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Palladium-catalyzed allene

An interesting palladium-catalyzed allene/azide incorporation and intramolecular 1,3-dipolar cycloaddition cascade to tetrazolo[5,l-tf]isoquinoline has been published by Grigg et al. <2005TL5899>. In the first step of the events, 3-bromo-6-iodobenzonitrile 105 was reacted with the allene/trimethylsilylazide system in the presence of palladium(O) catalyst to yield a coupling product 106 which under the reaction conditions applied (DMF, 70 °C for 24 h) gave 107. [Pg.660]

The palladium-catalyzed allene preparation method was extended to an asymmetric counterpart using a Pd/(R)-binap species as a chiral catalyst and axially chiral allenes 103 were obtained with good eantioselectivity [96]. It was found that the pres-... [Pg.114]

Palladium chemistry has been used in the synthesis of tetrahydroisoquinolines. Different combinations of iodoaryl-amine-alkene can be used in these multicomponent reactions. For example, the metal-mediated o-alkylated/alkenyl-ation and intramolecular aza-Michael reaction (Scheme 109) give moderate yields of heterocycle <2004TL6903>, whereas the palladium-catalyzed allene insertion-nucleophilic incorporation-Michael addition cascade (Equation 172) produces good yields of tetrahydroisoquinolines in 15 examples <2003TL7445> with further examples producing tetrahydroquinolines (Scheme 110) <2000TL7125>. [Pg.285]

Chromans possessing a fused isoxazolidine moiety 505 can be accessed via a palladium-catalyzed allene insertion-intramolecular 1,3-dipolar cycloaddition cascade reaction between ( )-fV-(2-hydroxybenzylidene)methanamine oxide, allene, and aryl iodides. This process creates two rings, two stereocentres and a quaternary carbon centre in one-pot (Equation 210) <2002CC1754>. [Pg.523]

SPS of isoxazolidines through 1,3-dipolar cycloaddition and their transformations have been reviewed <2005CSR507>. Isoxazolidines were also prepared by nitrone 1,3-dipolar cycloaddition on silica gel in solvent-free conditions under microwave irradiation <2001J(P1)452>. Fused polycyclic isoxazolidines were prepared via a multi-component palladium-catalyzed allene insertion-intramolecular 1,3-dipolar cycloaddition cascade <2002CC1754, 2005AGE7570>. [Pg.453]

While furans have been the main focus of palladium-catalyzed allene cycloisomerization, pyrroles can also be generated via reaction of allenyl-substituted amines. A number of metal catalysts have been reported to mediate the cyclization of these substrates to pyrrolines, however, the use of palladium catalysis can allow the concomitant incorporation of aryl functionality into the 3-position, as shown in Scheme 6.27. At elevated temperatures, oxidation of the pyrroline occurs to afford pyrroles [37]. [Pg.170]

Attempts to employ allenes in palladium-catalyzed oxidations have so far given dimeric products via jr al lyI complexes of type 7i62.63. The fact that only very little 1,2-addition product is formed via nucleophilic attack on jral ly I complex 69 indicates that the kinetic chloropalladation intermediate is 70. Although formation of 70 is reversible, it is trapped by the excess of allene present in the catalytic reaction to give dimeric products. The only reported example of a selective intermolecular 1,2-addition to allenes is the carbonylation given in equation 31, which is a stoichiometric oxidation64. [Pg.678]

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. [Pg.678]

Vinyl- or arylboronic acids also react with allenes, affording 1,3-dienes or styrene derivatives, respectively.89 This palladium-catalyzed addition proceeds with good regioselectivity and high stereoselectivity in favor of the formation of (ft)-trisubstituted isomer. [Pg.309]

Distannation of allenynes initially takes place at the allene moiety (Scheme 34).159,161 Upon heating, the produced allylstannane moiety further undergoes palladium-catalyzed intramolecular allylstannation of the alkyne moiety, affording the corresponding cyclized product. [Pg.750]

A unique system for catalytic silaboration of allenes, in which a catalytic amount of organic halide is used as a crucial additive, has been reported (Equation (86)).232 In the presence of Pd2(dba)3 (5 mol%) with 3-iodo-2-methyl-2-cyclohexen-l-one (10mol%), reactions of terminal allenes with a silylborane afford /3-silylallylboranes in good yields with excellent regioselectivity. It is worth noting that the addition takes place at the terminal C=C bond in contrast to the above-mentioned palladium-catalyzed silaboration. The alkenyl iodide can be replaced with iodine or trimethylsilyl iodide. The key reaction intermediate seems to be silylpalladium(n) iodide, which promotes the insertion of allenes with Si-C bond formation at the central -carbon. [Pg.762]

The palladium-catalyzed silastannation of bis(allene)s gives trans-cyclized product stereoselectively (Equation (121)).162 This stereochemical outcome stands in contrast to the distannation of the bis(allene)s, which affords m-cyclized product. [Pg.777]

Allylphosphonium salts are synthesized by substitution of allyl halides with PPh3. The use of allyl alcohol, allyl acetate, or nitropropene with a palladium catalyst has also been reported.19 It is shown in this study that the organophosphorous compounds can be obtained by a palladium-catalyzed addition to an allene. A notable aspect of this method is that it can control the stereochemistry of the phosphonium salt, and that (Z)-allylphosphonium salts have been obtained in pure form for the first time. [Pg.498]

In the following sections, the palladium-catalyzed conversion of the propargyl electrophiles into allenes will be briefly summarized with some representative examples and some recent reports. Although selectivity between the allenic and the pro-pargylic products has been one of the central topics in Pd-catalyzed reactions of the propargyl electrophiles, reactions giving allenes as main products will be considered. For more comprehensive reviews on these topics, previous publications should be consulted [7-14],... [Pg.95]

Palladium-catalyzed reduction of propargyl acetates is possible with Sml2 in the presence of a proton source (Scheme 3.17) [51]. The allene/alkyne selectivity is greatly influenced by the choice of the proton source. Propargyl phosphates were also converted into hydridoallenes by Pd-catalyzed reduction with Sml2 [52],... [Pg.101]

Other Palladium-Catalyzed Syntheses of Allenes from Propargyl Electrophiles... [Pg.105]

Chloroprene (2-chloro-l,3-butadiene 105), which is a mass-produced, inexpensive industrial material, is an excellent precursor to a variety of terminal allenes 107 [97]. The palladium-catalyzed reaction of 105 with pronucleophiles 106 in the presence of an appropriate base gave the terminal allenes 107 in good yields (Scheme 3.53). The palladium species generated from Pd2(dba)3-CHC13 and DPEphos was a good catalyst for these reactions of chloroprene. In contrast, (Z)-l-Phenyl-2-chloro-l,3-buta-diene, which is isostructural with the bromo-substrate 101, was nearly inert under these conditions. There is no substituent at the vicinal ris-position to the chloride in 105, which allows oxidative addition of the C-Cl bond in 105 to the Pd(0) species. [Pg.115]

In 2001, a palladium-catalyzed asymmetric hydrosilylation of 4-substituted-but-l-en-3-ynes (146) was reported by Hayashi and co-workers [115]. It was found that a monodentate bulky chiral phosphine, (S)-(R)-bisPPFOMe, was effective for the asymmetric synthesis of the axially chiral allenes 147 and up to 90% ee was achieved (Scheme 3.75). The bulky substituent at the 4-position in 146 is essential for the selective formation of the allene 147 the reaction of nC6H13C=CCH=CH2 gave a complex mixture of hydrosilylation products which consisted of <20% of the allenylsilane. [Pg.125]

The catalytic asymmetric synthesis of allenes was first achieved by Elsevier and co-workers in 1989 [104]. A palladium-catalyzed cross-coupling reaction of an allenyl-metal compound 250 (M = ZnCl, MgCl or Cu) with iodobenzene in the presence of DIOP 251 gave 252 in 25% ee (Scheme 4.65). The synthesis of 252 by the reaction of 250 (M = Br) with phenylzinc chloride in the presence of a chiral palladium catalyst gave a quantitative conversion but very low enantiomeric excesses (3-9% ee). [Pg.172]

Scheme 4.69 Highly enantioselective synthesis of allenes 272 by palladium-catalyzed substitution. Scheme 4.69 Highly enantioselective synthesis of allenes 272 by palladium-catalyzed substitution.
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