Epoxides Esters

Although hydrogenation of A-benzylideneaniline in the presence of 11 afforded the corresponding product (eq. 1 in Scheme 11), the a,(3-unsaturated ketone was converted into a mixture of unsaturated and saturated alcohols in the 42 56 ratio (eq. 2 in Scheme 11). Several substrates (nitrile derivatives, epoxides, esters, internal alkynes, and terminal alkenes), which are shown in Fig. 4, are not hydrogenated in this catalytic system. 

Several aspects are particularly noteworthy. Good chemoselectivity is noted in the compatibility with epoxides, esters, olefins, and alcohols. Entries 44 and 45 demonstrate the chemoselectivity between an unsaturated and saturated ketone. 

Sodium borohydride is a much milder reducing agent than lithium aluminium hydride and like the latter is used for the reduction of carbonyl compounds like aldehydes and ketones. However, under normal conditions it does not readily reduce epoxides, esters, lactones, acids, nitriles or nitro groups. 

More recent developments in the field of the Pirkle-type CSPs are the mixed r-donor/ r-acceptor phases such as the Whelk-Of and the Whelk-02 phases.The Whelk-Of is useful for the separation of underiva-tized enantiomers from a number of families, including amides, epoxides, esters, ureas, carbamates, ethers, aziridines, phosphonates, aldehydes, ketones, carboxylic acids, alcohols and non-steroidal anti-inflammatory drugs.It has been used for the separation of warfarin, aryl-amides,aryl-epoxides and aryl-sulphoxides. The phase has broader applicability than the original Pirkle phases. The broad versatility observed on this phase compares with the polysaccharide-derived CSPs... 

Aliphatic alcohols are not reducible under electrochemical conditions. Conversion to a suitable anionic leaving group however does allow carbon-oxygen bond cleavage. Thus, methanesulphonates are reduced at a lead electrode under constent current conditions and this affords an overall tw o step process for the conversion of alcohols to alkanes [9].Deoxygenation of alcohols by this route has been applied successMly in the presence of other functional groups which are difficult to reduce such as alkene, epoxide, ester and nitrile. Cyclopropanes are formed in 50-97 %... 

Epoxidation of the racemic adduct 188 with OT-chloroperbenzoic acid (MCPBA) in CH2CI2 proceeded slowly to give the epoxide 189 which further oxidized, usually in acid medium, to ( )rra r-4,5-diol 190 as a diastereoisomeric mixture (70 30) <1997T13783>. Epoxidation of substituted oxazines 28 and 191 with MCPBA led to epoxide esters... 

The order of reactivities of various functional groups determined under standard conditions (using externally generated diborane, and tetrahydrofuran as solvent) is acid > alkene > ketone > nitrile > epoxide > ester > acid chloride.33 Acids, aldehydes, ketones, epoxides, nitriles, lactones and azo compounds are reduced rapidly, esters more slowly and chloral, acid chlorides and nitro compounds are inert. Double bonds undergo the hydroboration reaction,25 nitriles and azo compounds are reduced to amines, and the remaining groups to alcohols. Ketones can be reduced selectively in the presence of epoxides. Contrary to the order of reactivities given above, it has been claimed that nitriles are reduced more rapidly than ketones.223... 

Alcohol, Ether, Epoxide, Ester, Sulfide, Sulfone,... 

Specific acid catalysis (SAC) involves a rapid protonation of the compound followed by the slow step, which is accelerated in comparison with the uncatalysed reaction because of the greater reactivity of the protonated compound. You have just seen an example with an epoxide. Ester hydrolysis (or formation) is another. Water attacks esters veiy slowly it attacks protonated esters much more quickly. This is just the ordinary mechanism for acid-catalysed ester hydrolysis (or formation) given in Chapter 12. 

Nucleophilic Substitution Solvolytic and Elimination Reactions Ring-opening of Epoxides Esters, Ethers, and Related Derivatives of Alcohols Oxidation Reduction Miscellaneous... 

Epoxides have received increased attention in view of their interest both as end-products and as chemical intermediates. Epoxidized oils—mainly high-oleic sunflower oil—and their ester derivatives have found important applications as plasticizers and additives for polyvinyl chloride (PVC). Epoxidized esters produced from high-oleic sunflower methyl esters have hydroxyl values of 0, oxirane values of 5.2/ 4.5, and iodine values of 1.7/1.5 (127)... 

TPAP tolerates a wide variety of functional groups, including double bonds, enones, halides, epoxides, esters, and lactones. Protecting groups, such as MEM, trityl, silyl and benzyl ethers, THP, and acetals, are not affected. 

Lithium tri-t-butoxyaluminum hydride readily reduces aldehydes and ketones to the corresponding alcohols and reduces acid chlorides to aldehydes. Epoxides, esters, carboxylic acids, tert-amides, and nitriles are not, or only slowly, reduced. Thus, the reagent may be used for chemoselective reductions. ... 

In principle, any functionality capable of producing a carbenium ion under strongly acidic conditions will be able to participate in a Ritter-type reaction. Such classes of compounds include alcohols, aldehydes, alkanes, alkenes, alkyl halides, carboxylic acids, dienes, epoxides, esters, ethers, glycols, ketones, IV-methylolamides and oximes. Consequently, an enormous number of examples is reported and only a representative selection can be presented here. A comprehensive listing of examples reported up to 1966 is provided in the review by Krimen and Cota. ... 

NaBHi is a much milder reducing agent than LiAlH,. In hydroxylic solvents it reduces aldehydes and ketones rapidly at 25° but is essentially inert to other functional groups epoxides, esters, lactones, carboxylic acids and salts, nitrile and nitro groups. Acid chlorides are reduced rapidly in diglyme or dioxane. 

There is thus considerable scope for further examination of the reactions of phosgene with a wide variety of alcohols, diols, aldehydes, hydroxy-aldehydes, epoxides, esters, acids and anhydrides to produce the desired range of chlorinated organic materials. The analogous reactions of COFj and of COCIF will be described in Chapters 13 and 16, respectively. 

A large number of cyclopropanes have been synthesized from cyclopropyl sulfones, cyclopropyl sulfoxides and cyclopropyl sulfides by taking advantage of the acidity of the cyclopropyl proton a to the C-S bond. Butyllithium is used almost exclusively as the base. The cyclopropyl anions obtained are capable of reacting with alkyl halides, aldehydes, enamines, epoxides, esters. 

One of die most popular reactions in organic chemistry is dissolving metal reductions [1-3], Two systems are frequently used - sodium dissolved in ammonia with alcohol and lithium dissolved in alkylamines [4]. Although calcium is seldom used, it has been successfully applied to the reduction of a variety of compounds and functional groups [5], including aromatic hydrocarbons, carbon-carbon double and triple bonds, benzyl ethers, allyl ethers, epoxides, esters, aliphatic nitriles, dithianes, als well as thiophenyl and sulfonyl groups. 

Sodium and potassium borohydrides are above all used for reducing aldehydes and ketones (Sections 3.2.1, 3.2.2) a,p-ethylenic ketones are converted to mixtures [W3]. In alcoholic media or THF, they leave epoxides, esters and lactones, acids, amides, and most nitro compounds unreacted, but they reduce halides (Section 2.1), anhydrides (Section 3.2.6), quartemary pyridinium salts (Section 3.3), double bonds conjugated to two electron-withdrawing groups (Sections 3.2.9, 4.4), and CUPd... 

LiBH4 is soluble in alcohols and ethers [BK5, PSl, W3]. In an diethylether or THF medium, the Li+ cation is a stronger Lewis acid than Na+, which gives to this reagent an increased reducing power. Epoxides, esters, and lactones may then be reduced (Sections 2.3, 3.2.5), while amides and nitriles remain intact unless one adds hot DME or methanol. Under these conditions, tertiary amides give alcohols (Section 3.2.8) and nitriles give amines (Section 4.3). 

Reductive desulfurization of the dithioketals 5.14 and 5.15 is performed under the same conditions as for thioethers [G02] LAH in the presence of copper salts or borohydrides in the presence of nickel salts (Figure 5.8). The deoxygenation of tertiary amine-oxides such as 5.16 and 5.17 can be performed with borohydride exchange resin-copper sulfate in methanol at room temperature or under reflux. This reaction tolerates other functional groups such as carbon-carbon double bonds, chlorides, epoxides, esters, amides, nitriles, sulfoxides, and sulfones [SA4] (Figure 5.8). 

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