Reactions with allylboronates synthesis

Allylboron compounds have proven to be an exceedingly useful class of allylmetal reagents for the stereoselective synthesis of homoallylic alcohols via reactions with carbonyl compounds, especially aldehydes1. The reactions of allylboron compounds and aldehydes proceed by way of cyclic transition states with predictable transmission of olefinic stereochemistry to anti (from L-alkene precursors) or syn (from Z-alkene precursors) relationships about the newly formed carbon-carbon bond. This stereochemical feature, classified as simple diastereoselection, is general for Type I allylorganometallicslb. 

In contrast to the 2-butenylboranes, 2-butcnylboronates have found widespread application in acyclic diastereoselective synthesis owing to their ease of preparation (Section 1.3.3.3.3.1.1.), configurational stability and highly stereoselective reactions with aldehydes3 4. The results of reactions of substituted allylboronates and representative achiral aldehydes are summarized in Table 1. 

The reactions of allylboronates 1 (R = H or CH3) may proceed either by way of transition state 3, in which the a-substituent X adopts an axial position, or 4 in which X occupies an equatorial position. These two pathways are easily distinguished since 3 provides 7 with a Z-olefin, whereas 4 provides 8 with an E-olefinic linkage. There is also a second fundamental stereochemical difference between these two transition states 7 and 8 are heterochirally related from reactions in which 1 is not racemic. That is, 7 and 8 arc enantiomers once the stereochemistry-associated with the double bond is destroyed. Thus, the selectivity for reaction by way of 3 in preference to 4, or via 6 in preference to 5 in reactions of a-subsliluted (Z)-2-butenylboronate 2, is an important factor that determines the suitability of these reagents for applications in enantioselective or acyclic diastereoselective synthesis. 

In spite of the poor diastereoselectivity realized in reactions with most chiral aldehydes, allylboronates are highly attractive reagents for organic synthesis.. i. 2,17 i ost are easily prepared in large quantities, and are convenient to use. 8 They are nonbasic, relatively non-nucieophilic, and hence are highly chemoselective in their reactions. 

The poor diastereoselectivity of the reactions of chiral aldehydes and achiral allylboronates appeared to be a problem that could be solved by recourse to the strategy of double asymmetric synthesis.f Our studies thus moved into this new arena of asymmetric synthesis, our objective being the development of a chiral allylboron reagent capable of controlling the stereochemical outcome of reactions with chiral aldehydes independent of any diastereofacial preference on the part of the carbonyl reaction partner. 

Related Allylboronate Reagents. A stereoselective synthesis of anti 1,2-diols has been achieved by using a DIPT-modified ( )-y-[(cyclohexyloxy)dimethylsilyl]allylboronate reagent. This reagent is best applied in double asymmetric reactions with chiral aldehydes such as o-glyceraldehyde acetonide (eq 9). 

Scheme 11-10). It should be noted that glyeeraldehyde derivatives are outstanding substrates for the tartrate ester-modified allylboronates [118]. Aldehyde 261, derived from 260 in two steps, underwent a highly stereoselective (selectivity = >99 1) allylation reaction with the Brown Ipc2BAllyl reagent 195 [112, 113] (an in-depth discussion of the synthesis and use of this reagent appears in Section... 

In situ generation of CH2 CHCH(Li)Cl and its trapping with triisopropyl borate provides new access to 1-chloroallylboronate [33] which is a valuable intermediate for the synthesis of variously substituted allylboronates via the reaction with organolithi-ums (eq (21)). 

Results of reactions of chiral a-methyl aldehydes and several chiral crotyl- and allyl-boron reagents are summarized in Tables 8 and 9. It is apparent from these data that the Brown (Ipc)2B(crotyl) and (Ipc)2B(allyl) reagents (51), (52) and (219) consistently give excellent results for the synthesis of each product diastereomer (Table 8, entries 3-6, 11, 16, 20, and 24 Table 9, entries 1,2, 10 and 18). This is true also for their reactions with chiral a- and 3-alkoxy aldehydes (Scheme 49).i. i4S-i50 Thg tartrate crotylboronates (18) and (19) also display excellent selectivity in the synthesis of crotyl diastereomers (136), (137) and (139) (Table 8, entries 7,10,13,17,25 and 28), but are much less selective for the syndesis of crotyl diastereomer (138), especially from -alkoxy-substituted aldehydes such as (253). Tartrate allylboronate (224) is also less effective than (Ipc)2Ballyl (219) for the synthesis of (257) and (258) in Table 9, and of (266) and (267) in Scheme 49.Substantial improvements in selectivity have been realized by using the taitramide-based allylboronate (228), and the results with this reagent (Table 9, entries 4, 7, 9, 12, 14, 17, 20 and 22) compare very favorably with those obtained with (219). The data... 

The allylation and crotylation of a-alkoxy aldehydes provide chiral 1,2-diol synthons which can be used in the synthesis of polyoj genated small molecules, for example, natural and unnatural sugars The tartrate-derived allylboronates I and 2 provide reagent-controlled selectivity in reaction with chiral glyceraldehyde acetonide 30. The intrinsic selectivity of the aldehyde is estimated by its reactions with pinacol allylboronates 33 and 34. The reagents 1 and 2 overcome the aldehyde s... 

The reactions of allylboronates with a-methyl-P-alkoxy aldehydes provides propionate adducts which are useful for the synthesis of polypropionate... 

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. 

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