Dithiolanes, cleavage

Secondary thiols.8 A new preparation involves dithiolane cleavage with n-butyllilhium to thiones, which are known to be reduced by the same reagent to sec-thiols by /8-hydride transfer. Yields are 78 90% from saturated thioketals. The mtthod is less useful for preparation of aryl substrates owing to competitive ItlflUltttion of the aromatic ring. 

Mercaptans are generally prepared by displacement reactions. However. secondary or hindered mercaptans are more difficult to obtain. The dithiolane cleavage icaction is a convenient in situ generation of thioketones which are known to be reduced with butyllithium to secondary mercaptans by p-hydrogen transfer Table I shows a number of mercaptans prepared from saturated thioketals in 78-90% yields. The aryl example gives lower yields partly because of ring metalation. 

BF3 Et20, EtSH, 25°, 40 min, 80-90% yield. Addition of sodium sulfate prevents hydrolysis of a dithioacetal group present in the compound replacement of ethanethiol with ethanedithiol prevents cleavage of a dithiolane group. 

Me3SiI, CH2CI2, 25°, 15 min, 85-95% yield.Under these cleavage conditions i,3-dithiolanes, alkyl and trimethylsilyl enol ethers, and enol acetates are stable. 1,3-Dioxolanes give complex mixtures. Alcohols, epoxides, trityl, r-butyl, and benzyl ethers and esters are reactive. Most other ethers and esters, amines, amides, ketones, olefins, acetylenes, and halides are expected to be stable. 

A carbonyl group can be protected as a sulfur derivative—for example, a dithio acetal or ketal, 1,3-dithiane, or 1,3-dithiolane—by reaction of the carbonyl compound in the presence of an acid catalyst with a thiol or dithiol. The derivatives are in general cleaved by reaction with Hg(II) salts or oxidation acidic hydrolysis is unsatisfactory. The acyclic derivatives are formed and hydrolyzed much more readily than their cyclic counterparts. Representative examples of formation and cleavage are shown below. 

Attempted cleavage using Hg(II) salts gave material that could not be distilled. 1,3-Dithiolanes can also be cleaved with Ag20 (MeOH, H2O, reflux, 16 h-4 days, 75-85% yield). 

The section on the cleavage of 1,3-dithianes and 1,3-dithiolanes (pp. 203-205), should be consulted since many of the methods described there are also applicable to the cleavage of oxathiolanes. 

Cleavage of 2,2-dibutyl 1,3-dithiolane with fluorine in anhydrous hydrogen fluoride results in the formation of 5,5-difluorononane [7] (equation 3)... 

DDQ, CH3CN, H2O, 80°, 43-95% yield."" These conditions also resulted in the cleavage of acetyl groups a dithiolane was stable to the conditions. 

An anomolous cleavage of a dithiolane was observed during an attempted hydroboration. ... 

The (racemic) tmns disulfoxide of 1,3-dithiolane 59 is readily deprotonated at C2 by lithium hexamethyldisilazide, and the resulting anion reacts with aldehydes at -78°C with moderate to excellent diastereoselectivity to give mainly the products 60, although subsequent cleavage of these to give the a-hydroxyaldehydes was not described (97JOC1139). 

Reductive cleavage of 1,3-dithiolanes is accomplished in low yields with sodium in liquid ammonia and gives either dithiols or mercapto sulfides depending on substituents in position two [679]. 

Scheme 1.64). The Ag(I)-mediated cyclization afforded dipole 306 for 1,3-dipolar cycloaddition with methyl vinyl ketone to yield adducts 307 and the C(2) epimer as a 1 1 mixture (48%). Hydrogenolytic N—O cleavage and simultaneous intramolecular reductive amination of the pendant ketone of the former dipolarophile afforded a mixture of alcohol 308 and the C(6) epimer. Oxidation to a single ketone was followed by carbonyl removal by conversion to the dithiolane and desulfurization with Raney nickel to afford the target compound 305 (299). By this methodology, a seven-membered nitrone (309) was prepared for a dipolar cycloaddition reaction with Al-methyl maleimide or styrene (301). 

A photosensitized cleavage of dithianes and dithiolanes by visible light [53,54] deserves to be mentioned. 

Dithioacetals (see also dithianes and dithiolanes) alkylation of 98 as acyl anion equivalents 75 carbanions of 87,97-102 cleavage of 14-18,98,102 desulfurization of 78 metal-catalysed coupling 127 reaction with Grignard reagents 127 reductive lithiation of 89 synthesis of 12-19,97-102 Dithioacids synthesis of 40... 

Typical examples for type 1 are the anodic cleavages of two carbon-sulfur bonds in 1,3-dithianes [46] or dithiolanes [47]. This reaction is especially effective if performed under the conditions of indirect electrolysis using triarylamine cation radicals as regenerable oxidative mediators [47] ... 

Flash vacuum pyrolysis (FVP) of 1,3-dithiolane 1-oxides (88-90), as a possible route to thiocarbonyl compounds, has been studied.57 Thiobenzophenone and thiofenchone are obtained from (88) and (89), respectively, but there was no evidence of heptane-4-thione formation from (90). A stepwise homolytic cleavage has been proposed. 

Pyrolytic methods involve the use of dithiolane S, S -dioxides as starting materials which, upon heating, afford reactive thioaldehydes, such as trifluorothioacetaldehyde, trapped as the Diels-Alder adduct369,370 (equation 82). In equation 80 an enethiolate was formed, and this feature has been employed also in the cleavage of the oxathiolane 78. The silver vinylthiolate 79 thus obtained was applied in the preparation of new antibacterial cephem derivatives371. 

Lewis acids readily isomerize both 1,3-dioxolanes and 1,3-oxathiolanes in ether solution. The reaction proceeds by coordination with the oxygen atom in the latter case since 1,3-dithiolanes do not isomerize under the same conditions. With trityl carbonium ion, an oxidative cleavage reaction takes place as shown in Scheme 6. Hydride extraction from the 4-position of 2,2-disubstituted 1,3-dioxolanes leads to an a-ketol in a preparatively useful reaction. 1,3-Oxathiolanes are reported to undergo similar cleavage but no mention of products other than regeneration of the ketone has been made (71CC861). Cationic polymerization of 1,3-dioxolane has been initiated by a wide variety of proton acids, Lewis acids and complex catalytic systems. The exact mechanism of the polymerization is still the subject of controversy, as is the structure of the polymer itself. It is unclear if polymerization... 

---