Phenyl-substituted epoxides

In conclusion, the ability to abstract the -proton is correlated to its degree of substitution. However, substituents other than simple aUcyl groups may modify this facility of proton removal and influence the course of the -elimination. As anticipated, the presence on the adjacent carbon of the epoxide of an ally lie or benzylic group results in a dramatic enhancement of the -elimination rate and modifies its regioselectivity . As shown in Scheme 19, the rearrangement of the phenyl-substituted epoxide 34 is complete within a few minutes, whereas several hours are required in the case of the corresponding alkyl-substituted epoxide 35. 

It was found that the ring opening of phenyl-substituted epoxides, as well as of aliphatic epoxides, can be achieved in high yield in a regio- and stereoselective manner with a mixture of 1 3 of diisopropylamine and hydrogen fluoride (diisopropylamine trishydrofluoride). d.s-... 

A summary of bimolecular rate constants for the acid-catalyzed hydrolysis of a series of alkyl-, vinyl- and phenyl-substituted epoxides is given in Table 1. Propylene oxide (7) is 6.6 times more reactive than ethylene oxide, and from a study of its reaction in H2018, it was shown that 70% of the glycol product results from addition of solvent to the secondary carbon and 30% from addition of solvent to the primary carbon. The reactivity per primary carbon of ethylene oxide is one-half of the observed reactivity of ethylene oxide, and thus the introduction of a methyl group on ethylene oxide results in an increase in reactivity at the primary carbon by a factor of 4 and an increase in reactivity at the secondary carbon by a factor of 9. These results are consistent with A-2 mechanisms for the acid-catalyzed hydrolyses of ethylene oxide and propylene oxide, in which some amount of positive charge generated on carbon at the transition state is stabilized by a methyl group. 

Regioselective reduction of terminal epoxides.2 By appropriate choice of i-Bu2 AIH or 1-BU3AI, terminal epoxides can be reduced with marked regioselcctivity to the primary or the secondary alcohol. Alkyl-substituted epoxides are reduced by f-Bu2AIH mainly to a secondary alcohol, whereas use of i-BujAl favors rcduclion to the primary alcohol. This regioselcctivity is reversed in the case silyl-substitutcd epoxides. Phenyl-substituted epoxides are reduced by i-Bu3AI mainly to primary alcohols. Reduction of these epoxides to secondary alcohols is best effected with LiAIH4 in THF. 

Murphy and coworkers have also reported rearrangement reactions of azido-tethered epoxides in which the azide tether was attached directly to a phenyl-substituted epoxide. Thus, when they treated epoxide 36 with SnCLt at 0°C in THE, ketone 37 was isolated... 

Insertion of phenyl, trimethylsilyl, and nitrile-stabilized metalated epoxides into zircona-cyclcs gives the product 160, generally in good yield (Scheme 3.37). With trimethylsilyl-substituted epoxides, the insertion/elimination has been shown to be stereospecific, whereas with nitrile-substituted epoxides it is not, presumably due to isomerization of the lithiated epoxide prior to insertion [86]. With lithiated trimethylsilyl-substituted epoxides, up to 25 % of a double insertion product, e. g. 161, is formed in the reaction with zirconacyclopentanes. Surprisingly, the ratio of mono- to bis-inserted products is little affected by the quantity of the carbenoid used. In the case of insertion of trimethylsilyl-substituted epoxides into zirconacydopentenes, no double insertion product is formed, but product 162, derived from elimination of Me3SiO , is formed to an extent of up to 26%. 

Our syntheses of these new materials showed that both hydrogenation and epoxidation occurred exclusively from the exo face of both VN and < >VX. This is consistent with extensive literature precedent for a variety of reactions on norbornenyl double bonds (9). H1 NMR spectroscopy of these materials also revealed an interesting pattern. All phenyl substituted compounds with endo imide rings (< >VN, HYVN, VNE) evidenced signals due to one of the ten aromatic protons (five on each phenyl ring) being shifted to unusually high field (6.4 +. 16). This is consistent with a field effect on a proton of one of... 

Reaction of styrene oxide with tetraallyltin in the presence of Bi(OTf)3 (2 mol%) affords the corresponding l-phenyl-4-penten-2-ol (Fig. 5). In a similar fashion, various aryl substituted epoxides react smoothly with tetraallyltin to give the corresponding homoallylic alcohols. This method give generality as cycloalkyl oxiranes and sterically hindered ones give the corresponding homoallylic alcohols. 

Table 17) with two substituents in position C3 the oxygen transfer by the chiral hydroperoxides occurred from the same enantioface of the double bond, while epoxidation of the (ii)-phenyl-substituted substrates 142c,g,i resulted in the formation of the opposite epoxide enantiomer in excess. In 2000 Hamann and coworkers reported a new saturated protected carbohydrate hydroperoxide 69b , which showed high asymmetric induction in the vanadium-catalyzed epoxidation reaction of 3-methyl-2-buten-l-ol. The ee of 90% obtained was a milestone in the field of stereoselective oxygen transfer with optically active hydroperoxides. Unfortunately, the tertiary allylic alcohol 2-methyl-3-buten-2-ol was epoxidized with low enantioselectivity (ee 18%) with the same catalytic system . 

Epoxides also participate in the Ritter reaction with nitriles. An investigation of the ring opening of several alkyl-substituted glycidic esters and amides 181 showed that this transformation occurs with inversion and is completely regiospecific. ° Esters appeared to be somewhat more reactive than amides. However, phenyl-substituted glycidic esters and amides 184 are almost totally nonstereoselective. In addition, the oxazolines 186 are isolated in low yield due to the propensity of intermediate 185 to generate an aldehyde byproduct 187 (Scheme 8.53). 

Among the phenyl-substituted ethylenos convertible into epoxides l>y treatment with pwrbetixoie arid are styrene, [Pg.347]

The polymer-bound Mn and Cr complexes were used as catalysts for epoxidations of six phenyl-substituted olefins with m-CPBA/NMO and for dihydropyranone formation from the Danishefsky diene and aldehydes. There are several remarkable features of the novel immobilized salens ... 

InCh was found to catalyse the ring opening of substituted epoxides by alcohols giving /3-hydroxy ethers.25 Epoxides with a phenyl substituent reacted at the benzyl carbon in an, SN-1 -like. Sx2 reaction whereas those with an alkyl substituent reacted at the least substituted carbon by an S 2 mechanism. 

Analysis of the second-order rate constants for various methyl and phenyl substituted cyclopropenes shows effects similar to those observed with alkenes undergoing epoxidation, again in agreement with the intermediacy of the oxabicyclo[1.1.0]butane in cyclopropene oxidation 263 ... 

Table 16. Ring Opening of Phenyl-Substituted and Cyelie Aliphatic Epoxides with Alkylaminc Hydrofluorides ...

A highly effective catalytic method for alkynylation of epoxides has recently been reported this involves the chelation-controlled alkylation of hetero-substituted epoxides with Mc3A1 and alkynyllithiums via pentacoordinate organoaluminum complexes [82]. For instance, reaction of epoxy ether, (l-benzyloxy)-3-butene oxide (75) in toluene with PhC = CLi under the influence of catalytic MesAl (10 mol%) proceeded smoothly at 0 °C for 5 h to furnish the alkynylation product l-(benzyloxy)-6-phenylhex-5-yn-3-ol (76) in 76 % yield. The yield of the product was very low (3 %) without MeaAl as catalyst under similar conditions. This is the first catalytic procedure for amphiphilic alkylation of epoxides. The participation of pentacoordinate MesAl complexes of epoxy ethers of type 75 is emphasized by comparing the reactivity with the corresponding simple epoxide, 5-phenyl-l-pentene oxide (77), which was not susceptible to nucleophilic attack of PhC s CLi with catalytic Me3Al under similar conditions (Sch. 50). 

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