Ketone enolates cross-coupling reactions

Stereodefined enol acetates of ketones can readily be synthesized by palladium-catalyzed cross-coupling reactions of arylboron compounds with enol acetates of a-bromo ketones (Eq. (70)) [113]. 

Cross-coupling reactions leading to the formation of C-X (X = heteroatom) bonds catalyzed by Pd(dba)2 have been reported. Aniline derivatives have been prepared via reaction of amine nucleophiles with aryl halides in the presence of Pd(dba)2 and phosphines, especially P( Bu)3. Likewise, diaryl and aryl alkyl ethers are produced from aryl halides (Cl, Br, I) and sodium aryloxides and alkoxides under similar conditions. Conditions effective for the coupling of aryl chlorides with amines, boronic acids, and ketone enolates using an easily prepared phosphine chloride as a ligand have recently been uncovered (eq 22). The preparation of aryl siloxanes and allyl boronates via Pd(dba)2-catalyzed C-Si and C-B coupling have been reported as well. 

In the total synthesis of (+)-lycopladine A by Toste et al. [30], a gold-catalyzed 5-endo cyclization of an iodoalkyne with a silyl enol ether has been used (Scheme 16.25). This transformation efficiently produces a -unsaturated bicyclic ketone that possesses the required quaternary asymmetric center at the position a to the carbonyl group. The vinyl iodide functionaiity generated during the cyclization was subsequently used in a palladium-catalyzed cross-coupling reaction in order to construct the pyridine ring of (-F)-lycopladine A. 

Abe, S. Miyaura, N. Suzuki, A. 1992. The palladium-catalyzed cross-coupling reaction of enol acetates of a-bromo ketones with 1-alkenyl-, aryl-, or alkylboron compounds A facile synthesis of ketones and their enol acetates. J. Am. Chem. Soc. 65 2863-2865. 

Potassium hydroxide in acetonitrile solution with dicyclohexyl-18-crown-6 gives good yields of aj8-unsaturated nitriles from a variety of aldehydes and ketones, including benzophenone. One consequence of the rate enhancement of the [3,3] sigmatropic rearrangement of certain enolates reported last year by Evans is a new route to prenylated quinones (Scheme 14). A development in the synthesis of olefins by the boron mediated cross-coupling reaction is the use of the boronic... 

Desilylative coupling of cinnamyltrimethylsilane results in 3,6-diphenyl-1,5-hexadiene as shown in Scheme 2.60. The cross-coupling reaction of silyl enol ethers and allylic silanes proceeds chemoselectively to give Y,8-unsaturated ketones, in which the oxovanadium(V) oxidatively desilylates the more readily oxidizable organosilicon compound [126], Their redox potentials determine whether they will act as a radical generator or acceptor. These redox potentials can be predicted from calculated ionization potentials. VO(OR)Cl2 is a versatile oxidant, which can induce chemoselective coupling via the oxidative desilylation of a variety of organosilicon compounds under controlled conditions, as shown in Scheme 2.61. 

Transition metal-catalyzed silicon-based cross-coupling reaction has emerged as a versatile carbon-carbon bond-forming process with high stereocontrol and excellent functional group tolerance [35], For example, (a-benzoyloxy)alkenylsilanes 105, prepared as a pure -isomer by 0-acylation of a lithium enolate derived from the corresponding acylsilane, reacts with carboxylic acid anhydrides in the presence of [RhCl(CO)2]2, giving rise to a-acyloxy ketones 106, which are then converted into 1,2-diketones by acidic workup (Scheme 5.27) [36]. 

Palladium-Catalyzed Arylation of Enolates. Very substantial progress has been made in the use of Pd-catalyzed cross coupling for arylation of enolates and enolate equivalents. This reaction provides an important method for arylation of enolates, which is normally a difficult transformation to accomplish.171 A number of phosphine ligands have been found to promote these reactions. Bulky trialkyl phosphines such as /n. v-(/-butyl)phosphinc with a catalytic amount of Pd(OAc)2 results in phenylation of the enolates of aromatic ketones and diethyl malonate.172... 

The Reformatsky reagents, i.e. zinc enolates of esters, undergo Ni catalysed cross-coupling with aryl halides.53 The Ni catalysed reaction of arylzincs with a-bromoacetates also permits a-arylation of esters54 (Scheme 11.13). However, a-alkenylation of enolates of ketones, aldehydes, and esters has been less satisfactory. Its further development is clearly desirable. Alternatively, a-alkenylation of a-iodoenones in conjunction with conjugate reduction discussed earlier should be considered. 

The insight that zinc ester enolates can be prepared prior to the addition of the electrophile has largely expanded the scope of the Reformatsky reaction.1-3 Substrates such as azomethines that quaternize in the presence of a-halo-esters do react without incident under these two-step conditions.23 The same holds true for acyl halides which readily decompose on exposure to zinc dust, but react properly with preformed zinc ester enolates in the presence of catalytic amounts of Pd(0) complexes.24 Alkylations of Reformatsky reagents are usually difficult to achieve and proceed only with the most reactive agents such as methyl iodide or benzyl halides.25 However, zinc ester enolates can be cross-coupled with aryl- and alkenyl halides or -triflates, respectively, in the presence of transition metal catalysts in a Negishi-type reaction.26 Table 14.2 compiles a few selected examples of Reformatsky reactions with electrophiles other than aldehydes or ketones.27... 

The cross-coupling of aryl halides and enolates is a powerful method to prepare a-arylated carbonyl compounds that are difficult to access through classic organic chemistry [29]. (NHC)Pd(allyl)Cl species [30] were the first NHC-bearing complexes used as pre-catalysts for the a-arylation of ketones [31,32]. More recently, novel (IPr)Pd(acac)Cl complexes have shown remarkable catalytic activity in this transformation [33]. From aryl chlorides, excellent yields were obtained after short reaction times at 60 °C, the lowest temperature reported to date with a carbene-based system (Table 1). 

The enolate can be built-in in the allyl esters of /3-keto esters (equation 53). The chemoselectivity is excellent, as shown by selective reaction of an allylic acetate in the presence of a simple ketone, using a tin enolate anion (equation 54). Even mildly nucleophilic species, such as allylic-tifr derivatives, react at room temperature, the method of choice for cross coupling of allylic units (equation 55). 

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