Crotyl addition aldehydes

The use of chiral Br0nsted acids is illustrated in Eq. 93 as a method for catalyst-controlled double diastereoselective additions of pinacol allylic boronates. Aside from circumventing the need for a chiral boronate, these additions can lead to very good amplification of facial stereoselectivity. For example, compared to both non-catalyzed (room temperature, Eq. 90) and SnCU-catalyzed variants, the use of the matched diol-SnCU enantiomer at a low temperature leads to a significant improvement in the proportion of the desired anti-syn diastereomer in the crotylation of aldehyde 117 with pinacolate reagent (Z)-7 (Eq. 93). Moreover, unlike reagent (Z)-ll (Eq. 91) none of the other diastereomers arising from Z- to E-isomerization is observed. 

Several methods promoted by a stoichiometric amount of chiral Lewis acid 38 [51] or chiral Lewis bases 39 [52, 53] and 40 [53] have been developed for enantioselective indium-mediated allylation of aldehydes and ketones by the Loh group. A combination of a chiral trimethylsilyl ether derived from norpseu-doephedrine and allyltrimethylsilane is also convenient for synthesis of enan-tiopure homoallylic alcohols from ketones [54,55]. Asymmetric carbonyl addition by chirally modified allylic metal reagents, to which chiral auxiliaries are covalently bonded, is also an efficient method to obtain enantiomerically enriched homoallylic alcohols and various excellent chiral allylating agents have been developed for example, (lS,2S)-pseudoephedrine- and (lF,2F)-cyclohex-ane-1,2-diamine-derived allylsilanes [56], polymer-supported chiral allylboron reagents [57], and a bisoxazoline-modified chiral allylzinc reagent [58]. An al-lyl transfer reaction from a chiral crotyl donor opened a way to highly enantioselective and a-selective crotylation of aldehydes [59-62]. Enzymatic routes to enantioselective allylation of carbonyl compounds have still not appeared. 

Masamune and cowoikers designed a set of chiral rra/iy-2,5-dimediylborolane-based reagents diat show remarkable enantioselectivities in hydroboration, ketone reduction and crotyl addition to aldehydes. The chirality transfer also turns out to be highly efficient in the aldol reaction. Initial experiments were aimed at defining the structural parameters which affect the E(0) Z(0) ratios of the enolates prepared from various alkanethioates with 2,5-dimethylborolanyl triflate (90) under standard conditions... 

The synthesis of 252 began with Brown s asymmetric crotylation to aldehyde 261. The resulting homoallyl alcohol was converted benzyl ester 262, which was reduced to give lactol acetate 263. Axial allylation to 263 formed 2,6-trans-tetrahydropyran 264, which was subjected to ozonolysis to give an aldehyde. Addition of alkenylzinc, prepared by hydrozircona-tion of an alkyne 265, to the aldehyde mediated by chiral ligand 266 yielded allyl alcohol 267 with a 5.1 1 diastereoselectivity [110]. The stereochemistry of the major isomer was found, unexpectedly, to be the S-form at Cl7, which rendered the macrolactonization to adopt the Mitsunobu reaction. The iodide 252, prepared from 267 in three steps, reacted with... 

The allylation and crotylation of aldehydes provide attractive alternatives to asymmetric acetate and propionate aldol addition reactions for the construction of /1-hydroxy aldehydes or ketones (Scheme 5.2 see also Chapter 4). In analogy to propionate aldol addition reactions, an important stereochemical feature involving the addition of substituted allylation reagents to aldehydes is simple diastereoselectivity namely, the formation of 1,2-syn versus 1,2-anti products. Although the underlying reasons for absolute and relative induction have yet to be studied in mechanistic detail for many of these processes, there are a collection of methods that reliably and predictably furnish optically active adducts. 

Coumalic acid, 56, 51 Crotyl fluoride, 57,73 18-CROWN-6,57, 30 Curtius rearrangement, 59, 1 Cyanide ion, as catalyst for conjugate addition of aldehydes, 59, 56 p-Cyanobenzenesulfonyl cyanide, 57, 89 2-( 1 -Cyanocyclohexyljhydrazinecarboxylic acid methyl ester, 58,102 Cy a noferrocene, 56, 30 Cyanogen chloride, 57, 88... 

An efficient route for the synthesis of the Phe-Phe hydroxyethy-lene dipeptide isostere precursors utilized for the design of potential inhibitors of renin and HIV-protease was developed. The key step is the zinc-mediated stereoselective allylation of A-protected a-amino aldehydes in aqueous solution (Eq. 8.32).70 NaBF4/M (M = Zn or Sn) showed facilitating allylation of a variety of carbonyl compounds in water, and a-and y-addition products of crotylations could be alternatively obtained under the control of this novel mediator (Eq. 8.33).71... 

The multi-component procedure is also effective for the chromium-catalyzed addition of organic halides to aldehydes (the Nozaki-Hiyama-Kishi reaction) [73]. The active Cr(II) species is recycled by redox interaction with Mn powder as the stoichiometric co-reductant in the presence of MesSiCl (Scheme 34), which mainly liberates the chromium catalyst from the alkoxide adduct. The chemo- and diastereo-selective addition reaction is performed with a variety of organic halides and alkenyl triflates. In the case of crotyl bromide, the addition is highly stereoconvergent, i.e., the respective anti-... 

Durandetti et al. have described iron-catalyzed electrochemical allylation of carbonyl compounds with allylic acetates (Equation (27)).333 In the case of aldehydes, slow addition of the corresponding aldehyde is required in order to avoid pinacol formation. With crotyl acetate (R3 = Me), the reaction proved to be highly regioselective, providing almost exclusively branched homoallylic alcohols 150. 

Homoallylic alcohols (8, 111-112). CrCl2, prepared in situ by reduction of CrCl, (Strem) in THF with Na/Hg, is superior to CrCl2 prepared by reduction of CrCl, with LiAlHj for the Cr(II)-mediated addition of crotyl halides to aldehydes. The homoallylic alcohols are formed in good yield and with high arm-selectivity.7 Example ... 

More recently, using the cyclometallated iridium C,(7-benzoate derived from allyl acetate, 4-methoxy-3-nitrobenzoic acid and BIPHEP, catalytic carbonyl crotylation employing 1,3-butadiene from the aldehyde, or alcohol oxidation was achieved under transfer hydrogenation conditions [274]. Carbonyl addition occurs with roughly equal facility from the alcohol or aldehyde oxidation level. However, products are obtained as diastereomeric mixtures. Stereoselective variants of these processes are under development. It should be noted that under the conditions of ruthenium-catalyzed transfer hydrogenation, conjugated dienes, including butadiene, couple to alcohols or aldehydes to provide either products of carbonyl crotylation or p,y-enones (Scheme 16) [275, 276]. 

As demonstrated in the course of a total synthesis of the macrolide bafilo-mycin, double diastereoselective additions can be useful even in the mismatched manifold. For example, the crotylation of chiral a-substituted aldehyde 167 with (E)- affords an 85 15 ratio of diastereomers favoring the desired anti-anti product (Scheme 17). Without a chiral tartrate reagent, the undesired anti-syn diastereomer would be intrinsically favored from aldehyde 167. The use of the appropriate tartrate reagent, the (R,R) unit in this instance, overturns this preference to afford an acceptable ratio of the two separable dias-teomers. 

IS, 2/ )-l-Cyclohexyl-2-methyl-3-buten-l-ol [Representative Procedure for Additions of ( )-Crotyl Diisopropyl Tartrate Boronate to Aldehydes]. ... 

Open transition states have been postulated in the aldol-type additions of ( )- and (Z)-crotyl-stannanes (21/22) to aldehydes. Irrespective of the ( ) or (Z) configuration of the stannane only. yyn-adducts 23/24 are formed. Due to the Lewis acid (LA) complexation of the carbonyl oxygen, a cyclic ( closed ) transition state cannot be adopted. Instead, an open geometry is preferred, in which the methyl and the R group move apart as far as possible to generate the enantiomorphous arrangements 25/2611. 

Bailie et al. were the first to mention alcohol formation from aldehydes by supported gold-catalyzed selective hydrogenation. The reaction of the formation of crotyl alcohol from crotonaldehyde showed high selectivity (up to 81%) at conversions of 5-10%, with preferential hydrogenation of C=0 rather than the C=C bond [216]. The addition of thiophene promoted this selective hydrogenation. This promotional effect was also observed in similar situations for Cu and Ag, but it was not very common for gold. 

The enantioselective addition of ally organometallics to carbonyls has become one of the workhorses of organic synthesis. Dennis Hall of the University of Alberta reports (J. Am. Chem. Soc. 125 10160, 2003) the scandium triflate catalysis chiral allylboronic acids become more effective tools. The best of these, the Hoffmann camphor derivative 2, adds to aldehydes under Sc(OTf), catalysis with excellent enantiomeric excess. The reaction works equally well for methallyl, and for the E and Z crotyl boronic acids. The crotyl derivatives react with the expected high diastereocontrol. A limitation to the boronate additions is that branched chain aldehydes give low yields. 

The acid portion of 1 was assembled by enantio-and diastereocontrolled addition of Z-crotyl borane to the aldehyde 8, following the Brown protocol. Hydroboration and oxidation led to 9, which was condensed with the allenyl silane 10 to give 11 with high diastereocontrol. Conversion of the alcohol to the iodide followed by three-carbon homologation by the Myers procedure then led to 1, which was cyclized with > 10 1 regio- and diasterocontrol to give 12. Ozonolysis and methylenation of the less hindered ketone then delivered 3. 

A practical method for the enantioselective addition of an allylic nucleophile to an aldehyde has been acid-mediated allyl transfer, as exemplified by the conversion of 1 and 2 to 3. While this method worked well for crotyl, allyl transfer itself suffered from eroded ee s. Teck-Peng Loh of the National University of Singapore has found (Tetrahedron Lett. 2004,45,5819) that camphorsulfonic acid (CSA) mediates this conversion without racemization. The alcohol 1 is prepared by addition of allyl Grignard to camphor, so both enantiomers are readily available. 

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