Thiocarbonyl 5-methylides

In some cases, aliphatic thiocarbonyl (5)-methylides can be protonated by 2,5-dihydro-l,3,4-thiadiazoles, which are their precursors, to give a thioxonium ion (e.g., 56). Carbanion 57 undergoes a ring opening to thiolate 58, which subsequently combines with 56 to give (5,5)-acetal 59 (40,103) (Scheme 5.22). 

Cycloadditions with other symmetrical acetylenes were carried out by using thiocarbonyl (5)-methylide (69) (159). Interestingly, no reaction was observed when acetylene dicarboxamide was used. The reaction of 69 with cyclooctyne resulted in the formation of cycloadduct 103 (Scheme 5.38). Interestingly, the spirocyclic 2,5-dihydrothiophenes of type 103 or 104 undergo acid-catalyzed ring opening upon treatment with silica gel or trifluoroacetic acid to give thiophenes 105 and 106, respectively. 

Reactions with Carbenes and Carbenoids. Photochemical decomposition of diazomethane in the presence of 1 in an argon matrix at 10 K yields thiocarbonyl 5-methylide (8) via addition of methylene to the sulfur atom. While increasing the temperature, 8 undergoes a 1,3-dipolar electrocyclization to give thiirane 9 (eq 5). 

A regioselective [3+2] cycloaddition of thiocarbonyl 5-methylides with 1,3-thiazol-5(4/f)thiones as the dipolarophiles has also been observed ". ... 

In the reaction of 2,2,4,4-tetramethylcyclobutan-l-one-3-thiocarbonyl 5-dimethyl-methylide with suitable dipolarophiles, [3+2] cycloadducts are similarly obtained in high yields. For example, reaction with tetracyanoethylene affords the [3+2] cycloadduct in 58% yield. Likewise, the thiocarbonyl -methylide derived from spiro[fenchane-2,2 -(1,3,4-thiadiazoline)] is trapped with dipolarophiles to give the corresponding [3+2] cycloadducts . 

The relative rate constants for cycloaddition of thiocarbonyl -methylides with dipolarophiles show that C=S dipolarophiles are very efficient. For example, thiofluorenone exceeds tetracyanoethylene and thiobenzophenone reacts 3000 times faster than dimethyl acetylene-dicarboxylate. ... 

The Corey-Chaykovsky reaction entails the reaction of a sulfur ylide, either dimethylsulfoxonium methylide (1, Corey s ylide, sometimes known as DMSY) or dimethylsulfonium methylide (2), with electrophile 3 such as carbonyl, olefin, imine, or thiocarbonyl, to offer 4 as the corresponding epoxide, cyclopropane, aziridine, or thiirane. ... 

Dithiolane isocyanate iminium methylides (55), are a new type of azomethine methylide derived 1,3-dipole, and undergo efficient and regioselective cycloaddition to thiocarbonyls to yield predominandy thiazolidine-2-thiones (56) <96TL711>. 

The dipolar structure 1 describes the chemical behavior of thiocarbonyl ylides best, although other mesomeric forms have been used for the representation of the electronic structure of these dipoles. The parent compound, thioformaldehyde (5)-methylide (1), was studied by means of spectroscopic and theoretical methods (2-5), which showed that the molecule possesses a bent allyl-type structure (6). According to theoretical calculations, structures lA and IB have the largest contribution (31.5% each) in the representation of the electronic structure, whereas 1C, which reflects the 1,3-dipolar character, has only a 4.2% contribution (5). 

Over the past two decades, important contributions to the chemistry of thiocarbonyl ylides were made by Huisgen et al. (27). By carrying out the reaction of thiobenzophenone with diazomethane at low temperature, formation of 2,5-dihydro-l,3,4-thiadiazole (15) with subsequent elimination of N2 was established as the route to the reactive thiobenzophenone (S)-methylide (16) (17,28). In the absence of intercepting reagents, 16 undergoes electrocyclization to give 17 or head-to-head dimerization to yield 1,4-dithiane 18 (Scheme 5.3). 

The desilylation methodology for the generation of 1,3-dipoles, developed by Vedejs and West (29) with regard to azomethine ylides, was successfully applied by Achiwa and co-workers (30) to the field of thiocarbonyl ylides. This approach allowed the generation of the parent thioformaldehyde (5)-methylide (la) and its use for preparative purposes (31,32). Generation of la in the presence of C=C dipolarophiles led to tetrahydrothiophenes (19) in high yield (Scheme 5.4). 

Acidic compounds of type R—XH, which are able to protonate thiocarbonyl ylides, also undergo 1,3-addition leading to products of S,S-, S,0-, or 5,A-acetal type (Scheme 5.20). Thiophenols and thiols add smoothly to thiocarbonyl ylides generated from 2,5-dihydro-l,3,4-thiadiazoles (36,38,86,98,99). Thiocamphor, which exists in solution in equilibrium with its enethiol form, undergoes a similar reaction with adamantanethione (5)-methylide (52) to give dithioacetal 53 (40) (Scheme 5.21). Formation of analogous products was observed with some thiocarbonyl functionalized NH-heterocycles (100). 

Numerous examples involving the preparation of tetrahydrothiophenes via [3 + 2] cycloaddition of thiocarbonyl ylides with electron-poor alkenes have been reported. Thiobenzophenone (5)-methylide (16), generated from 2,5-dihydro-1,3,4-thiadiazole (15) and analogous compounds, react with maleic anhydride, N-substituted maleic imide, maleates, fumarates, and fumaronitrile at —45°C (28,91,93,98,128,129). Similar reactions with adamantanethione (5)-methylide (52) and 2,2,4,4-tetramethyl-3-thioxocyclobutanone (5)-methylide (69) occur at ca. +45°C and, generally, the products of type 70 were obtained in high yield (36,94,97,130) (Scheme 5.25). Reaction with ( )- and (Z)-configured dipolaro-philes stereospecifically afford trans and cis configured adducts. 

Reaction with acetylenic dipolarophiles represents an efficient method for the preparation of 2,5-dUiydrothiophenes. These products can be either isolated or directly converted to thiophene derivatives by dehydration procedures. The most frequently used dipolarophile is dimethyl acetylenedicarboxylate (DMAD), which easily combines with thiocarbonyl yhdes generated by the extrusion of nitrogen from 2,5-dihydro-1,3,4-thiadiazoles (8,25,28,36,41,92,94,152). Other methods involve the desUylation (31,53,129) protocol as well as the reaction with 1,3-dithiohum-4-olates and l,3-thiazolium-4-olates (153-158). Cycloaddition of (5)-methylides formed by the N2-extmsion or desilylation method leads to stable 2,5-dUiydrothiophenes of type 98 and 99. In contrast, bicyclic cycloadducts of type 100 usually decompose to give thiophene (101) or pyridine derivatives (102) (Scheme 5.37). 

The reaction of thiocarbonyl ylides with propiolates affords a mixture of regioisomeric cycloadducts. Thus, 2,5-dihydrothiophenes obtained from the reaction of adamantanethione (5)-methylide (52) and methyl propiolate were produced in a 1 1 ratio (95). In the case of ylide 69, the ratio was 1 2 in favor of the sterically less hindered isomer (160). 

For preparative purposes, the reaction of thiocarbonyl ylides with carbonyl compounds can be considered as an alternative method for the synthesis of 1,3-oxathiolanes. Aromatic aldehydes, chloral, glyoxalates, mesoxalates, pyruvates as well as their 3,3,3-trifluoro analogues are good intercepting reagents for thioketone (5)-methylides (36,111,130,163). All of these [3 + 2] cycloadditions occur in a regioselective manner to produce products of type 123 and 124. 

The desUylation strategy has been used for the cycloaddition of the parent thiocarbonyl yhde la with aldehydes and reactive ketones. The product obtained using A-methyl-3-oxoindolinone as the trapping agent corresponds to the spiro-cyclic compound 125 (168). Thioketene (5)-methylide (127) was reported to react with aromatic aldehydes and some ketones to furnish 2-methylene-substituted 1,3-oxathiolanes (128) (51) (Scheme 5.42). 

Only a few examples of the [3 + 2] cycloaddition of thiocarbonyl ylides with C=N compounds have been reported so far. By comparison with aldehydes, imines are poor dipolarophiles. For example, Al-benzylidene methylamine and adamanta-nethione (5)-methylide (52) produce 1,3-thiazolidine (129) in only 13% yield (163). An alternative and efficient approach to 1,3-thiazohdines involves the [3 + 2] cycloaddition of azomethine ylides with thiocarbonyl compounds [cf. (169)]. 

The following types of dipolarophiles have been used successfully to synthesize five-membered heterocycles containing three heteroatoms by [3 + 2]-cycloaddition of thiocarbonyl ylides azo compounds, nitroso compounds, sulfur dioxide, and Al-sulfiny-lamines. As was reported by Huisgen and co-workers (91), azodicarboxylates were noted to be superior dipolarophiles in reactions with thiocarbonyl ylides. Differently substituted l,3,4-thiadiazolidine-3,4-dicarboxylates of type 132 have been prepared using aromatic and aliphatic thioketone (5)-methylides (172). Bicyclic products (133) were also obtained using A-phenyl l,2,4-triazoline-3,5-dione (173,174). 

A-Sulfinylamines (R—N=S=0) are known to function as reactive dienophiles and dipolarophiles, and some examples of [3 + 2] cycloaddition with thiocarbonyl ylides have been reported (176). For example, the reaction of thiobenzophenone (5)-methylide (16) with both A-phenyl and N-tosylsulfinylamines occurs regiose-lectively to give 1,3,4-dithiazolidine 3-oxides (135). In the case of thiocarbonyl ylide 69, reaction with N-phenyl sulfinylamine selectively afforded the analogous product 136 (R = Ph). However, the corresponding reaction with Al-tosyl sulfinylamine resulted in a mixture of the N,S-adduct (136) (R =Tos) and the 0,S-adduct 137. Formation of a mixture of products is compatible with a stepwise reaction via a zwitterionic intermediate. 

Like many other 1,3-dipoles (e.g., nitrile ylides, imines, and oxides) (7), thiocarbonyl ylides undergo head-to-head dimerization to give sterically crowded 1,4-dithianes. The first reported example involves the formation of 2,2,3,3-tetraphenyl-l,4-dithiane (18) from thiobenzophenone (5)-methylide (16) (17,28) (cf. Scheme 5.3). Other (5)-methylides are known to form analogous 1,4-dithianes (e.g., thiofluorenone (5)-methylide yields 172) (17). The (5)-methylides of 4,4-dimethyl-2-phenyl-l,3-thiazole-5(4//)-thione (105) and methyl dithiobenzoate (60,104) dimerize to give compounds 173 and 174, respectively. 

In some reactions with thiocarbonyl ylides, 1,3-thiazine derivatives are formed by a series of consecutive reactions. For example, the interception of 3-thioxocy-clobutanone (5)-methylide (69) with thiobenzamide results in the formation of the bicyclic 1,3-thiazine (176) (100a) (Scheme 5.50). A conceivable intermediate is the 1,3-adduct 175 as shown in Scheme 5.50. 

Saito et al. <1995S87> described a new method for the synthesis of heterocycle-fused[c]thiophenes via reaction of aryl heteroaryl thioketones with the carbene precursors. Heteroaromatic thioketones A react with carbenoids generated from bis(arylsulfonyl)diazomethanes or phenyliodonium bis(phenylsulfonyl)methylides to give heterocycle-fused[f]thiophenes B. The reaction involves the ring closure of the intermediary thiocarbonyl ylides, followed by restorative aromatization via the elimination of a sulfenic acid (Equation 11). 

Thiocarbonyl ylides are both nucleophilic and basic compounds (40,41,86). For example, adamantanethione (5)-methylide (52) is able to deprotonate its precursor, the corresponding 2,5-dihydro-1,3,4-thiadiazole, and a 1 1 adduct is formed in a multistep reaction (40,86). Thioxonium ion (56) (Scheme 5.22) was proposed as a reactive intermediate. On the other hand, thiofenchone (S)-methylide (48) is not able to deprotonate its precursor but instead undergoes electrocyclization to give a mixture of diastereoisomeric thiiranes (41,87,88). The addition of a trace of acetic acid changes the reaction course remarkably, and instead of an electrocyclization product, the new isomer 51 was isolated (41,87) (Scheme 5.18). The formation of 51 is the result of a Wagner-Meerwein rearrangement of thioxonium ion 49. 

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