Desulfurative silylation

Desulfurative silylation. Dithioacetals are converted to alkylsilanes on reaction with Cp2Ti[P(OEt)3]2 and EtjSiH. Allylsilanes are produced from p,y-unsaturated dithioacetals or l,3-bis(phenylthio)-l-alkenes. Germanes and stannanes are similarly obtained. 

The addition of the lithium enolates of methyl acetate and methyl (trimelhylsilyl)acetate to ( + )-(S)-2-(4-methylphenylsulfinyl)-2-cycloalkenones gives, after desulfurization, (/ -substituted cycloalkenones. A higher level of selectivity is observed with the a-silyl ester enolate and in the cyclohexenone series13. The stereochemical outcome is rationalized by assuming attack on a ground-state conformation analogous to that in Section 1.5.3.2.1. 

A further example of the use of 2//-thiopyrans as surrogates for m-substituted dienes involves the use of the protected 3,4-dihydio-3-(3-oxobutyl)A//-thiopyranA-onc, 3-[2-(2-methyl-l,3-dioxolan-2-yl)ethyl]-4-[tris(l-methy-lethyl)silyl)oxy-2//-thiopyran 328 as an equivalent of l-ethenyl-2-methylcyclohexene in Diels-Alder reactions. The thiopyran reacted with various maleimides to yield the endo cycloadducts and with methyl propenoate to give the exo adduct under either thermal or Lewis-acid-catalyzed conditions. In the latter case concomitant release of the protected ketone functions occurs, acid-catalyzed cyclization of which generates a fused cyclohexenone ring (Scheme 67). Desulfurization, preferably before the aldol cyclization, leads to derivatives of 2,3,4,4a,5,6,7,8-octahy-dro-4a-methylnaphthalenes < 1997CJC681 >. 

Phenylthioalkylation of silyl enol ethers. Silyl enol ethers of ketones, aldehydes, esters, and lactones can be alkylated regiospecifically by a -chloroalkyl phenyl sulfides in fhe presence of a Lewis acid. Zinc bromide and titanium(IV) chloride are the most effective catalysts. The former is more satisfactory for enol ethers derived from esters and lactongs. ZnBr2 and TiCL are about equally satisfactory for enol ethers of ketones. The combination of TiCL and Ti(0-f-Pr)4 is more satisfactory for enol ethers of aldehydes. Since the products can be desulfurized by Raney nickel, this reaction also provides a method for alkylation of carbonyl compounds. Of more interest, sulfoxide elimination provides a useful route to a,B-unsaturated carbonyl compounds. 

In Kiyooka s approach to acetate aldols by use of a stoichiometric amount of 3f, the enantiomeric excess obtained in the reaction with silyl ketene acetals derived from a-unsubstituted acetates was much lower (ca 10-20 %) than that obtained in the reaction with l-ethoxy-2-methyl-l-(trimethylsiloxy)-l-propene (> 98 % ee). Introduction of an removable substituent, e.g., a methylthio or bromo substituent, after aldol reaction at the a-position of chiral esters, resolved this problem [43e], Asymmetric synthesis of dithiolane aldols was achieved in good yield by using the silyl ketene acetal derived from l,3-dithiolane-2-carboxylate in the 3f-promoted aldol reaction, and desulfurization of the dithiolane aldols resulted in production of the acetate aldols in high enantiomeric purity (Eq. 56). 

The chiral oxadiene 281 adds to ethyl vinyl ether giving a 2 1 mixture of endo adducts (-h)-282 and (—)-283. Deacylation of pure (-f)-282 delivers 284, which is then protected as a silyl ether to give 285. Raney nickel reduction and deprotection provides ethyl glycoside 286. Protection of 284 as a benzyl ether, followed by desulfurization and subsequent hydroboration and deprotection, provides (-)-L-olivose [150] (Scheme 13.80). 

The monographs (8,9) also present clear expositions of methods of synthesis. A recent communication addressing a short approach to both symmetrical and unsymmetrical tetrahydrofurofuran lignans is outlined in Scheme 32 (149). Michael addition of the sodium salt of the silyl monoprotected diol (155) to the a-sulfonylcinnamate (156) gave the ether (157) which on desulfurization and hydrolysis gave the hydroxy acid (158). Lactonization of (158) by the Mukaiyama method... 

The studies of Ban and Wakamatsu culminated in the preparation of three natural compounds from a single synthetic route (Scheme 1.15). The enediol bis silyl ether 63 was converted to the dianion and immediately alkylated with l-iodo-3-butanol to give glycol 64 as a mixture of diastereomers in 87% yield. Diol fragmentation with lead tetraacetate afforded keto lactone 65 in quantitative yield. Formation of the dithioketal and subsequent Raney nickel desulfurization then gave 66 (81%). Macrocyclic lactone 66 is the simple natural product... 

In the presence of a Lewis acid, silyl enol ethers can be alkylated with reactive secondary halides, such as substituted benzyl halides, and with chloromethylphenyl sulfide (ClCH2SPh), an activated primary halide. Thus, reaction of the benzyl chloride 10 in the presence of zinc bromide with the trimethylsilyl enol ether derived from mesityl oxide allowed a short and efficient route to the sesquiterpene ( )-ar-turmerone (1.22). Reaction of ClCH2SPh with the trimethylsilyl enol ethers of lactones in the presence of zinc bromide, followed by 5-oxidation and pyrolytic ehmination of the resulting sulfoxide (see Section 2.2), provides a good route to the a-methylene lactone unit common in many cytotoxic sesquiterpenes (1.23). Desulfurization with Raney nickel, instead of oxidation and elimination, affords the a-methyl (or a-alkyl starting with RCH(Cl)SPh) derivatives. ... 

Activation of C-X Bonds. Even more important than carbonyl activation, ZnBr promotes substitution reactions with suitably active organic halides with a variety of nucleophiles. Alkylation of silyl enol ethers and silyl ketene acetals using benzyl and allyl halides proceeds smoothly (eq 13). Especially useful electrophiles are a-thio halides which afford products that may be desulfurized or oxidatively eliminated to result in a,p-unsaturated ketones, esters, and lactones (eq 14). Other electrophiles that have been used with these alkenic nucleophiles include Chloromethyl Methyl Ether, HC(OMe)3, and Acetyl Chloride... 

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