0-Allenic alcohols, chiral, synthesis

The synthesis of chiral liquid-crystalline allenes was reported by Tschierske and co-workers (Scheme 4.10) [14]. An asymmetric reduction of 41 with Alpine borane was a key step to an enantioenriched allene 44. After removal of the silyl group, the allenic alcohol was etherified by the Mitsunobu method to give 45, the first liquid-crystalline allene derivatives. 

An improved procedure for the synthesis of a-allenic alcohols in good yields and with approximately 90% e.e. was reported by Olsson and Claesson (56). (- )-(S)-3-Butyne-2-ol (25) was converted into the monotetrahydropyranyl derivatives 26a to c, which gave on reduction with LAH in ether or THF the chiral allenes 27a to c (Scheme 4). The absolute configurations of 27b and c were... 

A method for the synthesis of chiral allenic alcohols starting from resolved acetylenic amines. 

The chiral synthesis of allylic alcohols has been the focus of many research works due to the high versatility of these molecules in the preparation of many active com-poimds [58,82], Allen and Williams reported the first example of DKR of allylic alcohols via lipase-palladium catalyst coupling deracemization of cyclic allylic acetates [83]. However, the accumulation of secondary products, as well as the long reaction times required, limited the use of this strategy. 

As with i -substituted allyl alcohols, 2,i -substituted allyl alcohols are epoxidized in excellent enantioselectivity. Examples of AE reactions of this class of substrate are shown below. Epoxide 23 was utilized to prepare chiral allene oxides, which were ring opened with TBAF to provide chiral a-fluoroketones. Epoxide 24 was used to prepare 5,8-disubstituted indolizidines and epoxide 25 was utilized in the formal synthesis of macrosphelide A. Epoxide 26 represents an AE reaction on the very electron deficient 2-cyanoallylic alcohols and epoxide 27 was an intermediate in the total synthesis of (+)-varantmycin. 

Jin and Weinreb reported the enantioselective total synthesis of 5,11-methano-morphanthridine Amaryllidaceae alkaloids via ethynylation of a chiral aldehyde followed by allenylsilane cyclization (Scheme 4.6) [10]. Addition of ethynylmagnesium bromide to 27 produced a 2 1 mixture of (S)- and (R)-propargyl alcohols 28. Both of these isomers were separately converted into the desired same acetate 28 by acetylation or Mitsunobu inversion reaction. After the reaction of 28 with a silyl cuprate, the resulting allene 29 was then converted into (-)-coccinine 31 via an allenylsilane cyclization. 

The asymmetric synthesis of allenes via enantioselective hydrogenation of ketones with ruthenium(II) catalyst was reported by Malacria and co-workers (Scheme 4.11) [15, 16]. The ketone 46 was hydrogenated in the presence of iPrOH, KOH and 5 mol% of a chiral ruthenium catalyst, prepared from [(p-cymene) RuC12]2 and (S,S)-TsDPEN (2 equiv./Ru), to afford 47 in 75% yield with 95% ee. The alcohol 47 was converted into the corresponding chiral allene 48 (>95% ee) by the reaction of the corresponding mesylate with MeCu(CN)MgBr. A phosphine oxide derivative of the allenediyne 48 was proved to be a substrate for a cobalt-mediated [2 + 2+ 2] cycloaddition. 

A stereoselective synthesis of the enantiomerically enriched allenic hydrocarbons was described in 2001 (Scheme 18.11) [37]. For example, hydrostannylation of the chiral propargylic alcohol 28 (obtained with 82% ee by enantioselective reduction of... 

Chiral allenes. A key step in a recent synthesis of the optically active pheromone of the male boll weevil (3) used the orthocstcr Claisen rearrangement for transfer of the chirality of the acetylenic alcohol 1 to the allene 2. The final product (3) shows a higher optical rotation than the naturally occurring material, which may... 

Allene, perfluoro-, cycloaddition to phenylsydnone, 59, 12 Allene, phenylsulfinyl-, cycloaddition of nitrile oxides, 60, 276 Alloxan, structure, 55, 133 Alloxazines, synthesis, 55, 186 Allyl alcohols, ethers, chiral,... 

A synthesis of the Inhoffen-Lythgoe diol (46.7, Scheme 2.46), a useful intermediate in the synthesis of Vitamin D derivatives, demonstrates the use of a chiral acetal in an asymmetric tandem cyclisation reaction.102 Once again, Lewis acid co-ordination to the less hindered oxygen of the acetal 46.1 initiated a Prins-like cyclisation that terminated by attack of the propargylsilane on an incipient tertiary carbocation. After removal of the chiral auxiliary, the allene function in the alcohol 46.4 was transformed into the side chain of 46.7 with the creation of two new stereogenic centres. 

Synthesis of Chiral Nonracemic AUenes. Enantio-merically enriched chiral allenes can be prepared by derivatization of a racemic propargyl alcohol with (R)-NEI, followed by chromatographic separation of the resulting diastereomers and reaction of the purified diastereomers with lithium dialkylcuprates at —78 °C, as shown in eq 2. ... 

Alkynylepoxides [123,142,143 Eq. (68) 142] and alkynyl propiolactones [Eq. (69) 144] afforded allenyl-alcohols or allenyl-carboxylic acids. Diastereoselective ring opening of alkynylepoxides has been studied [143,145]. The use of optically active propargyl substrates enables the synthesis of optically active allenes [Eq. (70) 146] [10,140,145-147]. A subtle change of the reaction medium may drastically change the degree of chirality transfer, which has been systematically examined [145]. 

Reactions of chiral allenes proceed with a preference for the formation of the syn diastereomer. The stereochemical outcome of these reactions can be rationalized by invoking an open transition state model for the addition reactions (Figure 12), which depicts an antiperiplanar orientation of the chiral allenylsi-lane to the aldehyde carbonyl. In this model, steric repulsion between the allenyl methyl and the aldehyde substituent is most likely responsible for the destabilization of transition state (B), which leads to the anti (minor) stereoisomer. This destabilizing interaction is minimized in transition state (A). Table 5 illustrates representative examples and summarizes the scope of the regiocontrolled synthesis of homopropargylic alcohols using allenylsilanes. 

The chiral alcohols are mainly employed as esters or enol ethers. Esters with carboxylic acids can be obtained by any convenient esterification technique. Dienol ethers were obtained by transetherification with the ethyl enol ether of a 1,3-diketone, followed by Wittig reaction8 silyldienol ethers were obtained by the method of Danishefsky11-12 and simple enol ethers by mercury-catalyzed transetherification13. Esters and enol ethers have been used as chiral dienophiles or dienes in diastereoselective Diels-Alder reactions (Section D. 1.6.1.1.1.1.). (R)-l-Phenylethanol [(R)-4] has been used for enantioselective protonation (Section C.) and the (S)-enantiomer as chiral leaving group in phenol ethers for the synthesis of binaphthols (Section B.2.) the phenol ethers are prepared as described for menthol in the preceding section. (S)-2-Octanol [(S)-2] has found applications in the synthesis of chiral allenes (Section B.I.). 

Allenyltins are conveniently prepared from the terminal alkynes which have a suitable leaving group. An example is shown in equation 19. A two-step one-pot procedure for the synthesis of allene by hydrostannation of alkynes has recently been reported starting from propargylic alcohols a hydrostannation and subsequent deoxystannylation generates the allenes 6 as shown in equation 20. A chiral version of this procedure has also been described in the paper. 

Whereas the cycloisomerization of allenic ketones affords achiral products, replacing the keto with a hydroxy group leads to the formation of chiral heterocycles. In 2001, the synthesis of chiral 2,5-dihydrofurans by treatment of a-hydroxyallenes with catalytic amounts of AuCls in unpolar solvents was reported (Scheme 4-90). Many functionalities (e.g., carbonyl groups, additional free alcohols, and acid-sensitive... 

Molander and Sommers [115] reported a chromium(III)-catalyzed synthesis of allenes from propargyl alcohol derivatives and triaUcylaluminum reagents. When substituted and enantiomerically enriched propargyl alcohols 403 were treated with these reagents in the presence of the chromium complex 404, allenes 405 were obtained in good yields and with high levels of chirality transfer (Scheme 10.138). 

The preparation of the optical antipodes of a-aminopropiophenone from norephedrine and an improved large-scale resolution of norephedrine have been described. The stereoselective synthesis of diastereomeric amino-alcohols from chiral aminocarbonyl compounds by reduction or by addition of organometallic reagents has been reviewed, and syntheses of a-allenic amines and allenic amino-alcohols have been reported. 

---