Enol ethers addition reactions

Several azides are observed to undergo addition to enamines (Scheme 14) and to enol ethers. The reaction conditions are mild Typically, the reagents are heated together in chloroform for 1-2 hours. 

For example, 1-donor-substituted cyclopropancmethanols may be efficiently produced by cyclopropanation of suitably substituted enol ethers, by reaction of 1-donor-substituted 1-lithio-cyclopropanes with carbonyl compounds, or by addition of carbon nucleophiles to 1-donor-substituted cyclopropanecarbaldehydes. Oxaspiropentanes, important precursors of cyclobutanones, may as easily be obtained by epoxidation of methylenecyclopropanes, or by reaction of carbonyl compounds with diphenylsulfonium cyclopropanide and l-bromo-1-lithiocyclopropanes, respectively. Moreover, as the stereochemistry of most rearrangements may be efficiently controlled, asymmetric syntheses begin to appear. 

Copper complexes derived from bis(-2,6-dichlorophenyle-dene)-( 15,25)-1,2-diaminocyclohexane (11) catalyze various reactions such as Diels-Alder reaction, aziridination (eq 20), cyclopropanation, and silyl enol ether addition to pyruvate esters. Although the scope of these reactions may be sometimes limited, enantioselectivities are generally high. The same complex (with copper(I) salts) catalyzes the asymmetric insertion of silicon- hydrogen bond into carbenoids. ... 

At first glance, reaction (224) seems to be similar to the enol ether additions , although one could well have expected oxygen transfer processes, e.g. equation (110) or (126) to take precedence. That is, the a -product of cycloaddition or the corresponding acyclic zwitterion is unexpected, but each is readily related to the final... 

The coupling of an allyl or acyl moiety onto carbon atoms is achieved by anodic oxidation of a-heteroatom substituted organostannanes or Oj -acetals in the presence of allylsilanes or silyl enol ethers. The reaction probably involves carbocations as intermediates that undergo electrophilic addition to the double bond [245c]. 

Taking into account the competitive hydrolysis of the silyl enol ether, this reaction is remarkable. The method was shown to be general and was extended to a variety of aldehydes and several a,j9-unsaturated carbonyl compounds giving uniformly 1,4-addition with aldehydes and a mixture of 1,4- and 1,2-adducts in the case of ketones [187]. Later, this aqueous version of the Mukaiya-ma reaction was shown to give near quantitative yields in the presence of a water-tolerant Lewis acid such as ytterbium triflate [188]. Keeping with the same concept,copper(II) triflate [189],indium(III) trichloride [190],tris(pentafluoro-phenyl)boron [191] and scandium(III) triflate in the presence of a surfactant [192] have proved to be active catalysts. 

In order to reverse the diastereoselectivity in the aldol reaction, the Lewis acid-catalyzed silyl enol ether addition (73) (Mukaiyama aldol reaction) was examined. Since the Mukaiyama aldol reaction is assumed to be proceeded via an acyclic transition state, a chelation controled aldol reaction of the a-alkoxy aldehyde should be possible (74). In the presence of TiCU, the silyl enol ether derived from 14 was reacted with aldehyde 13, followed by desilylation to afford the desired anti-Felkin product 122a as a single adduct (Scheme 21). Based on precedents for chelation-controlled Mukaiyama aldol reaction (74), the exceptional high selectivity in this reaction would be accounted for by chelation of TiCl4 with the C23-methoxy group of the aldehyde 13 (eq. 13). On the other hand, when the lithium enolate derived from 14 was treated with the aldehyde 13, followed by desilylation, it gave a 1 4 ratio of the two epimers in favour of the undesired (22S)-aldol product... 

Most of the 1,2,3-triazolines bearing a functional group are amines (12.1-1) or ethers (12.1-2). These two types are most often prepared by azide addition to enamines (Eq. 1) or enol ethers (Eq. 2). Such reactions have been shown to provide excellent yields under a variety of circumstances by Huisgen and his collaborators. They have also demonstrated the conversion of 12.1-1 and 12.1-2 to the corresponding 1,2,3-triazoles in high yield. In a subsequent paper this research group reported on the stereochemistry of the enol ether addition (Eqs. 3,4). 

Most examples of the Bradsher cycloaddition reaction have utilized fused polycyclic aromatics as the cationic aza-diene fragment. Falck and co-workers have reported that one can carry out this reaction using monocyclic quaternary aza-aromatics. The application of this methodology was illustrated using the A -(2,4-dinitrophenyl) salt of A, A -diethylnicotin-amide 3 and ethyl nicotinate 4 in conjunction with enol ethers. The reaction proceeded at room temperature to generate adducts 5. This was the result of the exo-addition at the C2-C5 positions of the pyridyl ring. The resultant iminium ion was then trapped by the methanolic solvent. 

Following this route, the authors achieved the synthesis of 10 analogues of compound 58, in a high global yield, where the crucial step of this total synthesis was the efficient catalytic enantio-, regio-, EIZ-, and diastereoselective three-component inverse electron demand hetero-[4+2] cycloaddition/allylboration sequence. This key process provides a rare example of an enantioselective hetero-Diels-Alder reaction involving acyclic 2-substituted enol ethers. Additionally, these compounds were evaluated for antimicrobial activity, and two of them showed more activity than the original thiomarinol H. 

Enol ethers are more reactive toward formaldehyde and MesAl than simple alkenes. Reaction with dihydropyran gives a 75% yield of a 92 8 mixture of 33 and 34 (See Figure 10). The major product is again formed by cis addition of hydroxymethyl and methyl groups. Quite different results are obtained with acyclic enol ethers. 20 Reaction of ethyl propenyl ether, as a 78 22 cis-trans mixture, with 2 equivalents of paraformaldehyde and 2 equivalents of MesAl at 0 in CH2CI2 gives a 65% yield of an 18 1 mixture of threo- and c yr/ir< -3-ethoxy-2-meAyl-l-butanol (37 and 38). Identical results are obtained from either pure stereoisomer of ethyl propenyl ether. 

According to Mayr s nucleophilicity scale (N), silyl enol ethers derived from aldehydes (N > 3.5) and ketones (N > 5) and, in particular, silyl ketene acetals (N > 8) [70] represent powerful nucleophihc reagents. Indeed, the aldol-type addition of trichlorosilyl enol ethers 76a-d to aldehydes 1 proceeds readily at room temperature without a catalyst (Scheme 15.14), which is in contrast with the lack of reactivity of allyl silanes in the absence of a catalyst. As a result, the reaction exhibits simple first-order kinetics in each component [71, 72]. Nevertheless, the reaction is substantially accelerated by Lewis bases, which provides a sohd ground for the development of an asymmetric variant The required trichlorosilyl enol ethers 76 can be generated in various ways, for example (i) from the corresponding trimethylsilyl enol ethers on reaction with SiCLt, catalyzed by (AcO)2Hg,... 

Stannyl enol ethers have an adequate reactivity toward aldehydes to give aldol adducts without any additive or catalyst (Scheme 3-194). In order to enhance the reactivity and selectivity of stannyl enol ethers, a variety of catalysts like Lewis acids, Lewis bases, and radical initiators is applied to this reaction. In contrast to silyl enol ethers, the reaction proceeds through acyclic or cyclic transition states, depending on the reaction conditions. 

A useful catalyst for asymmetric aldol additions is prepared in situ from mono-0> 2,6-diisopropoxybenzoyl)tartaric acid and BH3 -THF complex in propionitrile solution at 0 C. Aldol reactions of ketone enol silyl ethers with aldehydes were promoted by 20 mol % of this catalyst solution. The relative stereochemistry of the major adducts was assigned as Fischer- /ir o, and predominant /i -face attack of enol ethers at the aldehyde carbonyl carbon atom was found with the (/ ,/ ) nantiomer of the tartaric acid catalyst (K. Furuta, 1991). 

Although ethereal solutions of methyl lithium may be prepared by the reaction of lithium wire with either methyl iodide or methyl bromide in ether solution, the molar equivalent of lithium iodide or lithium bromide formed in these reactions remains in solution and forms, in part, a complex with the methyllithium. Certain of the ethereal solutions of methyl 1ithium currently marketed by several suppliers including Alfa Products, Morton/Thiokol, Inc., Aldrich Chemical Company, and Lithium Corporation of America, Inc., have been prepared from methyl bromide and contain a full molar equivalent of lithium bromide. In several applications such as the use of methyllithium to prepare lithium dimethyl cuprate or the use of methyllithium in 1,2-dimethyoxyethane to prepare lithium enolates from enol acetates or triraethyl silyl enol ethers, the presence of this lithium salt interferes with the titration and use of methyllithium. There is also evidence which indicates that the stereochemistry observed during addition of methyllithium to carbonyl compounds may be influenced significantly by the presence of a lithium salt in the reaction solution. For these reasons it is often desirable to have ethereal solutions... 

The in situ cyanosilylation of p-an1saldehyde is only one example of the reaction which can be applied to aldehydes and ketones in general. - The simplicity of this one-pot procedure coupled with the use of inexpensive reagents are important advantages over previous methods. The silylated cyanohydrins shown in the Table were prepared under conditions similar to those described here. Enolizable ketones and aldehydes have a tendency to produce silyl enol ethers as by-products in addition to the desired cyanohydrins. The... 

The general reaction procedure and apparatus used are exactly as described in Procedure 2. Ammonia (465 ml) is distilled into a 2-liter reaction flask and to this is added 165mlofisopropylalcoholandasolutionof30g(0.195 mole) of 17/ -estradiol 3-methyl ether (mp 118.5-120°) in 180 ml of tetrahydrofuran. The steroid is only partially soluble in the mixture. A 5 g portion of sodium (26 g, 1.13 g-atoms total) is added to the stirred mixture and the solid dissolves in the light blue solution within several min. As additional metal is added, the mixture becomes dark blue and a solid (matted needles) separates. Stirring is inefficient for a few minutes until the mass of crystals breaks down. All of the sodium is consumed after 1 hr and 120 ml of methanol is then added to the mixture with care. The product is isolated as in Procedure 4h 2. After being air-dried, the solid weighs 32.5 g (ca. 100% for a monohydrate). A sample of the material is dried for analysis and analyzed as described in Procedure 2 enol ether, 91% unreduced aromatics, 0.3%. The crude product may be crystallized from acetone-water or preferably from hexane. 

Cross-conjugated dienones are quite inert to nucleophilic reactions at C-3, and the susceptibility of these systems to dienone-phenol rearrangement precludes the use of strong acid conditions. In spite of previous statements, A " -3-ketones do not form ketals, thioketals or enamines, and therefore no convenient protecting groups are available for this chromophore. Enol ethers are not formed by the orthoformate procedure, but preparation of A -trienol ethers from A -3-ketones has been claimed. Another route to A -trien-3-ol ethers involves conjugate addition of alcohol, enol etherification and then alcohol removal from la-alkoxy compounds. 

The photochemical addition of trifiuoroiodomethane to unsaturated systems has been thoroughly investigated by Haszeldine. Little use has been made of this reaction in the steroid field. Irradiation of the enol ether (64) in trifiuoroiodomethane containing pyridine in a quartz vessel furnishes in 60 %... 

Selective fluonnation in polar solvents has proved commercially successful in the synthesis of 5 fluorouracil and its pyrimidine relatives, an extensive subject that will be discussed in another section Selective fluonnation of enolates [47], enols [48], and silyl enol ethers [49] resulted in preparation of a/phn-fluoro ketones, fieto-diketones, heta-ketoesters, and aldehydes The reactions of fluorine with these functionalities is most probably an addition to the ene followed by elimination of fluonde ion or hydrogen fluoride rather than a simple substitution In a similar vein, selective fluonnation of pyridmes to give 2-fluoropyridines was shown to proceed through pyridine difluondes [50]... 

A fluormated enol ether formed by the reaction of sodium ethoxide with chlorotnfluoroethylene is much less reactive than the starting fluoroolefin To replace the second fluorine atom, it is necessary to reflux the reaction mixture. The nucleophilic substitution proceeds by the addition-elimination mechanism [30] (equation 26). 

Because of thetr electron deficient nature, fluoroolefms are often nucleophihcally attacked by alcohols and alkoxides Ethers are commonly produced by these addition and addition-elimination reactions The wide availability of alcohols and fliioroolefins has established the generality of the nucleophilic addition reactions The mechanism of the addition reaction is generally believed to proceed by attack at a vinylic carbon to produce an intermediate fluorocarbanion as the rate-determining slow step The intermediate carbanion may react with a proton source to yield the saturated addition product Alternatively, the intermediate carbanion may, by elimination of P-halogen, lead to an unsaturated ether, often an enol or vinylic ether These addition and addition-elimination reactions have been previously reviewed [1, 2] The intermediate carbanions resulting from nucleophilic attack on fluoroolefins have also been trapped in situ with carbon dioxide, carbonates, and esters of fluorinated acids [3, 4, 5] (equations 1 and 2)... 

Reaction of estrone methyl ether with methyl Grignard reagent followed by Birch reduction and hydrolysis of the intermediate enol ether affords the prototype orally active androgen in the 19-nor series, normethandrolone (69). ° (Note that here again the addition of the methyl group proceeded stereoselectively by approach from the least hindered side.) The preparation of the ethyl homolog starts by catalytic reduction of mestranol treatment of the intermediate, 70, under the conditions of the Birch reduction and subsequent hydrolysis of the intermediate enol ether yields norethandrolone (71). ... 

Though dental afflictions constitute a very significant disease entity, these have received relatively little attention from medicinal chemists. (The fluoride toothpastes may form an important exception.) This therapeutic target Is, however, sufficiently Important to be the focus of at least some research. A highly functionalized piperazine derivative that has come out of such work shows prophylactic activity against dental caries. Condensation of the enol ether 1 of thiourea with ji-pentylisocyanate gives the addition product 1J. Reaction of this with diamine 78, derived from piperazine, leads to substitution of the methylthio moiety by the primary amine, in all likelihood by an addition-elimination sequence. There is thus obtained ipexidine (79). ... 

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