Allylic borinate compounds

The effectiveness of these bases is correlated with the pK of respective amines [10]. Lithium amides derived from secondary amines whose pK values are in the vicinity of 30 (e.g., HN-t-BuSiMe, and HN(SiMej)2) are not suitable for efficient metalation. However, amines like HN-i-Prj, HNChx, and HN-/-PrChx, with pK, values around 35 bring efficient metalation. Moreover, the studies have revealed [8] that bulkiness of OR, as in Ib-d, gives lower yield of desired allylic borinate [11]. Consequently, combination of 9-methoxy-9-BBN and LiNChXj are found to afford the desired allylic borinate (3a) intermediate in excellent yields (Table 28.1) [8]. The 3a intermediate serves as a versatile intermediate in the synthesis of cyclooctane compounds (Chart 28.2) and thus solves the longstanding problem of high-degree strain arising from the powerful transannular interactions present in such systems [12]. 

The addition of allylic boron reagents to carbonyl compounds first leads to homoallylic alcohol derivatives 36 or 37 that contain a covalent B-O bond (Eqs. 46 and 47). These adducts must be cleaved at the end of the reaction to isolate the free alcohol product from the reaction mixture. To cleave the covalent B-0 bond in these intermediates, a hydrolytic or oxidative work-up is required. For additions of allylic boranes, an oxidative work-up of the borinic ester intermediate 36 (R = alkyl) with basic hydrogen peroxide is preferred. For additions of allylic boronate derivatives, a simpler hydrolysis (acidic or basic) or triethanolamine exchange is generally performed as a means to cleave the borate intermediate 37 (Y = O-alkyl). The facility with which the borate ester is hydrolyzed depends primarily on the size of the substituents, but this operation is usually straightforward. For sensitive carbonyl substrates, the choice of allylic derivative, borane or boronate, may thus be dictated by the particular work-up conditions required. 

Non-fluxional vinylic boranes do not react with carbonyl compounds. Nevertheless, the vinylic borane 29 reacts with acetone (2 h under reflux) yielding the Z-isomer of the homoallylic borinic ester 30b. The cw-configuration of the reaction product 30b corresponds to the following sequence of transformations (Scheme 2.11). The [1,7]-H shift in the vinylic borane 29 gives the allylic Z, Z-isomer 28d which immediately reacts with acetone before the equilibrium among the allylic isomers is established. On the other hand, cyclopentanone reacts directly with 29 under mild conditions yielding Z, Z-1,3,5-heptatriene 31 and borinic ester 32 (Scheme 2.12). Apparently 29 reacts with the enol form of cyclopentanone, and a direct splitting of the B-Q ,2 bond takes place. Similar reaction of 29 with acetic acid was used for the preparative synthesis of previously unknown hydrocarbon 31 (Scheme 2.12) [35]. 

The B-allyl-9-BBN derivatives react with carbonyl compounds to afford borinate esters, which on protonolysis using triethanolamine afford the corresponding homoallylic alcohols. Consequently, the allylboration sequence provides a synthetically useful alternative to the familiar Grignard s synthesis of these alcohols. However, the protonolysis by triethanolamine causes a problem in the isolation of homoallylic alcohol from the thick, air-sensitive, boron-containing mixture. Fortunately, treatment of pentane solution of borinate esters of 9-BBN with 1 equiv of ethanolamine results in the rapid formation of a fluffy white precipitate of ethanolamine 9-BBN adduct, which can be easily removed (Eq. 6.7) [1]. 

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