Substituted homoallyl alcohol synthesis

Scheme 1.3.6 Asymmetric synthesis of sulfonimidoyl-substituted homoallyl alcohols.

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]. 

A diorganonickel complex generally undergoes reductive elimination more rapidly than the corresponding palladium complex. Nickel can mediate retro-allylation, which is involved in allylation of allylic carbonate with homoallylic alcohols for efficient synthesis of 1,5-hexadienes [25]. A combination of Ni(cod)2 (cod = 1,5-cyclooctadiene) and triethyl phosphite catalyzes the allylation reaction of Boc-protected cinnamyl alcohol (Boc = f-butoxycarbonyl) with homoallylic alcohols (Scheme 5.34). The reactions with alkyl-substituted homoallylic alcohols (R = alkyl) are not regiospecific but are sterically controlled. The highest linear... 

The 2-oxonia [3,3]sigmatropic rearrangement was also used by Ramachandran ti al. to explain their observation on the synthesis of 4-substituted homoallylic alcohols from crotylboronates [292]. The products from the ln(OTf)3 catalyzed reaction of crotylboronates and aldehydes were observed to be highly dependent on temperature, with the kinetic 2-substituted homoallylic alcohol exclusively observed at low temperature and the thermodynamic 4-substituted product observed at room temperature. This is provided that there is an excess of aldehydes, with less than stoichiometric amounts giving product mixtures (Figure 8.134). These results are consistent with the oxonia [3,3]sigmatropic rearrangement mechanism. The procedure was found to be useful for a variety of alkyl and aryl aldehydes. 

An elegant application of the Vilsmeier reaction is the synthesis of substituted biphenyls as reported by Rao and RaoJ Starting with homoallylic alcohol 8, the biphenyl derivative 9 was obtained from a one-pot reaction in 80% yield ... 

Pancratistatln. The first total synthesis of ( )-pancratistatin (94) (Scheme 14), the structurally most complex of narciclasine alkaloids, was achieved by Danishefsky [27]. The requisite starting material, the substituted benzaldehyde 95 prepared from pyrogallol in six steps in 18% overall yield, was converted via the homoallylic alcohol 96 into the diene 97. Reaction of 97 with 2-nitrovinylsulphone yielded the cycloadduct 98, which on treatment with tributyltinhydride and 2,2 -azobisisobutyronitrile furnished the cyclohexadiene 99. Whilst the cyclisation of the silylether 99 or the derived phenol, under the influence of iodine, could not be accomplished, the more nucleophilic stannylether did participate in the desired ring closure and provided via the iminium salt, the iodolactone 100 on aqueous work-up. 

W. Adam, C. R. Saha-Moller, and K. S. Schmid, Synthesis of 4,6-dideoxyfuranoses through the regioselective and diastereoselective oxyfunctionalization of a dimethylphenylsilyl-substituted chiral homoallylic alcohol, J. Org. Chem., 66 (2001) 7365-7371. 

An aluminium-catalysed tandem Claisen-ene sequence has been developed for the synthesis of homoallylic alcohols (89) and thence a-methylene-y-butyrolactones (90) in good overall yields. Extensive investigation has revealed that Et2AlSPh catalyses Claisen rearrangement of ft -substituted allyl vinyl ethers (85) into 0,5-aluminium... 

Zinc-mediated Barbier-t) e addition of 238, followed by Luche s procedure obtained a mixture of the homoallylic alcohol diastereomers 239 and 240. Alcohol 239 was carried through benzoylation, deketalization, silylation, and ozonolysis, to produce C-branched y-lactone 241. Benzoylation of 240 followed by hydroboration, PCC oxidation, debenzoylation, and alkaline-promoted cyclization directly formed C3-branching 2-deoxyfuranose 242 [87] (O Scheme 63). A novel method for stereoselective synthesis of 4 -a-carbon-substituted nucleosides, through epoxidation of 4, 5 -unsaturated nucleosides and SnCU-promoted epoxy ring opening, was... 

The synthesis of methyl ketone 281 began with the reaction between the tetra-substituted allylborane 279 and 2,3-0-isopropylidene-D-glyceraldehyde 48. The resulting homoallylic alcohol 280, obtained in 73% yield and excellent selectivity (exact ratio not defined) [231], was converted in two steps to the methyl ketone 281. Aldol condensation between the lithium enolate of 281 and aldehyde 278 (structure shown in Scheme 11-12) gave, after protection of the initial adduct, the Felkin diastereomer 282 as the only reported product in 54% yield. This adduct... 

The transient zirconocene butene complex, 105, has proved to be useful in a number of organic transformations. For example, butene substitution of zirconocene alkene complexes with alkoxy-substituted olefins results in /3-alkoxide elimination to furnish the zirconocene alkoxy compounds (R = Me, 123 R = Bnz, 124) (Scheme 16).50,51 Addition of propargyl alcohols to the zirconocene butene complex, 105, affords homoallylic alcohols. These reactions are of limited utility owing to the lack of stereoselectivity or formation of multiple products. Positioning the alkoxide functional group further down the hydrocarbyl chain allows synthesis of cyclopropanes, though mixtures of the carbocycle and alkene products are obtained in some cases (Scheme 16).52... 

In addition, recent studies towards the synthesis of bryostatin 1 have described high diastereoselectivity for the chelation-controlled condensation of the substituted stannane 68 with ent-33 leading to the desired i yn-product 69 via 70 (Scheme 5.2.17).While ketones have rarely been explored as reactive electrophiles for stereoselective allylations, proximate coordination of a Lewis acid through a-chelation can produce favorable results, as illustrated in the exclusive formation of the tertiary homoallylic alcohol 72 from 71 (Scheme 5.2.17).28... 

The use of allyltins and y-substituted allyltins in the stereocontrolled synthesis of homoallylic alcohols. ... 

The table, which collects representative examples, shows that monosubstituted epoxides afford homoallylic alcohols resulting from the attack to the less substituted carbon atom (runs 1, 5 and 7). Homoallylic alcohols are useful intermediates in several important total synthesis." Disubstituted epoxides fail to react (run 4). Styrene oxide leads to a mixture of homoallylic alcohols (run 2) and allylic epoxides give mixture of 1,2- and 1,4-opening product, with predominance of the 1,4 product (run 3, 6 and 8). 

The zinc-based Simmons-Smith type procedures frequently require rather harsh conditions in order to provide acceptable cyclopropane yields. Also, the discrimination between allylic alcohols, homoallylic alcohols and olefins without a hydroxyl group is often not very pronounced. These drawbacks are avoided by a new method which substitutes samarium metal (or samarium amalgam) for zinc (Table 4)43. This cnahlcs only allylic alcohols to be cyclo-propanated under very mild conditions, even for highly crowded substrates. The hydroxy-directed diastereofacial selectivity is good to excellent for cyclic olefins. Due to this property, the method has been applied to the stereoselective synthesis of 1,25-dihydroxycholecalciferol44. 

---