Cross alkyl halides, palladium-catalyze

Treatment of the (—)-menthone-derived 2/7-1,3-benzoxazin-4(3//)-one 202 with triflic anhydride gave the triflate 203 in quantitative yield. Palladium-catalyzed cross-coupling of 203 with 2-pyridylzinc halide resulted in formation of an approximately 3 1 mixture of the 4-(2-pyridyl)-2//-l,3-benzoxazine 204 and a 4-imino-l,3-benzodioxane derivative 205 (Scheme 36). Compound 205 was formed by the isomerization of 203, which occurred with complete retention of stereochemistry. The 4-(2-pyridyl)-l,3-benzoxazine derivative 204 was applied in enantioselective allylic alkylations of 1,3-diphenyl-2-propenyl acetate with dimethyl malonate as a chiral ligand inducing a 62% ee in the product <2005JOM(690)2027>. 

Transition metal-catalyzed cross-coupling reactions between vinyl organometallic compounds and unactivated alkyl halides that can be usually performed with palladium, nickel and cobalt are of particular synthetic interest [37-39]. Recently, the groups of Cahiez [48] and Cossy [49] concurrently reported the first iron-catalyzed reaction of alkenyl Grignard compounds with primary and secondary alkyl halides (X=Br, I) (Scheme 5.15). The two protocols basically differ in the iron source... 

Early findings by Suzuki and co-workers [109] showed that the palladium-catalyzed iminocarbonylative cross-coupling reaction between 9-alkyl-9-BBN derivatives, t-butylisocyanide, and arylhalides gives access to alkyl aryl ketones 132 after hydrolysis of the corresponding ketimine intermediates 131. Presumably, the concentration of free isocyanide is kept to a minimum by its coordination with the borane. Formation of an iminoacylpalladium(II) halide 130 by insertion of isocyanide to the newly formed arylpalladium complex followed by a transmetallation step afford the ketimine intermediates 131 (Scheme 8.52). 

The stereospecific insertion of 2-monosubstituted alkenyl carbenoids was successfully employed in the preparation of 1-alkyl-1-zircono-dienes. The Z and E carbenoids of 1-chloro-l-lithio-l,3-butadiene (69 and 70, respectively) are generated in situ fromE- andZ-l,4-dichloro-2-butene [53] (Scheme 25). Inversion of configuration at the carbenoid carbon during the 1,2-metalate rearrangement stereospecifically yields terminal dienyl zirconocenes 71 and 72 [54] (Scheme 25). As the carbenoid-derived double bond is formed in 9 1=Z E for 69 and >20 1=E Z isomeric mixtures for 70, the metalated dienes 71 and 72 are expected to be formed with the same isomeric ratio. Carbon-carbon bond formation was achieved by palladium-catalyzed cross-coupling with allyl or vinyl halides to give the functionalized products with >95 5 stereopurity [55-57]. 

Palladium-catalyzed cross-coupling of alkyl halides is a challenging problem due to slow oxidative addition rates and rapid y9-elimination of palladium hydride (Scheme 5). 

Palladium catalyzed cyanation [71] has recently received a lot of attention in the literature as a cross-coupling which employs cheap, commercially available metal cyanides and incorporates the versatile and synthetically useful cyano group. The development of a domino ort/ o-functionalization/cyanation reaction represents an advance in palladium catalysis as there are very few, if any palladium-catalyzed domino cyanation reactions. The development of the domino ortfto-functionalization/ cyanation [72, 73] by Lautens has led to some of the most significant discoveries of highly functionalized alkyl halides as coupling partners, as well as further development in the selectivity and scope of o/t/to-arylation chemistry. 

A second important palladium-catalyzed process is cross coupling of an aryl or alkenyl tialkyltin reagent with an alkyl or aryl halide. In this reaction, one carbon-palladium bond is generated by transmetalation of Pd x with BuaSn-R, while the other carbon-palladium bond is formed by oxidative addition of an organic halide with a Pd°L species. This reaction, which is tolerant of many organic functional groups, is normally known as the Stille Reaction (Scheme 4). ... 

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