Copper boronate species

Synthesis of a series of novel functionalized achiral and chiral allyl boronates has been recently reported by Ramachandran via nucleophilic SNj -type addition of copper boronate species (generated from the boronates 37, 141, 142 under Miyaura conditions) [115,116] to various functionalized allyl acetates that tvere prepared either via vinylalumination or by Baylis-Hillman reaction with various aldehydes [117]. The resulting allylic boronates bearing an ester moiety (X=OR) were subsequently used for the synthesis of a-alkylidene-/3-substituted-y-butyrolactones by allylboration of aldehydes (Scheme 3.76). 

Better results can be obtained by genetaling die boronate species widi die aid of sodium medioxide. In diis case, satisfactory transmetalalion occurs on treatment widi Cut. Hills, die ftinctionalized copper reagent 55 can be alkyuylaied widi 1-bromo-l-bexyne at -40 C, ftirnisbing die etiyue 56 in 7596 yield (Sdieme 2.15) [32]. 

Better results can be obtained by generating the boronate species with the aid of sodium methoxide. In this case, satisfactory transmetalation occurs on treatment with Cul. Thus, the functionalized copper reagent 55 can be alkynylated with 1-bromo-l-hexyne at —40 °C, furnishing the enyne 56 in 75% yield (Scheme 2.15) [32]. 

Scheme 4.26 shows the development of two general reactions based on copper(I) thiophene-2-carboxylate (CuTC) or Cu(OAc)2 for the formal arylation of imtnes with arylboronic acids [62]. The O-acetyl or O-pentafluorophenyl oximes react with a wide range of electron-rich, electron-poor and electron-neutral boronic acids, and even ortho-substituted substrates react well. The mechanism is proposed to proceed, as shown in Scheme 4.27, via an initial oxidative addition of the copper(I) species, either CuTC or through reduction of Cu(OAc)2 by the boronic acid, to the ketoxime O-carboxylate. This is followed by transmetallation and reductive elimination to generate the final product and regenerate the catalytically active copper(I) species. 

In addition to arylboronic acids, arylboronates have also been successfully used in fluorination reactions (Scheme 7.56) [93]. These boron compounds are attractive substrates since they are typically more robust than other boron species and can often be stored for long periods of time. The catalyst system for this reaction was a copper(I) triflate species along with 2 equiv of silver fluoride. While several sources of electrophilic fluorine generated the aryl fluorides, N-fluoro-2,4,6-trimethylpyridinium hexafluorophosphate was the most effective. The chemistry displayed broad functional group tolerance with the lowest yields obtained with heteroarylboronates. The authors were also able to devise a one-pot borylation-fluorination reaction starting from the parent arene. The arene was converted into an arylboronate through an iridium-catalyzed borylation reaction in the first step of the reaction, while fluorination was achieved during the second step. This is particularly attractive since it facilitates the conversion of unfunctionalized substrates into aryl fluorides. 

Taylor, D., B.G. Maddock, and G. Mance. 1985. The acute toxicity of nine grey list metals (arsenic, boron, chromium, copper, lead, nickel, tin, vanadium and zinc) to two marine fish species dab (Limanda limanda) and grey mullet (Chelon labrosus). Aquat. Toxicol. 7 135-144. 

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