Homoallyl alcohols, stereoselective synthesis

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. 

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... 

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)... 

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. 

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). 

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]. 

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. 

Stereoselective addition of allyl metal reagents to various functionalities is an important reaction in organic synthesis [32, 33]. The allylation of epoxides and aziridines with allyltin reagent is catalyzed by Lewis acids. Even though many Lewis acids have been reported to catalyze this reaction, Bi(OTf)3 is distinct because it avoids the formation of byproducts and is also environmentally more compatible. It catalyzes the reaction of aryl epoxides with tetraallyltin to afford the corresponding homoallyllic alcohol [34]. 

Chiral alkenyl and cycloalkenyl oxiranes are valuable intermediates in organic synthesis [38]. Their asymmetric synthesis has been accomplished by several methods, including the epoxidation of allyl alcohols in combination with an oxidation and olefination [39a], the epoxidation of dienes [39b,c], the chloroallylation of aldehydes in combination with a 1,2-elimination [39f-h], and the reaction of S-ylides with aldehydes [39i]. Although these methods are efficient for the synthesis of alkenyl oxiranes, they are not well suited for cycloalkenyl oxiranes of the 56 type (Scheme 1.3.21). Therefore we had developed an interest in the asymmetric synthesis of the cycloalkenyl oxiranes 56 from the sulfonimidoyl-substituted homoallyl alcohols 7. It was speculated that the allylic sulfoximine group of 7 could be stereoselectively replaced by a Cl atom with formation of corresponding chlorohydrins 55 which upon base treatment should give the cycloalkenyl oxiranes 56. The feasibility of a Cl substitution of the sulfoximine group had been shown previously in the case of S-alkyl sulfoximines [40]. 

Ni alkoxide as a stoichiometric reaction. However, in this reaction the silylnickel alkoxide 76 is formed, and its reductive elimination affords silyl ethers 77 and 78. At the same time, Ni(0) is regenerated to make the reaction catalytic. The formal total synthesis of elaeokanine C (79) was carried out by this reaction [25], Homoallylic alcohol 81 is obtained by the intermolecular reaction of benzaldehyde with the diene 80 and hydrosilane in high regio- and stereoselective manner [26],... 

Tandem intramolecular silylformylation-allylation reaction of diallylhydrosilyl ethers derived from homoallyl alcohols is convenient for rapid, stereoselective synthesis of 1,3,5-triols convertible to more oxygen-functionalized compounds (Scheme 12).142,142a,142b 143 [ he second uncatalyzed allylation step would be facilitated by the formation of a strained silacycle intermediate, which has enough Lewis acidity to activate the formyl group. A similar tandem reaction via alkyne silylformylation has been reported.144... 

Aldehydes, ketones, and acetals react with allyltrimethylsilane in the presence of a catalytic amount of BiX3 (X = C1, Br, OTf) to give homoallyl alcohols or homoallyl alkyl ethers (Equation (52)).91-93 The BiX3-catalyzed allylation of aldehydes and sequential intramolecular etherification of the resulting homoallylic silyl ethers are involved in the stereoselective synthesis of polysubstituted tetrahydropyrans (Equation (53)).94,95 Similarly, these Lewis acids catalyze the cyanation of aldehydes and ketones with cyanotrimethylsilane. When a chiral bismuth(m) catalyst is used in the cyanation, cyanohydrines are obtained in up to 72% ee (Equation (54)). a-Aminonitriles are prepared directly from aldehydes, amines, and cyanotrimethysilane by the BiCl3-catalyzed Strecker-type reaction. 

Asymmetric allylboration has also been applied to y-methoxyallyl derivatives. Isomerically pure (Z)-y-methoxyallyldiisopinocampheylborane (rf31), prepared from Ipc2lSOMe and the lithium anion of allyl methyl ether, reacts with various aldehydes to afford the yyn - j-m e (boxy homoallylic alcohol (32a) in a highly regio- and stereoselective manner17 (Scheme 3.In). This one-pot synthesis of enantiomerically pure 1,2-diol derivatives went as smoothly as the asymmetric Brown crotylation, affording products with uniformly high diastereoselectivity. 

In order to apply tartrate ester-modified allyl- and crotylboronates to synthetic problems,23 Roush and Palkowitz undertook the stereoselective synthesis of the C19-C29 fragment 48 of rifamycin S, a well-known member of the ansamycin antibiotic group24 (Scheme 3.1u). The synthesis started with the reaction of (S,S)-43E and the chiral aldehyde (S)-49. This crotylboration provided the homoallylic alcohol 50 as the major component of an 88 11 1 mixture. Compound 50 was transformed smoothly into the aldehyde 51, which served as the substrate for the second crotylboration reaction. The alcohol 52 was obtained in 71% yield and with 98% diastereoselectivity. After a series of standard functional group manipulations, the alcohol 53 was oxidized to the corresponding aldehyde and underwent the third crotylboronate addition, which resulted in a 95 5 mixture... 

The lithium derivative of the chiral chelating diamine (3 )-2-(l-pyrrolidinylmethyl)-pyrrolidine (6) has been used extensively in stereoselective synthesis, i.e. in the deprotonation of ketones and rearrangement of epoxides to homoallylic alcohols. The lithium amide has been crystallized from toluene solution, and X-ray analysis revealed that it forms a ladder-type tetramer with the two pyrrolidine nitrogens solvating the two lithiums at the end of the ladder38, (Li-6)4. 

Intramolecular hydrosilylation of allyl and homoallyl alcohols, with subsequent oxidative cleavage of the resultant C—Si bond, has provided a new approach to the legiocontrolled synthesis of 1,2-and/or 1,3-diols (see also Section 4.3.2.2.3). The example shown (Scheme 10) illustrates nicely the use of syn stereoselection in a reiterative manner. 

Highly stereoselective introduction of a (3,(3-dimethyl-homoallylic alcohol subunit was also accomplished in this synthesis by using a DIPT-modified prenylboronate (eq 11). ... 

Asymmetric Allylation of Prochiral Aldehydes. The asymmetric allylation reaction is useful for stereoselective carbon-carbon bond formation, and therefore development of an effective method for the synthesis of optically active homoallyl alcohols was sought. A chiral allylating agent, readily generated from tin(II) trifluoromethanesulfonate, chiral diamine 1, and allyldi-isobutylaluminum, was efficiently employed in the asymmetric allylation of aldehydes in 1996 (eq 16). ... 

A relevant extension of the ring opening of epoxides with a titanium salt can be seen in the concomitant scission of the C-C bond of cyclobutane illustrated in Eqs (285) and (286) [648]. Choice of each diastereoisomer enables highly selective construction of the trisubstituted double bond which finds application in terpene synthesis. The tandem cleavage of the C-O and C-C bonds was similarly feasible in the combination of oxetane and cyclobutane as illustrated in the stereoselective synthesis of a homoallyl alcohol (Eq. 287) [648]. 

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