Enol ethers tetrasubstituted

Carbon-carbon double bonds in unconjugated alkenes usually exhibit weak to moderate absorptions due to C=C stretehing in the range 1660-1640 em V Disubstituted, trisubstituted and tetrasubstituted alkenes usually absorb near 1670 cm The more polar carbon-carbon double bonds in enol ethers and enones usually absorb strongly between 1600 and 1700 crn k Alkenes conjugated with an aromatic ring absorb strongly near 1625 crn k... 

Trimethyl(prop-l-en-2-yloxy)silane afforded (3-amino ketone 24u in good yield (Table 5, entry 10). Silyl enol ethers derived from 3-pentanone and cyclopentanone smoothly afforded (3-amino ketones 24v and 24w, respectively (Table 5, entries 11 and 12). Tetrasubstituted silyl enol ethers readily produced the expected products 24x and 24g (Table 5, entries 13 and 14). 

Aldol reactions with enol silyl ethers5 (Mukaiyama reaction). Although TiCl4 is commonly used to effect aldol reactions with enol silyl ethers, BF3 etherate is more effective for aldol reactions of tetrasubstituted enol ethers such as (Z)- and (E)-3-methyl-2 (trimethylsilyloxy)-2-pentene (1). These enolates react with aldehydes in the same sense as the corresponding metal enolates, but with generally higher levels... 

Tetrasubstituted pyrroles could be obtained by skeletal rearrangement of 1,3-oxazolidines, a reaction that is substantially accelerated by microwave irradiation. Dielectric heating of a 1,3-oxazolidine 7, absorbed on silica gel (1 g silica gel/mmol) for 5 min in a household MW oven (900 W power) cleanly afforded the 1,2,3,4-tetrasubstituted pyrrole 8 in 78% yield, thus reducing the reaction time from hours to minutes (Scheme 5) [24], 1,3-Oxazolidines are accessible in one-pot, two-step, solvent-free domino processes (see also Sect. 2.6). The first domino process, a multi-component reaction (MCR) between 2 equivalents of alkyl propiolate and 1 equivalent of aldehyde furnished enol ethers 9 (Scheme 5). Subsequent microwave-accelerated solvent-free reactions of enol ethers 9 with primary amines on silica support afforded intermediate 1,3-oxazolidines, which in situ rearranged to the tetrasubstituted pyrroles (2nd domino process). Performed in a one-pot format, these... 

Polysubstituted 1,3-oxazolidines were prepared in a one-pot diversity oriented four-component reaction (4-MCR), comprising two linked domino processes. Thus, domino synthesis of enol ethers 9 was followed by a sequential amine addition-cyclization sequence [74]. While strong microwave irradiation (900 W) of silica-gel absorbed conjugated alkynoates 9 and amines afforded tetrasubstituted pyrroles (via the skeletal rearrangement of 1,3-oxazolidines, see Sect. 2.1 and Scheme 5) [24], the use of milder microwave conditions (160 W power, 90 min) furnished 1,3-oxazolidines. Under these mild conditions the 1,3-oxazolidines did not rearrange to pyrroles and with respect to diastereoselectivity, the 1,3-oxazolidines were obtained as mixtures of syn/anti isomers. Overall, the formation of one C-C bond, one C-0 bond, two C - N bonds and a ring in this MCR required less than 3 hours and utilized simple and commercially available reagents (Scheme 26). 

Epoxide -> aliylic alcohol. Treatment of an oxirane with equimolar amounts of 1 and DBU in an aromatic solvent affords aliylic trimethylsilyl ethers in moderate yield. 2,2-Di-, tri-, and tetrasubstituted oxiranes, as well as oxides of cycloalkenes, react at 23° or below. 2,3-Di- and monosubstituted oxiranes do not react at this temperature these species react with 1 and DBU at 70-80° to give trimethylsilyl enol ethers. The reaction of epoxycyclooctane gives a product of transannular cyclization. In the case of epoxycyclohexane, the intermediate 2 has been isolated. 

The reaction is effective with electron-rich carbonyls such as trimethylsilyl esters and thioesters, as Table 20 indicates. Lactones ate substrates for alkylidenation however, hydroxy ketones are formed as side products, and yields are lower than with alkyl esters. Amides are also effective, but form the ( )-isomer predominantly. This method has been applied to the synthesis of precursors to spiroacetals (499) by Kocienski (equation 115). ° The reaction was found to be compatible with THP-protected hy- oxy groups, aromatic and branched substituents, and alkene functionality, although complex substitution leads to varying rates of reaction for alkylidenation. Kocienski and coworkers found the intramolecular reaction to be problematic. As with the CrCb chemistry, this reaction cannot be used with a disubstituted dibromoalkane to form the tetrasubstituted enol ether. Attempts were made to apply this reaction to alkene formation by reaction with aldehydes and ketones, but unfortunately the (Z) ( )-ratio of the alkenes formed is virtu ly 1 1. ... 

Tetrasubstituted enol ethers such as (5.44) undergo dihydroxylation using PYR ligands with good ee, but for other tetrasubstituted olefins, enantioselectivities tend to be reduced and isolated yields also suffer. 

A stereoselective approach to tetrasubstituted (Z)-/3-hydroxy-o -TMS (trimethylsi-lyl)enol ethers occurs via a sequential addition/[ 1,2]-Brook rearrangement/epoxide-opening process of TMS-substituted oxiranyl anions with acylsilanes (Scheme 46). ... 

A stereoselective approach to tetrasubstituted (ii)-/ -hydroxy silyl enol ethers from aryl-substituted oxiranyl anions and acylsilanes is reported to occur via a sequential addition - [l,2]-Brook rearrangement - epoxide-opening (Scheme 87). ... 

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