Thiocarbonyl compounds, cycloaddition

There is an enormous literature on thiocarbonyl compounds, due in part to the technical and industrial importance of many of them, including thioamides, thioureas, xanthates, dithiocarbamates and so forth. An excellent, and recent, general review is available.107 There are also specialized reviews germane to the present chapter Griffin, Woods, and Klayman2 discussed the use of thioureas in the synthesis of heterocycles the preparation of thiazoles from thioamides is included in a three-part volume on Thiazoles 108 the use of carbon disulfide in the synthesis of trithiones and related heterocycles has been reviewed by Mayer109 and Huisgen110 has reported numerous examples of 1,3-dipolar cycloadditions in which carbon disulfide was used. 

Reaction of lithium trimethylsilyldiazomethane (TMSC(Li)N2) with thiocarbonyl compounds has proved to be a convenient method for the preparation of 5-substituted 1,2,3-thiadiazoles. This reaction is very similar to the Pechmann-Nold reaction but probably does not proceed through a dipolar cycloaddition pathway. A number of examples of this type of reaction were described in CHEC-II(1996). More recently, it was reported that TMSCN2Li also reacts with diethylaminothiocarbonyl chloride to afford a mixture of 1,2,3-thiadiazoles 66 and 67 (Equation 19) <1997BSB533>. 

I.3.4.2.5. Carbonyl and Thiocarbonyl Compounds a-(Hydroxyimino)phenyl-acetonitrile oxide (generated in situ at room temperature from PhC( NOH)C ( NOH)Cl in the presence of NaHC03 or Et3N) reacts with simple aldehydes and ketones R1R2CO to give 1,4,2-dioxazoles 180 (347). Related dioxazoles, formed by cycloaddition of benzonitrile oxide to aromatic aldehydes, upon treatment with I-BuOK, undergo cyclo-reversion, allowing direct conversion to substituted benzoic acids or their esters (348). 

When planning reactions of thiocarbonyl compounds with electrophilic carbene complexes it should be taken into aceount that thiocarbonyl compounds can undergo uncatalyzed 1,3-dipolar cycloaddition with acceptor-substituted diazomethanes to yield 1,3,4-thiadiazoles. These can either be stable or eliminate nitrogen to yield thiiranes or other products similar to those resulting from thiocarbonyl ylides [1338]. 

Scheme 12 shows synthesis of 1,2,3-thiadiazoles by the Wolff, Hurd-Mori and Pechmann-Nold methods. Pechmann s and Wolffs are the oldest of the methods. The Pechmann-Nold synthesis involves the [3 + 2] cycloaddition of diazo-compounds to isothiocyanates or thiocarbonyl compounds (modified Pechmann synthesis). The use of thiocarbonyl compounds in the [3 + 2] cycloaddition step has broadened the scope of this reaction and made the starting materials more readily accessible. Wolffs method requires the synthesis of diazoketones that are treated with a thionating reagent to produce 1,2,3-thiadiazoles. With the development of new methods of diazotransfer reactions, the diazoketone precursors have become easily attainable and with further attention to the thionating reagents, this reaction is also useful for the synthesis of 1,2,3-thiadiazoles. 

Closely related to the already mentioned electrocyclizations of N-acyl thione S-imide (see Section 4.14.9.2) are some intermolecular cycloadditions involving this unusual class of 1,3-dipoles. Thus, the thione-S-imide intermediate (233) is probably involved in the formation of spirodithiazoline derivative (234) from the thione (235) and aryl azides <93HCA2147>. Also fluorenone-S-/ -tosylimide affords with carbonyl or thiocarbonyl compounds (R H) the corresponding oxathia- or dithia-zolidine derivatives (236) (Y = O or S) <80BCJ1023> (Scheme 44) (see also Section 4.14.6.1). 

An attempted synthesis of biotin using thiocarbonyl ylide cycloaddition was carried out (131,133,134). The crucial step involves the formation of the tetrahydrothiophene ring by [3 + 2] cycloaddition of a properly substituted thiocarbonyl ylide with a maleic or fumaric acid derivative (Scheme 5.27). As precursors of the thiocarbonyl ylides, compounds 25a, 72, and 73 were used. Further conversion of cycloadducts 74 into biotin (75) required several additional steps including a Curtius rearrangement to replace the carboxylic groups at C(3) and C(4) by amino moieties. 

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)]. 

Table 14 Cycloaddition Reactions of Thiocarbonyl Compounds with Dienes...

Sigmatropic, electrocyclic, cycloaddition and cycloelimination, and cheletropic reactions have all been carried out with organosulfur compounds and often used for synthetic puiposes. A chapter of Block s monograph (203] is devoted to this topic, and most of the pericyclic processes include examples with sulfur compounds. The treatises by Barton and Ollis [482], Trost and Fleming [483] and Klamann [484] are guides to the more specialized literature. Some reviews deal with specific cases thiocarbonyl compounds [120] or cycloaddition reactions [485],... 

Cycloaddition of diazoalkanes with thiocarbonyl compounds occurs usually in the regiochemistry derived from a thiophilic addition of the carbon end of the dipole to sulfur, yielding a 1,3,4-thiadiazoline (1). 

The cleavage of the S —N bond in a phthalimidesulfeny 1 derivative may be achieved with base yielding a thiocarbonyl compound, which is trapped either as [2 + 4] cycloaddition product331 or in a 1,3-dipolar reaction332 (equation 62). 

Thiocarbonyl compounds are excellent reaction partners in all types of cycloadditions, especially 1,3-dipolar (Section IV.E.3) and Diels-Alder reactions (Section IV.E.4). They have been frequently used in the trapping of unstable thiocarbonyl derivatives1. 

A cycloreversion mechanism is suggested for the transformation of the nonisolable cycloadduct 90 to the aldehyde 91 and isothiocyanate 92 <1996BCJ719> and for the spiro-1,4,2-oxathiazole intermediates 94 to the dioxothiazoline 95 and the aryl isothiocyanate 92 <2001MOL510>. Both cycloadducts are obtained by cycloaddition reactions of nitrile oxides 88 to thiocarbonyl compounds (Scheme 12). 

Although the 1,4,2-oxathiazolidine derivatives 16 (X = O Y = S) are usually nonisolable intermediates of reactions between nitrones and thiocarbonyl compounds, in some instances a cycloaddition/cycloreversion equilibrium is established with steric hindrance influencing its position. This is the case for the kinetically stable... 

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