Palladium acetate cyclization

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). 

There are reports of an increasing number of palladium-assisted reactions, in some of which the palladium has a catalytic function. Thus furan and thiophene undergo facile palladium-assisted alkenylation giving 2-substituted products. Benzo[6 Jfuran and TV- acetyl-indole yield cyclization products, dibenzofurans and carbazoles respectively, in addition to alkenylated products (8UOC851). The arylation of pyrroles can be effected by treatment with palladium acetate and an arene (Scheme 86) (81CC254). 

In a recent communication, the parent system 2 has been obtained in poor yields (16% and 10%, respectively) from the double cyclization of N-diphenyl-1,3-phenylenediamine either by using two equivalents of palladium acetate in refluxing acetic acid or by irradiation in methanol in the presence of a catalytic amount of iodine (00SC3651). All the available approaches sununarized so far were marred by harsh reactioi conditions or troublesome-to-prepare starting materials, leading to low overall yields of the desired products and difficulty in introducing sensitive substituents. 

Bromination of the diphenyl indole derivative 316 with bromine in DMF or trimethylammonium bromide afforded the 7-bromo derivative 317. Reaction with allyl bromide or its derivatives gave A-allyl derivatives 318 that upon cyclization with palladium acetate gave 7,9-dimethoxy-l,2-diphenylpyrrolo[3,2,l-// ]quinoline derivatives 319 (92T7601) (Scheme 57). 

Perhydroindans (46) and (47) could be obtained in 73% yield from the carbonate (48) with only minor amounts of elimination product. The use of BSA and the triisopropyl phosphite-palladium acetate catalytic system provides further improvement. The low cisitrans selectivity in the formation of the first ring, and rapid subsequent cyclization account for the fact that the ratio of (46) to (47) is only 2 1 (Scheme 2.14). Even the presence of a bulky trialkylsiloxyl substituent adjacent to the vinyl sulfone moiety has only a minor influence on the cisitrans selectivity [24]. 

A novel route to indoles and quinolines has been developed by sequential Wiltig and Heck reactions <96CC2253>. Thus, treatment of o-bromo- or iodo-lV-lrifluoroaceiylanilines (86) with a stabilized phosphorane affords the corresponding enamines 87 as a mixture of isomers. Cyclization to 88 is effected by heating with palladium acetate, tri phenyl phosphine, and bu.se. 

The insertion of carbon monoxide into readily available 2-bromo-3-aminopropene derivatives can be effected by catalytic quantities of palladium acetate and triphenylphosphine high CO pressures are not required (Scheme 16).38 The /Mactam products presumably arise by palladation,carbonylation, and cyclization as depicted in Scheme 17.38 An extension of this approach to the synthesis of biologically interesting condensed /(-lactams can be expected. 

Dialkylindolines and 1,3-dialkylindoles are formed in poor yield (<10%) from the reaction of ethyl- or phenymagnesium bromide with 2-chloro-N-methyl-N-allylaniline in the presence of catalytic quantities of (bistriphenylphosphine)nickel dichloride.72 In a modification of this procedure, the allyl derivatives can be converted by stoichiometric amounts of tetrakis(triphenylphosphine)nickel into 1,3-dialkylindoles in moderate yield72 (Scheme 43) an initial process of oxidative addition and ensuing cyclization of arylnickel intermediates is thought to occur. In contrast to the nickel system,72 it has proved possible to achieve the indole synthesis by means of catalytic quantities of palladium acetate.73 It is preferable to use... 

An interestingly short total synthesis of quadrone was developed by Kende and coworkers who made application of Pd(II)-mediated cycloalkenylation of silyl enol ethers (Scheme LV) Their point of departure was 609 which was converted directly to 610, Reaction of this silyl enol ether with palladium acetate in acetonitrile gave predominantly 6JI which could be cyclized to 612. From this intermediate, it was possible to prepare the known keto acid. 

Cyclization ok Diphenyl Ethers to Dibenzofurans with Palladium Acetate under Acidic Conditions... 

The Heck reaction of dihydroindoles produces a mixture of cyclized products, the ratio of which can be controlled by varying the reaction conditions < 1998CEJ1554>. Hence, the < a ti-product is produced exclusively using palladium acetate as catalyst in the presence of silver carbonate and is isomerized to the endoA oms. i on exposure to camphor-sulfonic acid (CSA) at room temperature (Scheme 11). 

Palladium acetate has also been used to catalyze oxidative cyclizations to produce the related dihydroindole in dimethylacetamide (DMA) in moderate yields <1997BMEL749> (Equation 68). Similar cyclizations have been reported to occur in the presence of manganese dioxide and nitrobenzoic acid <1997TL7207>. 

Additionally, some Pd-catalyzed type II zinc-ene cyclizations have been described. When the allylic acetate 181 was treated with EtiZn in the presence of a catalytic amount of Pd(PPh3)4, its slow conversion to a cyclic organozinc species by a type zinc-ene reaction was observed and iodinolysis afforded the six-membered ring 182 in relatively low yield. The regioselectivity was noteworthy as C-C bond formation occurred at the most substituted terminus of the allylmetal. By contrast, the type II palladium-ene cyclization of the allylic acetate 181, in conjunction with a /1-elimination process, proceeded with opposite regioselectivity and led to the six-membered ring 183 (equation 88)114. 

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... 

It has been shown that combination of bromoallylation reaction and Heck cyclization is a useful methodology for the preparation of a variety of fused bicyclic (3-lactams of nonconventional structure [95], Starting from acetates 164 and using palladium acetate as the palladium source, DMF as solvent, potassium carbonate as base, and triphenylphosphine, the reaction occurred. The reaction conditions were further optimized and typical results for the preparation of bicyclic (3-lactams 165-168 are summarized in Schemes 57. 

A palladium-catalyzed cyclization of 2-iodobenzyl 2-butynyl ethers 562 with ethynyltrimethylsilane leads to 4-substituted isochromans 563 (Equation 234) <2002T9007>. Isochromans 564 can be accessed using a similar palladium-catalyzed cyclization of a propargylic acetal 565 with (Z)-selectivity observed in the exocyclic double bond (Equation 235) <2005JOC489>. 

Among the unimolecular cyclizations, the synthesis yielding a single product with excellent yields was the cyclization of allyloxy alcohols brought about by a ruthenium complex. The other unimolecular processes exhibited very low yields and/or mixture of products. The most popular synthesis of 1,3-dioxocins involved the cyclization of 1,5-alcohols with the insertion of a carbon unit. Such acetalization of both acyclic dialcohols or hydroxyl groups bound to rings is particularly efficient and the cyclization of methane-diphenols or dihydroxybenzophenones with dihalomethanes was of wide applications. Palladium-promoted cyclization of chloromercurio compounds showed to be certainly less effective even if it presented some cases in reasonable yields. The sole example synthesis of 1,3-dioxocins by transformation of another ring has no preparative interest. 

Palladium-catalyzed cyclization of the oxime derivative 47 provided a good yield of the pyrrole 48 (Equation 9) <1999CL45>. Similar reactions have been observed in connection with cyclization studies of related ketone trimethylhydrazonium salts <2005H(65)273>. Photochemical radical cyclization of 7,5-unsaturated ketone oximes has been reported to produce 1-pyrrolines <2005TL2373>. Similar 0-acetyloximes may also be annulated to 1-pyrrolines by treatment with acetic acid in the presence of 1,4-cyclohexadiene and naphthalene-l,5-diol, possibly proceeding via a radical mechanism <2002CL144>. 

A route to pyrroles illustrated by the preparation of 292 involves initial treatment of the nitroketene-5, 5 -acetal 293 with an organometallic reagent, followed by conversion of the resulting alkene 294 to the enamine 295, and final annulation to the target heterocycle (Scheme 34) <1998T12973>. A related approach featuring constmction of /3-hydroxyenamines from 1,3-dicarbonyl compounds and /3-amino alcohols, and subsequent palladium-catalyzed cyclization to pyrroles, has been reported <1996TL9203>. 

Several new routes involve formation of one carbon-carbon bond in pre-formed substrates. Palladium-catalyzed cyclization of /3-hydroxyenamine derivatives has been employed in a route to substituted pyrroles and 4,5,6,7-tetrahy-droindoles with multiple substituents by formation of the C-3-C-4 bond as the key feature, as illustrated by construction of the molecule 534 (Equation 146) <2006T8533>. Zinc perchlorate-catalyzed addition of alcohols to the nitrile functionality of a-cyanomethyl-/3-ketoesters, followed by annulation gave access to a series of substituted ethyl 5-alkoxypyrrole-3-carboxylates <2007T461>. Similar chemistry has also been used for synthesis of a related set of pyrrole-3-phosphonates <2007T4156>. A study on preparation of 3,5,7-functionalized indoles by Heck cyclization of suitable A-allyl substituted 2-haloanilines has also appeared <2006S3467>. In addition, indole-3-acetic acid derivatives have been prepared by base induced annulation of 2-aminocinnamic acid esters (available for instance from 2-iodoani-lines) <2006OL4473>. 

Cyclization of phenols 6 with the (acetoxypinene)palladium acetate complex 5 gives the enantiomeric 2,3-dihydro-2-vinylbenzofurans (R)-764. 

The asymmetric cyclization of 2[( )-3-pentenyl]phenol (1) performed with (f/3-pinene)palladium acetate (see Section 4.6.2.2.2.) in the presence of copper(II) acetate in methanol under an oxygen atmosphere, gives 3,4-dihydro-2-vinyl-27/-1 -benzopyran (2) in 64% yield and 25% ee87. The enantiomeric excess is determined by H-NMR analysis, in the presence of Eu(tfc)3, of methyl 3,4-dihydro-2//-1 -benzopyran-2-carboxylate, derived from 2 by oxidation with potassium permanganate, followed by esterification with diazomethane. 

A novel Pd(I) complex has been obtained from the cyclization of diphenylacetylene with palladium acetate in methanol (12) ... 

Palladium-catalyzed cyclization-anion capture involving 1,6-en-yne 7 proceeds via vinylpalladium species 8 (Scheme 5.6.2) to give 9 in good yield. Similar processes using allyl acetate or halide starter species and phenylboronic acid or lithium acetate as anion capture agents have been reported. ... 

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