Reactions with allylboronates mechanism

The reactions of ailylboranes, -silanes and -stannanes with carbonyl compounds and imines always take place with double-bond migration, and the structural stability of the reagent is a common problem that is encountered ( 2.7). The reactions of ailylboranes and -boronates occur without catalysis, while those of allylsilanes and -stannanes usually require the presence of a Lewis add [253], The mechanism of the reactions of allylboron derivatives is concerted, and the addition occurs via a six-membered cyclic transition state. A slightly distorted chair transition state model in which the oxygen of the carbonyl group is coordinated to the boron atom is usually invoked (Figure 6.42). Various steric and polar interactions dictate whether the Si or Re face of the prochiral aldehyde is attacked (models C j... 

Recently, Kobayashi and co-workers reported an interesting variant for the synthesis of homoallylic amines, dubbed an ammonia fixation reaction [128]. With this method, allylboronates are reacted with aldehydes in a solution of ethanolic ammonia. Despite the highly basic conditions, optically pure protected a-hydroxy aldehydes such as 89 can be employed without any observed racemization, and this approach was apphed to the synthesis of aminosugar derivatives via aminoalcohol product 90 (Equation 47). Unfortunately, the addition of a chiral camphor-based allylboronate to benzaldehyde led only to a low enantioselectivity (34% ee). Reactions with the ( )- and (2)-pinacol crotylboronates lead to the same diastereoselectivity seen in the corresponding reactions with aldehydes, affording the respective anti and syn products from a reaction mechanism that most likely involves the intermediacy of primary imines. 

This method has not yet found widespread use for the preparation of allylboronates. In fact, uncatalyzed hydroborations of dienes tend to provide the undesired regioiso-mer with the boron atom on a terminal carbon, i.e., homoallylic boranes. By making use of certain transition metal catalysts, however, Suzuki and co-workers found that (Z)-allylic catecholboronates such as 22 can be obtained in high yield from various substituted butadienes (e.g., isoprene. Equation 11) [44]. Whereas a palladium catalyst is the preferred choice for acyclic dienes, a rhodium catalyst (Rh4(CO)i2) was best for the hydroboration of cyclohexadiene. A suitable mechanism was proposed to explain the high regioselectivity of this process. In all cases, a reaction quench with benzaldehyde afforded the expected homoallylic alcohol product from a tandem hy-droboration/allylation (Section 6.4.1.4). 

Recently, Shibasaki and co-workers reported a copperreaction using a chiral diphosphine ligand, DuPHOS, with an added lanthanide salt (118]. This new allylation system provides good levels of enantioselectivity in additions of the simple allylboronate 2 to either aromatic or aliphatic ketones that present a large difference of steric bulk on both sides of the carbonyl (Equation 43). Based on NMR experiments and on the lack of diastereoselectivity in crotylation examples, the suggested mechanism of this allylation involves transmetallation of the boron to an allylcopper species. 

DFT has been used to probe the mechanism of allylation of ketones by allylboronates in the presence of diethylzinc. Results favour a double y-addition stepwise route, rather than concerted Lewis acid. Diethylzinc is found to be weakly catalytic, with the addition of ethanol substantially accelerating the reaction via Zn(OEt)2 catalysis, with Zn(OH)2 and ZnF2 efficiencies also being calculated. 

Diboration of 1,3-Dienes, Allenes, Enones, and Other Unsaturated Molecules. As described previously in the original article, the Pt[0] catalyzed addition of 1,3-dienes with B2pin2 affords various allylboronic esters (eq 4). Reactions using phosphine-based catalysts such as Pt(PPh3)4 stereoselectively produce els -1,4-addition products with Z-configuration for aliphatic and cyclic dienes. The reaction mechanism suggests... 

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