Homoallyl alcohols, stereoselective

A stereoselective base catalysed [2,3] sigmatropic rearrangement of allyl ethers to homoallylic alcohols (stereoselective) (see 1st edition). 

Hartung, J. and Greh, M. (2002) Transition metal-catalyzed oxidations of bishomoallyhc alcohols. J. Organomet. Chem., 661,67-84 (b) Hartung, J., Drees, S., Greh, M., Schmidt, P., Svoboda, 1., Fuess, H., Murso, A., and Stalke, D. (2003) (SchifF-base)vanadium(V) complex-catalyzed oxidations of substituted bis(homoallylic) alcohols -Stereoselective synthesis of functionalized tetrahydrofurans. Eur. J. Org. Chem., 2388-2408. 

The ylide (35), prepared from base treatment of the methylenetriphenyl-phosphorane-isobutene oxide adduct, has been shown to react with steroidal aldehydes to give the (E)-homoallylic alcohol stereoselectively [equation (6)], especially at low temperatures. 

Hartung J, Drees S, Greb M et al (2003) (Schiff-base) vanadium (V) complex-catalyzed oxidations of substimted bis (homoallylic) alcohols-stereoselective synthesis of functionalized tetrahydrofurans. Eur J Org Chem 13 2388-2408... 

The Pd-catalyzed hydrogenolysis of vinyloxiranes with formate affords homoallyl alcohols, rather than allylic alcohols regioselectively. The reaction is stereospecific and proceeds by inversion of the stereochemistry of the C—O bond[394,395]. The stereochemistry of the products is controlled by the geometry of the alkene group in vinyloxiranes. The stereoselective formation of stereoisomers of the syn hydroxy group in 630 and the ami in 632 from the ( )-epoxide 629 and the (Z)-epoxide 631 respectively is an example. 

HOFFMAN - YAMAMOTO Stereoselective adylations Synthesis of syn or anti homoallylic alcohols from Z or E crotylboronate and aldehydes (Hoffman) or of syn homoallylic alcohols from crotylstannanes, BF3 and aldehydes (Yamamoto)... 

Pd(0)-catalyzed hydrogenolysis of vinylepoxides offers an attractive regio- and dia-stereoselective route to homoallylic alcohols (Scheme 9.36) [104, 155, 156]. Thus, hydrogenolysis of ( ) olefin 88 affords syn isomer 89 with inversion of configuration at the allylic carbon, while subjection of (Z) isomer 90 to identical reaction conditions results in the anti isomer 91. The outcomes of these reactions are ex-... 

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. 

The surprising selectivity in the formation of 4 and 5 is apparently due to thermodynamic control (rapid equilibration via the 1,3-boratropic shift). Structures 4 and 5 are also the most reactive of those that are present at equilibrium, and consequently reactions with aldehydes are very selective. The homoallylic alcohol products are useful intermediates in stereoselective syntheses of trisubstituted butadienes via acid- or base-catalyzed Peterson eliminations. 

A )-1-Methyl-2-butenylstannanes similarly give ann-homoallylic alcohols on healing with aldehydes, only traces of the sjn-isomers being detected. Moreover, these reactions are highly stereoselective for formation of (Z) double bonds in the products. It would appear that small amounts (ca. 10%) of the (Z)-isomers in the (A)-l-methyl-2-butenylstannanes (see Section 1.3.3.3.6.1.1.2.) do not interfere because they are significantly less reactive17. 

Coupling to both termini of the 2-methyl-2-propcnyl residue occurs when the complex 5, formed from the iodo compound 4 and stiver tetratluoroborate, is allowed to react with an excess of aldehyde, giving rise to diastcreomerically pure 4-fluoro-2,4,6-trisubstituted tetrahy-dropyrans 617. The details of the reaction and, as well, the origin of stereoselectivity is unclear at present. It would not be surprising if the reaction is restricted to those aldehydes leading in the first step to homoallylic alcohols capable of forming mesomerically highly stabilized carb-enium ions on solvolysis. 

A new chiral auxiliary based on a camphor-derived 8-lactol has been developed for the stereoselective alkylation of glycine enolate in order to give enantiomerically pure a-amino acid derivatives. As a key step for the synthesis of this useful auxiliary has served the rc-selective hydroformylation of a homoallylic alcohol employing the rhodium(I)/XANTPHOS catalyst (Scheme 11) [56]. 

Recently, a new multicomponent condensation strategy for the stereocontrolled synthesis of polysubstituted tetrahydropyran derivatives was re-published by the Marko group, employing an ene reaction combined with an intramolecular Sakurai cyclization (IMSC) (Scheme 1.14) [14]. The initial step is an Et2AlCl-promoted ene reaction between allylsilane 1-50 and an aldehyde to afford the (Z)-homoallylic alcohol 1-51, with good control of the geometry of the double bond. Subsequent Lewis acid-media ted condensation of 1-51 with another equivalent of an aldehyde provided the polysubstituted exo-methylene tetrahydropyran 1-53 stereoselectively and... 

Synthetic transformations of the products of the intramolecular bis-silylation have been examined. The five-membered ring products derived from homopropargylic alcohols were hydrogenated in a stereoselective manner (Scheme ll).90 Oxidation of the products under the Tamao oxidation conditions (H202/F /base)96 leads to the stereoselective synthesis of 1,2,4-triols. This method can be complementary to the one involving intramolecular bis-silylation of homoallylic alcohols (vide infra). 

The hydrogenation of acyclic homoallylic alcohols with a 1,1-disubstituted ole-fmic bond by cationic [Rh(diphos-4)]+ catalyst proceeds in modest to moderate stereoselectivity, generally forming 1,3-anti compounds (Table 21.10, entries 1, 4 and 5), and the effect of the stereogenic center at the allylic position overrides the directivity of hydroxyl group. The 1,3-syn product is then observed though in poor selectivity (entry 3) [19, 57, 58]. Inspection of the hydrogenation prod-... 

With the aid of BF3 OEt2, methoxyborolane (R,R)-114 reacts with (.E)- or (Z)-crotylpotassium to provide (is,R,R)-115 and (Z,R,R)-115, respectively. After adding the aldehyde to a solution of crotyl-borolane in THF at —78°C for 4 hours, 2-aminoethanol is added. The solution is warmed to room temperature, and oxidative cleavage at this point gives the homoallylic alcohols with high stereoselectivity. The borolane moiety can be recovered by precipitating it as an amino alcohol complex and can be reused without any loss of enantiomeric purity. As shown in Scheme 3-43, the (.E)- and (Z)-crotyl compounds lead to anti- and -products 116, respectively. The diastereoselectivity is about 20 1, and the ee for most cases is over 95% (Table 3-11). 

The mode of reaction of titanacydobutenes with carbonyl compounds is largely dependent on steric factors (Scheme 14.31) [72]. Ketones and aldehydes tend to insert into the titanium—alkyl bond of 2,3-diphenyltitanacydobutene, and homoallylic alcohols 70 are obtained by hydrolysis of the adducts 71 [65a,73]. On the contrary, when dialkyl-substi-tuted titanacydobutenes are employed, the reaction with aldehydes preferentially proceeds through insertion into the titanium—vinyl bond. Thermal decomposition of the adducts 72 affords conjugated dienes 73 with E-stereoselectivity as a result of a concerted retro [4+2] cycloaddition [72]. 

Hydrozirconation of monosubstituted allenes offers easy access to allylzircono-cene chlorides, which react with carbonyl compounds to afford homoallylic alcohols in a highly regio- and stereoselective manner (Scheme 16.68) [73-75],... 

Very recently the tandem hydroformylation/acetalization has been used for the synthesis of new synthetically valuable chiral auxiliary derived from camphor. Stereoselective allylation of camphor and subsequent terminal hydroformylation of the resulting homoallylic alcohol affords the 5-lactol auxiliary (camTHP OH) in multigram scale (Scheme 8) [41]. 

Silyl homoallylic alcohols are obtained with high y-regioselection and E-stereoselection on reaction of chiral alkoxy- and aminomethyl-substituted a -silylallyl carbanions with aldehydes factors which influence the diastereomeric excess have been identified. 

Metallic tin, Sn(0), is even more effectively employed. For example, in the presence of Sn(0), allyl bromide and a-halocarbonyl compounds afford nucleophilic organometallic species, which add to aldehydes in good yields to give homoallylic alcohols (12) and g-hydroxycarbonyl compounds (13,14) respectively. a-Diketones could be reduced by activated Sn(0), to give tin(II) enediolates which in turn undergo aldol reaction to form a,g-dihydroxyketones (15,16). This reaction was successfully applied to a stereoselective synthesis of methyl D-glucosaminate (17). 

The approach to polyketide synthesis described in Scheme 5.2 requires the relatively nontrivial synthesis of acid-sensitive enol acetals 1. An alternative can be envisioned wherein hemiacetals derived from homoallylic alcohols and aldehydes undergo dia-stereoselective oxymercuration. Transmetallation to rhodium could then intercept the hydroformylation pathway and lead to formylation to produce aldehydes 2. This proposal has been reduced to practice as shown in Scheme 5.6. For example, Yb(OTf)3-cata-lyzed oxymercuration of the illustrated homoallyhc alcohol provided organomercurial 14 [6]. Rhodium(l)-catalyzed hydroformylation of 14 proved successful, giving aldehyde 15, but was highly dependent on the use of exactly 0.5 equiv of DABCO as an additive [7]. Several other amines and diamines were examined with variation of the stoichiometry and none proved nearly as effective in promoting the reaction. This remarkable effect has been ascribed to the facilitation of transmetallation by formation of a 2 1 R-HgCl DABCO complex and the unique properties of DABCO when both amines are complexed/protonated. 

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