheme 14.16. Transformation of thioacetals into y-substituted allylsilanes.

Scheme 14.34. Stereoselective preparation of conjugated dienes by the titanocene(ll)-promoted reaction of thioacetals with alkynes.

The carbene complexes generated by desulfurization of thioacetals with the titanoce-ne(II) species react with internal alkynes to produce the conjugated dienes 79 with high stereoselectivity (Scheme 14.34) [77]. The process appears to involve syn-elimination of P-hydride from the alkyl substituent that originates from the carbene complex after the formation of titanacyclobutene 80. 

In order to ascertain whether sufficient nickel to complete a given reaction has been used, the liquid phase may be tested for starting material before an attempt is made to isolate a product. In general the sodium fusion test for sulfur is satisfactory for this purpose but in certain individual cases a specific test may be more convenient. Thus, in the desulfurization of thioacetals (mercaptals), unreacted material... 

When 2-4-0-ethylidene-D-glucofuranurono-6,3-lactone [obtained by the hydrolysis of thioacetal 61 (Ph = Et)] was treated with 5,5-dimethyl-l,3-cyclohexanedione (dimedone), 6-deoxy-6,6-bis(4,4-di-methyl-2,6-dioxocyclohexyl)-3,5-0-ethylidene-L-gulono-1,4-lactone (73) was formed in 71% yield.99... 

In addition to the common methods of synthesis, it has been shown that the desulfurization of thioacetals yields organogermanes (Equations (7) and (8)) with excellent selectivity in some cases (Equation (9)).8 Ring-opening reactions of strained [l]ferrocenophanes furnish germanium-substituted ferrocenes9,10 (Equation (10)).9... 

Crossed Michael-type reactions of thioacetates MeCOSCH(R )CH,CHO with a,(3-unsaturated... 

Wiles C. and Watts, P. and Haswell, S. J. (2007). An efficient, continuous flow technique for the chemoselective synthesis of thioacetals. Tetrahedron Letters, 48, 7362-7365. 

The conjugate additions of thiols to a,p-unsaturated electrophiles was extended by Wang [96]. Catalyst 166 promoted the addition of thioacetic acid to a variety of enones, including aliphatic, aromatic and heteroaromatic substituents (Scheme 42). Wang expanded the scope of the reaction to include asymmetric additions of thioacetic acid to nitro-olefms (Scheme 43) [97]. Thiourea catalyst 166 promoted the addition reactions in high yields and high enantiomeric ratios for a variety of P-substituted nitro-olefms. 

The reactions proceeded efficiently under mild conditions in short time. The silyl enol ethers reacted with the activated acetals or aldehydes at -78 °C to give predominant erythro- or threo-products [136, 137] respectively. In the same manner, the aldol reaction of thioacetals, catalyzed by an equimolar amount of catalyst, resulted in <-ketosulfides [139] with high diastereoselectivity. In the course of this investigation, the interaction of silyl enol ethers with a,]3-unsaturated ketones, promoted by the trityl perchlorate, was shown to proceed regioselec-tively through 1,2- [141] or 1,4-addition [138]. The application of the trityl salt as a Lewis acid catalyst was spread to the synthesis of ]3-aminoesters [142] from the ketene silyl acetals and imines resulting in high stereoselective outcome. 

Because carbohydrates are so frequently used as substrates in kinetic studies of enzymes and metabolic pathways, we refer the reader to the following topics in Ro-byt s excellent account of chemical reactions used to modify carbohydrates formation of carbohydrate esters, pp. 77-81 sulfonic acid esters, pp. 81-83 ethers [methyl, p. 83 trityl, pp. 83-84 benzyl, pp. 84-85 trialkyl silyl, p. 85] acetals and ketals, pp. 85-92 modifications at C-1 [reduction of aldehydes and ketones, pp. 92-93 reduction of thioacetals, p. 93 oxidation, pp. 93-94 chain elongation, pp. 94-98 chain length reduction, pp. 98-99 substitution at the reducing carbon atom, pp. 99-103 formation of gycosides, pp. 103-105 formation of glycosidic linkages between monosaccharide residues, 105-108] modifications at C-2, pp. 108-113 modifications at C-3, pp. 113-120 modifications at C-4, pp. 121-124 modifications at C-5, pp. 125-128 modifications at C-6 in hexopy-ranoses, pp. 128-134. 

The same group utilized thiourea 12 (10mol% loading) for the catalysis of the enantioselective Michael addition of thioacetic acid to various chalcones [214]. At room temperature and otherwise unchanged conditions, in comparison to the... 

Scheme 6.64 Michael adducts provided from the 12-catalyzed asymmetric addition of thioacetic acid to various chalcones.

Scheme 6.65 Mechanistic proposals for the biflinctional mode of action of catalyst 12 in the Michael addition of thioacetic acid to nitroalkenes (A) and to chalcones (B).

Glycosyl halides (7a-e) were stereoselectively transformed into l,2-tra s-thio-glycoses by i) (8a-d, 8j) a two-step procedure via the pseudothiourea derivatives [9,10a] the substitution of halide by thiourea is mostly a S l-type reaction since acetylated 1-thio-a-D-mannose (8b) was obtained from acetobromoman-nose (7b) [9cj ii) (8e-i) using thiolates in protic and aprotic solvents [10], or under phase transfer catalysis conditions [11]. Another approach involved the reaction of thioacetic acid with 1,2-trans-per-O-acetylated glycoses catalyzed with zirconium chloride [12]. The 1,2-trans-peracetylated 1-thioglycoses (8e-h) were obtained in high yield. No anomerized products could be detected in these reactions (Fig. 1). 

The first syntheses of 1,2-cfs-thioglycoses (a-D-gluco- and )3-D-manno- derivatives) have been achieved by the reaction in acetone of alkyl or benzyl xanthate or potassium thioacetate with the corresponding l,2-tra s-glycosyl halides [13]. More recently, tetra-O-acetyl-l-S-acetyl-l-thio-a-D-glucopyranose (10a) (Scheme 3) has been obtained i) by reaction of -acetochloroglucose (9 a) with either potassium thioacetate in HMPA or the tetrabutylammonium salt of thio-acetic acid in toluene [14] ii) by peroxide-induced addition of thioacetic acid to the pseudo-glucal (11) [15]. 

Several methods were described for the selective de-S-acetylation of 0-acetyl protected 1-thioglycoses. Sodium methoxide in methanol at low temperature (below -20 °C) was known to afford mainly the de-S-acetylated compound [16] or exclusively this compound when the reaction was quenched at low temperature by adding H-l- resin [17]. Demercuration of tetra-O-acetyl-l-phenylmercury(II)-thio- -D-glucopyranose (12) (Scheme 4) obtained by treatment of (8e) with phenylmercury(II)acetate afforded a convenient synthesis of tetra-0-acetyl-l-thio-/3-D-glucose (8a) [18]. This sequence applied to the a-anomer (10a) (Scheme 3) led to the expected de-S-acetylated compound (10b) [19]. Chemoselective deprotection of thioacetate at the anomeric position of peracetylated 1-thioglycoses was also achieved in good yield by action of cysteamine in acetonitrile or hydrazinium acetate in DMF [20,11]. 

A novel route to 2,3-dihydrothiophenes involved a titanocene-promoted carbene formation and subsequenct intramolecular cyclization onto a thiol ester <99SL1029>. Treatment of thioacetal 9 with the low-valent titanium complex 10 gave 2,3-dihydrothiophene 12 by intramolecular olefination of the thiol ester of titanium-carbene intermediate 11. Another metal-mediated cyclization onto the thiophene ring system involved the palladium-catalyzed cyclization of 1,6-diynes <99T485>. For example, treatment of thioether 1,6-diyne 13 with Pdlj in the presence of CO and Oj in methanol followed by treatment with base gave 14. 

Table 4 Synthesis of thioacetals 124 (a-anomers) from dihydroartemisinin 29a...

In the reaction of the eight-membered cyclic carbonate rac-lca with KSAc in THF/H2O (see Scheme 2.1.4.21) the conversion of the substrate, even at higher temperatures, did not exceed 53% and gave a mixture of thioacetate 19aa and carbonate ent-lca in a ratio of 53 47. Formation of thioacetate 19aa with 84% ee and of carbonate ent-lca with 72% ee in a ratio of approximately 1 1 (Table 2.1.4.15, entry 1) showed that an efficient kinetic resolution had occurred (see Scheme 2.1.4.21). Similar results were recorded in the reaction of carbonate rac-lca with KSBz (entry 2). The results recorded after the termination of the reaction of the acyclic carbonate rac-3ba with KSBz in CH2CI2/H2O at 48% conversion also revealed the operation of kinetic resolution in this case (entry 3). 

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