Silyl enol ethers palladium complexes

Silyl enol ethers and ketene acetals derived from ketones, aldehydes, esters and lactones are converted into the corresponding o/i-unsaturated derivatives on treatment with allyl carbonates in high yields in the catalytic presence of the palladium-bis(diphenylphosphino)ethane complex (32). A phosphinc-free catalyst gives higher selectivity in certain cases, such as those involving ketene acetals. Nitrile solvents, such as acetonitrile, are essential for success. 

Ceric ammonium nitrate promoted oxidative addition of silyl enol ethers to 1,3-butadiene affords 1 1 mixtures of 4-(/J-oxoalkyl)-substituted 3-nitroxy-l-butene and l-nitroxy-2-butene27. Palladium(0)-catalyzed alkylation of the nitroxy isomeric mixture takes place through a common ij3 palladium complex which undergoes nucleophilic attack almost exclusively at the less substituted allylic carbon. Thus, oxidative addition of the silyl enol ether of 1-indanone to 1,3-butadiene followed by palladium-catalyzed substitution with sodium dimethyl malonate afforded 42% of a 19 1 mixture of methyl ( )-2-(methoxycarbonyl)-6-(l-oxo-2-indanyl)-4-hexenoate (5) and methyl 2-(methoxycarbonyl)-4-(l-oxo-2-indanyl)-3-vinylbutanoate (6), respectively (equation 12). 

The mechanism of the trimethylsilyl enol ether cyclization may involve formation of a palladium enol-ate which adds to the double bond. However, another mechanism is also possible involving attack of a palladium(II)-alkene complex upon the silyl enol ether double bond. 

In 1998, a new type of Pd(II) binuclear complex was reported which was effective for Mannich reactions of an imine derived from glyoxylate and anisidine with silicon enolates [38,39]. In these reactions, use of solvents including a small amount of water was essential. It was shown that water played an important role in this system water not only activated the Pd(II) complex to generate a cation complex, but also cleaved the N-Pd bond of the intermediate to regenerate the chiral catalyst. This reaction reportedly proceeded via an optically active palladium enolate on the basis of NMR and ESIMS analyses. A unique binuclear palladium-sandwiched enolate was obtained in the reaction of the p-hydroxo palladium complex with the silyl enol ether [(Eq. (9)]. 

The imines 12 (X = 4-CH3-QH4-SO2 (Ts), Ar, C02R, COR, etc.) preformed or generated in situ from N,0- or N,N-acetals or hemiacetals are another important class of Mannich reagents frequently used for diastereo- and/or enantioselective aminoalkylation reactions catalyzed by chiral Lewis acids (usually copper or palladium BINAP complexes such as 13). Among other things excellent results were obtained in the aminoalkylation of silyl enol ethers or ketene acetals [24], A typical example is the synthesis of Mannich bases 14 depicted in Scheme 5 [24b], Because of their comparatively high electrophilicity imines 12 could even be used successfully for the asymmetric aminoalkylation of unactivated alkenes 15 (ene reactions, see Scheme 5) [24h, 25], and the diastereo- and/or enantioselective aminoalkyla-... 

Lewis acid catalysts activate the aldehyde by coordination to the carbonyl oxygen. Shibasaki et al. [13] were able to demon,strate that the activation of the enol ether is possible too. The reaction of the aldehyde 37 with the silyl enol ether 38 in the presence of the catalyst 39 proceeds with good, but still not excellent enantioselectivity to yield the aldol adduct 40. Only 5 mol % of the chiral palladium(II) complex 39 was used (Scheme 6a). Activation of the Pd(lI)-BINAP complex 39 by AgOTf is necessary. Therefore, addition of a small amount of water is important. 

The neutral palladium(II) compound 43 is transformed by addition of AgOTf into the cationic complex 44. In the presence of water an exchange of the triflate anion to hydroxide occurs (44 — 45). Finally, the palladium enolate 46 is formed from the palladium complex and the silyl enol ether. 

Cationic Pd complexes can be applied to the asymmetric aldol reaction. Shibasaki and coworkers reported that (/ )-BINAP PdCP, generated from a 1 1 mixture of (i )-BINAP PdCl2 and AgOTf in wet DMF, is an effective chiral catalyst for asymmetric aldol addition of silyl enol ethers to aldehydes [63]. For instance, treatment of trimethylsi-lyl enol ether of acetophenone 49 with benzaldehyde under the influence of 5 mol % of this catalyst affords the trimethylsilyl ether of aldol adduct 113 (87 % yield, 71 % ee) and desilylated product 114 (9 % yield, 73 % ee) as shown in Sch. 31. They later prepared chiral palladium diaquo complexes 115 and 116 from (7 )-BINAP PdCl2 and (i )-p-Tol-BINAP PdCl2, respectively, by reaction with 2 equiv. AgBF4 in wet acetone [64]. These complexes are tolerant of air and moisture, and afford similar reactivity and enantioselec-tivity in the aldol condensation of 49 and benzaldehyde. Sodeoka and coworkers have recently developed enantioselective Mannich-type reactions of silyl enol ethers with imi-nes catalyzed by binuclear -hydroxo palladium(II) complexes 117 and 118 derived from the diaquo complexes 115 and 116 [65]. These reactions are believed to proceed via a chiral palladium(fl) enolate. 

The experimental results and the known facility of O-desilylation of silyl enol ethers, such as 3-acetoxy-2-trimethylsiloxypropenes, under the given reaction conditions led Trost ° to suggest the intermediacy of an oxatrimethylenemethanepalladium complex 4 addition to the alkene at the less-substituted terminal carbon atom of 4 followed by tautomerism and ring closure would give rise to the cyclopropane. Since the palladium complex that is prepared from tris(dibenzylideneacetone)palladium(0)-chloroform complex [Pd2(dba)j CHClj] and triphen-ylphosphane also catalyzes the Brook rearrangement of an a-silyl ketone to a silyl enol ether, (2-oxo-3-silylpropyl) acetates can also serve as precursors of intermediate palladium complexes 4, and the same cyclopropanation reactions as with 3-acetoxy-2-trimethylsiloxypropenes can be carried out. 

If the electrophile is a vinyl triflate, it is essential to add LiCl to the reaction so that the chloride may displace triflate from the palladium o-complex. Transmetallation takes place with chloride on palladium but not with triflate. This famous example illustrates the similar regioselectivity of enol triflate formation from ketones to that of silyl enol ether formation discussed in chapter 3. Kinetic conditions give the less 198 and thermodynamic conditions the more highly substituted 195 triflate. 

The search for a catalyst suitable to promote addition of the less reactive silyl enol ethers of ketones has identified a novel class of cationic transition metal complexes in two independent laboratories. The use of a chiral palladium(II) di-aquo complex in the catalytic asymmetric addition of silyl enol ethers to aldehydes (first demonstrated by Shibasaki, Sodeoka et al. [52a, 52b]) provided a clear precedent for their subsequent use with a-imino esters [53] (Scheme 27). Initial experiments focused on the reaction of various a-imino esters 82a-c with silyl enol ether 83 (1.5equiv) in the presence of the Pd diaquo complex 80a (10 mol %) in DMF. Extensive experimentation led to the formation of 84c in 67% ee, and also underscored the importance of suppressing the generation of tetrafluoroboric acid during the course of the reaction. 

Nakai and a coworker achieved a conceptually different protonation of silyl enol ethers using a chiral cationic palladium complex 40 developed by Shibasaki and his colleagues [61] as a chiral catalyst and water as an achiral proton source [62]. This reaction was hypothesized to progress via a chiral palladium enolate which was diastereoselectively protonated by water to provide the optically active ketone and the chiral Pd catalyst regenerated. A small amount of diisopropylamine was indispensable to accomplish a high level of asymmetric induction and the best enantioselectivity (79% ee) was observed for trimethylsilyl enol ether of 2-methyl-l-tetralone 52 (Scheme 11). 

Heck-type reactions with enol carboxylates (e.g., vinyl acetate) are generally complex. Most common are reactions in which vinyl acetate is employed as an ethylene equivalent (see Scheme 24). However, an example of a preparatively useful reaction with an intact acetate function is given in entry 44.The reaction of vinyl triflates with vinyl phosphonates affords the corresponding conjugate dienylphosphonates (entry 45).f A new access to reactive nonaflates via a one-pot nonaflation-Heck reaction was recently reported (entry 46). " This reaction sequence starts from silyl enol ethers and provides functionalized 1,3-dienes in a simple manner, lodonium salts can be used as RPd precursors (entry 47). It is notable that the palladium(O) insertion preferentially occurs inbetween the iodonium ion and the vinylic, rather than the arylic sp -hybridized carbon (entry 47). Some years ago, Jeffery used acetylenic halides to achieve (JiJ-enynoates and (Ji)-enynones in fair yields at room temperature (entry 48). ... 

The four most common methods for the synthesis of late transition metal enolates are oxidative addition to halocarbonyl compoxmds, ligand metathesis with main group enolates or silyl enol ethers, nucleophilic addition of anionic metal complexes to halocarbonyl electrophiles, and insertion of an a,3-imsaturated carbonyl compoimd into a metal hydride. Examples of these synthetic routes are shown in Equation 3.47-Equation 3.50. Equation 3.47 shows the synthesis of a palladium enolate complex by oxidative addition of ClCHjC(0)CHj to Pd(PPh3), Equation 3.48 shows the synthesis of a palladium enolate complex by the addition of a potassium enolate to an aryl Pd(II) halide complex, and Equation 3.49 shows the synthesis of the C-bound W(II) enolate complex in Figure 3.7 by the addition of Na[( n -C5R5)(CO)jW] to the a-halocarbonyl compound. Finally, Equation 3.50 shows the synthesis of a rhodium enolate complex by insertion of but-l-en-3-one into a rhodium hydride. This last route has also been used to prepare enolates as intermediates in reductive aldol processes. - ... 

We mentioned that by mixing vinyl epoxides and zerovalent palladium, the alcoholate formed was usually sufficiently basic to deprotonate the pronucleophile entity. In some cases, especially with ketones, low reactivity and yields were reported (Table To overcome the problem of the weak basicity of the alcoholate, silyl enol ethers, keto adds, or preformed lithium enolates have successfully been employed.f f" f f /3-Keto acids are masked enolates via the decarboxylation of the intermediary Tr-allylpalladium ]3-ketocarboxylate complexes. The main limitation of the use of keto adds as pronucleophiles seems to be their low reactivity toward the hindered cyclic vinyl epoxides. In these cases, the cationic n-allylpalladium complex undergoes ]S-elimination. Indeed, the reaction between benzoyl acetic acid and cyclobutadiene monoxide in the presence of Pd(PPh3>4 gives only the corresponding cyclopentanone and acetophenone as the... 

The proposed catalytic cycle for the above-described conjugate reduction is outlined in Scheme 17. Initial coordination of the nucleophilic Pd(0)-phosphine complex to the electron-deficient olefin to form complex I is a reversible process that occurs rapidly at room temperature. Oxidative addition of the sihcon hydride moiety to complex I would result in the hydrido olefin complex II. Migratory insertion of the hydride ligand into the electrophilic /S-carbon of the coordinated olefin can result in the palladium enolate intermediate in. Reductive elimination of the silicon moiety and the enolate completes the catalytic cycle and forms the silyl enol ether IV. The latter is prone to acid-catalyzed hydrolysis to produce the saturated ketone. "" ... 

PaUadium(n) enolate complex intermediates are also generated by the silicon-palladium exchange reaction of silyl enol ethers with 7r-allylpalladium(ll) alkoxide intermediate, which is formed in situ from aUyl carbonate with palladium-phosphine complex. With a catalytic amount of Pd(OAc)2 and dppe (diphenylphosphinoethane) in acetonitrile, silyl... 

Some palladium(II) enolate complexes have been prepared and isolated in the reaction of silyl enol ethers lacking a hydrogen, which may be eliminated as palladium(II) hydride via the corresponding cr-(2-oxoalkyl)palladinm. As expected, palladium(II) enolate... 

Both mononuclear aquo- and binuclear /x.-hydroxocomplexes of palladium react with silyl enol ethers to give 0-enolate complexes, which may take part in the aldol P i and Mannich reactions (Scheme... 

A dithioester version of the well-known Dieckmann cyclization gives very high yields under milder conditions than those used for the classical reaction. Palladium(ii)-promoted intramolecular cyclization of silyl enol ethers of alkenyl methyl ketones produces cyclic a,j8-enones in a reaction where oxo-7r-allyl-palladium complexes are postulated as key intermediates [equation (53)]/ ... 

The silyl enol ethers (42), in the presence of palladium acetate, cyclize to give the a,/8-unsaturated ketones (44), the reaction probably proceeding via the oxo-ir-allylpalladium complex (43)/ The reaction proceeds readily at room temperature in the presence of stoicheiometric amounts of Pd(OAc)2, and is particularly useful for the synthesis of 3-methylcyclopent-2-enone derivatives (45). 

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. ... 

Other metals besides palladium are also effective. Reaction of the cationic allyltetracarbonyUron complex derived from (1) or (2) with silyl enol ethers, O-sUyl ketene acetals, or allylstan-nanes, followed by oxidative decomplexation, gives the vinyl-sUane products. The process was shown to occur with near complete retention of stereochemistry (cf. eqs 4 and 5). ... 

The role of palladium in organic synthesis continues to be explored and exploited. Enol stannanes are monoalkylated by allylic acetates in the presence of tetrakis(triphenylphosphine)palladium, Enol stannanes give higher selectivity for monoalkylation than enolate ions or silyl enol ethers. High regioselec-tivity is observed for alkylation at the less substituted end of the allyl moiety. Olefins, after complexation to palladium(ll), alkylate enolate anions. The organopalladium product may be converted into saturated ketones, or into enones by /3-elimination, or acylated with carbon monoxide (Scheme... 

We were able to envision a reasonable catalytic cycle for the use of silyl enol ethers in the asymmetric alkylation reaction, but there were several complications that could potentially lead to lower enantioinduction in the silyl enol ether reactions (Scheme 6). The generation of the enolate independent of the palladium(II) 7t-allyl complex and the presence of a tetrabutylammonium counter ion could shift the mechanism of the reaction. We had very httle proof at the time, but our working hypothesis was that the C-C bond-forming step occurred in the inner sphere of the palladium atom. We considered the possibihty that the conditions used in the silyl enol ether reactions might facilitate an outer sphere pathway resulting in lower ee products. In the event, we found that the ketone products generated from silyl enol ethers did not significantly differ in ee from the equivalent products of allyl enol carbonate reactions (e.g., Table 8 vs. Table 2). 

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