Enolates oxidations, palladium acetate

Enantioselective deprotonation can also be successfully extended to 4,4-disubstituted cyclohexanones. 4-Methyl-4-phenylcyclohexanone (3) gives, upon reaction with various chiral lithium amides in THF under internal quenching with chlorotrimethylsilane, the silyl enol ether 4 having a quaternary stereogenic carbon atom. Not surprisingly, enantioselectivities are lower than in the case of 4-tm-butylcyclohexanone. Oxidation of 4 with palladium acetate furnishes the a./i-unsaturated ketone 5 whose ee value can be determined by HPLC using the chiral column Chiralcel OJ (Diacel Chemical Industries, Ltd.)59c... 

In contrast, the closely related palladium acetate-promoted intramolecular alkylation of alkenes by tri-methylsilyl enol ethers (Scheme 4)6,7 has been used to synthesize a large number of bridged carbocyclic systems (Table 1). In principle, this process should be capable of being made catalytic in palladium(II), since silyl enol ethers are stable to a range of oxidants used to carry the Pd° -> Pd11 redox chemistry required for catalysis. In practice, catalytically efficient conditions have not yet been developed, and the reaction is usually carried out using a full equivalent of palladium(II) acetate. This chemistry has been used in the synthesis of quadrone (equation 2).8 With the more electrophilic palladium(II) trifluoroace-tate, methyl enol ethers underwent this cyclization process (equation 3).9... 

With this bicyclic intermediate available in sizeable amounts, ready advance to 111 could be conveniently accomplished prior to annulation of the second five-membered ring (Scheme XIV). 1,3-Carbonyl transposition was realized by complete eradication of the original carbonyl by Ireland s method [60] followed by allylic oxidation. Application of the Piers cyclopentannulation protocol [61] to 111 made 113 conveniently available. Introduction of a methyl group into ring B was brought about by treatment of the kinetically derived enol triflate [62] with lithium dimethylcuprate [63], Hydrolysis of 114 gave the dienone, which was directly transformed into 115 by oxidation of its silyl enol ether with palladium acetate in acetonitrile [64],... 

The first case of a tetrahedral palladium(O) tetraolefin complex (more exactly, Pd(diolefin)2) has been isolated in the course of the Saegusa oxidation of a silyl enol ether, aimed at the synthesis of alkaloids. Palladium acetate was used as oxidant in this reaction, and a brown compound separated from the solution, which was characterized by X-ray diffraction as 16 (Equation (5)). It decomposed upon heating to give the expected product of oxidation. This supports the accepted mechanism of Saegusa oxidation. ... 

Addition of tributylstannyl-lithium to crotonaldehyde and protection of the resulting alcohol with chloromethyl methyl ether gives the stannane (192), which reacts with both alkyl and aryl aldehydes RCHO to form specifically the t/rr o-hydroxy-enol ethers (193). These latter compounds have been used to prepare tra/i5-4,5-disubstituted butyrolactones by hydrolysis and subsequent oxidation. Palladium-catalysed carbonylation of RX in the presence of organotin species constitutes a useful synthesis of unsymmetrical ketones, and in the example reported this year RX is an arenediazonium salt. The reaction, which is basically an aromatic acylation, proceeds in good to excellent yield. Another Pd-catalysed reaction of aromatics, this time aryl bromides, is their reaction with acetonyltributyltin (194), prepared from methoxytributyltin and isopropenyl acetate, to give the arylacetones (195). ... 

The protection of the hemiacetal hydroxyl in step C is followed by a purification of the dominant stereoisomer. The C-6 methyl group is introduced in step C by conjugate addition of dimethylcuprate. The enolate is trapped as the silyl enol ether and oxidized to the enone by palladium acetate. The enone from step D is then subjected to a Wittig reaction. As in several of the other syntheses, the hydrogenation in step E is used to establish the configuration at C-4 and C-6. 

Note. Enol acetates undergo a similar oxidation, using the palladium species and tributyltin methoxide as dual catalysts. 

The oxidation of silyl enol ethers 111 with palladium(n) acetate is a convenient nnethod for the preparation of synthetically useful 2,6-disubstituted 2,3-dihydro-4-pyridones 112 <95TL(36)9449>. 

C(l) in 355 is in the oxidation state of an aldehyde or a ketone in 1-alkylated products. The necessary solvolytic attack of the enol carbamate double bond requires substoichio-metric amounts of a catalyst such as mercuric acetate or palladium chloride and one equivalent of acid (e.g. methanesulphonic acid) for binding the liberated diisopropylamine. 

The industrial synthesis of vinyl acetate [14] via palladium-catalyzed oxidative coupling of acetic acid and ethene using direct 02 reoxidation has already been mentioned (Scheme 3, d). Some NaOAc is required in the reaction medium, and catalysis by Pd clusters, as alternative to Pd(II) salts, was proposed to proceed with altered reaction characteristics [14]. Similarly, the alkenyl ester 37 (Table 5) containing an isolated vinyl group yields the expected enol acetate 38 [55] whereas allylphenol 39 cyclizes to benzofuran 40 with double bond isomerization [56]. 

Three new chirality centers are formed with high enantio- and complete diastereoselectivity in the course of the reaction of the enol triflate 37 to the bicyclo [3.3.0]octane derivative 38 (Scheme 11) [15]. In this transformation, the intermediate 39, formed by oxidative addition, leads to the cationic palladium-7r-allyl complex 40, which is finally converted to the isolated product 38 by regio- and diastereoselective nucleophilic addition of an acetate anion. The bicyclic product 38 is of interest as a building block for the synthesis of capnellene sesquiterpenes. 

Catalytic hydrogenation of dihydrothebaine methine [ix] with colloidal palladium in dilute acetic acid causes saturation of the 9 10 double bond, scission of the cyclic ether, and hydrolysis of the enol ether group giving dihydrothebainone dihydromethine [xvm] [3], and this is the most satisfactory method of preparing the latter. The dihydromethine [x] may be reduced to [xvm] under the same conditions [3]. [xvm] can also be prepared by hydrolysis of dihydrothebaine dihydromethine [x] to dihydrocodeinone dihydromethine [xix] (also accessible by the chromic acid oxidation of a-tetrahydrocodeimethine [xx] [3]) followed by aluminium amalgam reduction [3]. 

A wide variety of nucleophiles add to an -rf-allyl ligand. Desirable nucleophiles typically include stabilized carbanions such as CH(COOR)2 or 1° and II0 amines. Unstabilized nucleophiles such as MeMgBr or MeLi often attack the metal first and then combine with the n-allyl by reductive elimination. The Tsuji-Trost reaction, which is typified by the addition of stabilized carbanions to T 3—allyl ligands complexed to palladium followed by loss of the resulting substituted alk-ene, comprises an extremely useful method of constructing new C-C bonds, and many applications of this reaction have appeared in the literature.61 Equation 8.43 illustrates an example of a Pd-catalyzed addition of a stabilized enolate to an allyl acetate.62 The initial step in the catalytic cycle is oxidative addition of the allyl acetate to the Pd(0) complex, followed by nq1 to nq3—allyl isomerization, and then attack by the nucleophile to a terminal position of the T 3—allyl ligand. We will discuss the Tsuji-Trost reaction, especially in regard to its utility in chiral synthesis,63 more extensively in Chapter 12. 

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