Homopropargyl alcohol

A similar allyl [91] or propargyl [92] Reformatsky reagent has been used to prepare fluormated homoallylic or homopropargylic alcohols, respectively [91, 92] (equations 60 and 61)... 

These mesylates, in turn, can be converted to enantioenriched allenyltin, zinc, and indium reagents which add to aldehydes with excellent diastereo-and enantioselectivity to afford either syn- or anti-homopropargylic alcohols or allenylcarbinols (eq 2, 3, and 4).3 4 Adducts of this type serve as useful intermediates for the synthesis of polyketide and hydrofuran natural products.5... 

In the case of terminal alkynes having oxygenated functions in the linear chain (Scheme 10, route D), Martin, Padron, and coworkers found that homopropargylic alcohols reacted properly, yielding 2-substituted dihydropyrans as sole products, probably via a Prins-type cyclization. This cyclization provides a new approach toward 2-alkyM-halo-5,6-dihydro-2//-pyrans through a concomitant C-C and C-O bond formation (Scheme 21) [35]. 

Scheme 22 Coupling of secondary homopropargylic alcohols and aldehydes promoted by iron (III) halides...

As an extension of this work, the same authors explored such methodology for the synthesis of 2,6-disubstituted dihydropyrans using secondary homopropargylic alcohols (Scheme 10, route E). Surprisingly, the treatment of pent-4-yn-2-ol and 3-methylbutanal in the presence of FeCls led to unsaturated ( )-(3-hydroxyketone and ( )-a,p-unsaturated ketone in 2.5 1 ratio and 65% yield, without any trace of the expected Prins-type cyclic product (Scheme 22) [36]. To test the anion influence in this coupling, FeCE and FeBrs were used in a comparative study for the reaction of pent-4-yn-2-ol (R = R" = H, = Me) and several aldehydes. A range of aldehydes except for benzaldehyde was transformed into unsaturated (3-hydroxy-ketones in moderate to good yields. 

Several ways to suppress the 2-oxonium-[3,3]-rearrangements might be envisioned. Apart from the introduction of a bulky substituent R at the aldehyde (Scheme 23) a similar steric repulsion between R and R might also be observed upon introduction of a bulky auxiliary at R. A proof-of-principle for this concept was observed upon by using of a trimethylsilyl group as substituent R in the alkyne moiety (Scheme 25, R = TMS). This improvement provided an efficient access to polysubstituted dihydropyrans via a silyl alkyne-Prins cyclization. Ab initio theoretical calculations support the proposed mechanism. Moreover, the use of enantiomerically enriched secondary homopropargylic alcohols yielded the corresponding oxa-cycles with similar enantiomeric purity [38]. 

Scheme 23 Proposed mechanism for the addition of secondary homopropargylic alcohols to...

Scheme 25 Silyl alkyne-Prins cyclization of secondary homopropargylic alcohols and aldehydes using FeXs as a promoter...

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). 

An alternative disconnection of homopropargylic alcohols substrates for intramolecular hydrosilylation is the opening of an epoxide with an alkynyl anion. This strategy was employed in a total synthesis of the macrolide RK-397 (Scheme 20). Epoxide ring opening serves to establish homopropargylic alcohol C with the appropriate stereochemistry. A hydrosilylation/oxidation protocol affords the diol E after liberation of the terminal alkyne. The... 

The final cyclization manifold has been realized with a different ruthenium catalyst (Scheme 22). The cationic [Cp Ru(MeCN)3]PF6 induces exclusive endo-dig cyclization of both homopropargylic and bis-homopropargylic alcohols.29 73 The clean reaction to form a seven-membered ring is noteworthy for several reasons intramolecular exo-dig cyclization with bis-homopropargylic alcohols is not well established, the platinum-catalyzed case has been reported to be problematic,80 and the selectivity for seven-membered ring formation over the exo-dig cyclization to form a six-membered ring is likely not thermodynamic. The endo-dig cyclization manifold was thus significant evidence that a re-examination of alkyne hydrosilylation mechanisms is necessary (see Section 10.17.2). 

Closely related to both allyl carbenoids and the allenyl carbenoids discussed above, propargyl carbenoids 101 are readily generated in situ and insert into zirconacycles to afford species 102 (Scheme 3.27), which are closely related to species 84 derived from allenyl carbenoids [65], Protonation affords a mixture of allene and alkyne products, but the Lewis acid assisted addition of aldehydes is regioselective and affords the homopropargylic alcohol products 103 in high yield. Bicydic zirconacyclopentenes react similarly, but there is little diastereocontrol from the ring junction to the newly formed stereocenters. The r 3-propargyl complexes derived from saturated zirconacycles are inert towards aldehyde addition. 

Allenic alcohols,3 In the presence of Sml2 and Pd[P(C6H3),]4, sec- and tert-propargylic acetates add to ketones to give allenic alcohols as the only or major product. A mixture of allenic and homopropargylic alcohols is formed from reactions of primary propargylic acetates. 

Reduction of the cyclic alkynyl carbonate 31 afforded two different products depending on the phosphine ligands on the palladium catalyst [48], Whereas Pd(dba)2/dppe gave the allenic product 32, the homopropargyl alcohol 33 was obtained with nBu3P (Scheme 3.16). 

A single example of allene formation was briefly described for a reaction of 2-methylbut-l-en-3-yne (148) with catecholborane (149) [116]. The allenylborane 150 was not isolated but converted into the homopropargyl alcohol 151 in 57% yield by quenching with benzaldehyde (Scheme 3.76). 

An asymmetric version of the Pd-catalyzed hydroboration of the enynes was reported in 1993(118]. The monodentate phosphine (S)-MeO-MOP was used as a chiral ligand for the palladium catalyst. Enantioselectivity of the asymmetric hydroboration was estimated from the enantiopurity of homopropargyl alcohols, which were obtained from the axially chiral allenylboranes and benzaldehyde via an SE pathway (Scheme 3.78). 

In 1993, Hayashi and co-workers reported a catalytic asymmetric synthesis of alle-nylboranes 256 by palladium-catalyzed hydroboration of conjugated enynes 253 (Scheme 4.66) [105]. Reaction of but-l-en-3-ynes 253 with catecholborane 254 in the presence of a catalyst, prepared from Pd2(dba)3 CHC13 (1 mol%) and a chiral mono-dentate phosphine ligand (S)-MeO-MOP 255 (1 mol%), gave an allenylborane 256. The ee of 256 was determined by the reaction with benzaldehyde affording the corresponding optically active homopropargyl alcohols 257 with up to 61% ee (syn anti= 1 1—3 1). 

Additional allene homologues were prepared by using this methodology with a variety of electrophiles (EX, Table 9.2) [6], For reactions requiring removal of a secondary allenic proton the base of choice was tBuLi. Only allenic products were formed except in the reaction with cyclopentanone, in which a small amount of the homopropargylic alcohol product was produced (last entry). 

Treatment of allene (1,2-propadiene) with 2equiv. of butyllithium leads to an intermediate dilithio species which adds to ketones and aldehydes to afford homopropargylic alcohols in high yield (Table 9.3) [7]. This intermediate also reacts with geranyl chloride to afford the alkynyl coupling product uncontaminated by the allene regioisomer. 

In situ magnesiation of an allenyl iodide with isopropylmagnesium bromide gives rise to a transient allenyl Grignard reagent, which adds to aldehydes and ketones to afford mainly homopropargylic alcohol adducts (Table 9.8) [18]. The anti diastereo-mers are favored, especially with sterically demanding aldehydes. Additions to ketones are less selective. 

Table 9.12 Conversion of lithio propargyl chloride to allenic carbinols and homopropargylic alcohols.

Catechol allenylboranes have also been used to synthesize homopropargylic alcohols [25], These reagents are prepared by hydroboration of an enyne with catechol-borane in the presence of a Pd(0) catalyst possessing monodentate phosphine ligands. Dienylboranes were formed as minor products. Optimum results were obtained by treatment of the catecholborane with molar equivalents of triphenylpho-sphine and the palladium catalyst. Although several allenylboranes were prepared, only the dimethyl reagent was further examined. Treatment of that borane with benzaldehyde afforded the homopropargylic alcohol in 62% yield (Eq. 9.21). 

Table 9.16 Synthesis of homopropargylic alcohols from B-allenyl-9-BBN.

Acid chlorides were also shown to be reactive electrophiles. B-Allenyl-9-BBN affords tertiary bis-homopropargylic alcohols in satisfactory yields upon reaction with acetyl or benzoyl chloride (Eq. 9.23). 

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