Acylpalladium intermediate

Formation of ketones. Ketones can be prepared by the carbonylation of halides and pseudo-halides in the presence of various organometallic compounds of Zn, B, Al, Sn, Si, and Hg, and other carbon nucleophiles, which attack acylpalladium intermediates (transmetallation and reductive elimination). 

Alkyl- and arylmercury(II) halides are used for the ketone formation[402]. When active methylene compounds. such as /f-keto esters or malonates are used instead of alcohols, acylated / -keto esters and malonates 546 are produced, For this reaction, dppf is a good ligand[403]. The intramolecular version of the reaction proceeds by trapping the acylpalladium intermediate with eno-late to give five- and six-membered rings smoothly. Formation of 547 by intramolecular trapping with malonate is an example[404]. 

The 2-substituted 3-acylindoles 579 are prepared by carbonylative cycliza-tion of the 2-alkynyltrifluoroacetanilides 576 with aryl halides or alkenyl tri-flates. The reaction can be understood by the aminopalladation of the alkyne with the acylpalladium intermediate as shown by 577 to generate 578, followed by reductive elimination to give 579[425]. 

Acyi halides are reactive compounds and react with nucleophiles without a catalyst, but they are activated further by forming the acylpalladium intermediates, which undergo insertion and further transformations. The decarbonyla-tive reaction of acyl chlorides as pseudo-halides to form the aryipalladium is treated in Section 1,1.1.1. The reaction without decarbonylation is treated in this section. 

In addition to alcohols, some other nucleophiles such as amines and carbon nucleophiles can be used to trap the acylpalladium intermediates. The o-viny-lidene-/j-lactam 30 is prepared by the carbonylation of the 4-benzylamino-2-alkynyl methyl carbonate derivative 29[16]. The reaction proceeds using TMPP, a cyclic phosphite, as a ligand. When the amino group is protected as the p-toluenesulfonamide, the reaction proceeds in the presence of potassium carbonate, and the f>-alkynyl-/J-lactam 31 is obtained by the isomerization of the allenyl (vinylidene) group to the less strained alkyne. 

Keto esters are obtained by the carbonylation of alkadienes via insertion of the aikene into an acylpalladium intermediate. The five-membered ring keto ester 22 is formed from l,5-hexadiene[24]. Carbonylation of 1,5-COD in alcohols affords the mono- and diesters 23 and 24[25], On the other hand, bicy-clo[3.3.1]-2-nonen-9-one (25) is formed in 40% yield in THF[26], 1,5-Diphenyl-3-oxopentane (26) and 1,5-diphenylpent-l-en-3-one (27) are obtained by the carbonylation of styrene. A cationic Pd-diphosphine complex is used as the catalyst[27]. 

Organopalladium intermediates are also involved in the synthesis of ketones and other carbonyl compounds. These reactions involve acylpalladium intermediates, which can be made from acyl halides or by reaction of an organopalladium species with carbon monoxide. A second organic group, usually arising from any organometallic reagent, can then form a ketone. Alternatively, the acylpalladium intermediate may react with nucleophilic solvents such as alcohols to form esters. 

A.2. Solvocarbonylation. In solvocarbonylation, a substituent is introduced by a nucleophilic addition to a tt complex of the alkene. The acylpalladium intermediate is then captured by a nucleophilic solvent such as an alcohol. A catalytic process that involves Cu(II) reoxidizes Pd(0) to the Pd(II) state.244... 

Application of the carbonylation reaction to halides with appropriately placed hydroxy groups leads to lactone formation. In this case the acylpalladium intermediate is trapped intramolecularly. 

An example of an intramolecular palladium-catalyzed oxidation of an allene involving carbonylation was used in the synthesis of pumilotoxin 251 D (equation 32)65. Intramolecular aminopalladation of the allene followed by carbonylation of the palladium-carbon bond and subsequent oxidative cleavage of the acylpalladium intermediate by CuCE afforded pyrrolidine 72 in which the chirality at the carbon at the 2-position was established. 

Insertion of ethene into the Pd-H bond provides the ethyl complexes [Pd(Et)(TPPTS)3] and tra 5-[Pd(Et)(TPPTS)2] which take up CO and yield tra -[Pd C(CO)Et (TPPTS)2]. These complexes were all characterized by NMR techniques in separate reactions. Again, elimination of propionic acid from the acylpalladium intermediate (eq. 5.6) was found rate-determining ... 

Acylpalladium intermediates can be involved in intramolecular processes leading to the formation of carbo- or heterocycles. In this chapter we discuss the cyclizations via the attack of acylpalladium intemediates at carbon centers and formation of new G-G bonds. The basic scheme (Scheme 7) of such processes includes the oxidative addition of Pd(0) to G(j )-X bonds (X = halogen or triflate), migratory insertion of GO, and subsequent intramolecular addition of acylpalladium intermediate to double or triple bonds to yield cyclic ketones. 

In the presence of alcohols, the termination stage changes to nucleophilic cleavage of acylpalladium intermediate. In this case, cyclization competes with premature alkoxycarbonylation (Equation (29)). 

Cyclizations onto triple bonds are rare, and require intramolecular trapping of acylpalladium intermediate (Scheme 20). ... 

Intramolecular carbonylative cross-coupling involving enolizable GH-acidic fragments has been described by Negishi et al. In this case, trapping of acylpalladium intermediate is effected formally by enolate, either with carbon or oxygen center (Scheme 28). 

Another variation of the palladium-catalyzed carbonylation reaction occurs when hydrogen is added rather than an alcohol or a primary or secondary amine. This variation leads to aldehyde formation the hydrogen reduces the acylpalladium intermediate to aldehyde and metal hydride (76). A basic tertiary amine is also added as in the ester-forming reaction to neutralize the hydrogen halide formed in the dissociation of the hydride ... 

The course of the insertion of diphenylketene into ir-allylpalladium intermediates has been found to depend on the nature of the ir-allyl precursor. Allyl acetates give dienes, while allyl carbonates give car-boxymethylated products (equations 84 and 8S).264 An intermediate allyl Pd—OR species (9) is believed to exist in both cases. When R = Ac, decarbonylation is followed by (J-H elimination, whereas if R = Me, alkoxide attacks the acylpalladium intermediate and yields the methoxycarbonyl compound. 

Allyl ketones can be prepared by trapping acylpalladium intermediates with main group metal compounds. The allyl ketone 251 can be prepared from the allyl ester 248 by trapping acylpalladium 249 with the alkylzinc compound 250 at room temperature and 1 atm [115]. Reaction of geranyl chloride (252) with the furylstannane 253 under CO pressure afforded the ketone 254, which was converted to dendrolasin (255) [93]. Aldehydes are prepared by trapping with a metal hydride. The /l,y-unsaturated aldehyde 257 is prepared by the carbonylation of the allyl chloride 256 in the presence of Bu3 SnH [116,117],... 

Insertion of CO also generates the acylpalladium intermediate 7, and 2,3-alkadienoates are obtained by alcoholysis (Type lb). 

Active methylene compounds can be used for trapping the acylpalladium intermediates [21], The triketone 85 is obtained in the presence of cyclohexane-1,3-dione (84). The carbonylation proceeds under 1 atm of CO at 50 °C. 

The mechanism of this three-component coupling reaction is probably analogous to the aforementioned insertion of acyl chlorides (above). One can imagine assembling an intermediate acylpalladium species either by oxidative addition to an acyl chloride or, in this case, by oxidative addition to the aromatic iodide followed by migratory insertion into carbon monoxide. Once formed, the acylpalladium intermediate can insert into the SCB to furnish a 7-(chlorosilyl)propyl ketone, which cyclizes in the presence of the amine to afford cyclic enol ethers. 

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