Unsaturated esters, alcohols from

Because the olefin geometry in compound 9 will most certainly have a bearing on the stereochemical outcome of the hydroboration step, a reliable process for the construction of the trans trisubsti-tuted olefin in 9 must be identified. A priori, the powerful and predictable Wittig reaction28 could be used to construct E u, [3-unsaturated ester 10 from aldehyde 11. Reduction of the ethoxycarbonyl grouping in 10, followed by benzylation of the resulting primary alcohol, would then complete the synthesis of 9. Aldehyde 11 is a known substance that can be prepared from 2-furylacetonitrile (12). 

In two studies toward the total synthesis of natural products it could be shown that the a,jS-unsaturated esters derived from the vinylogous Mukaiyama aldol reactions can be further functionalized into advanced intermediates. The C1-C7 segment of oleandolide commences with the VMAR of aldehyde 68 derived from the Roche ester. The so-generated stereo-triad was protected as PMB ether and the ester 76 was reduced to the allylic alcohol. Sharpless asym-... 

The construction of the alkenyl side chain and the control of the C9, CIO and Cll stereogenic centers was achieved from (5)-(+)-methyl 3-hydroxy-2-methylpropionate 1. (Scheme 21) This compound was transformed to aldehyde 99 in three steps. Bis(2,2,2)trifluoroethyl)[(methoxycabonyl)methyl]-phosphonate [23] was employed for the selective formation of the cA-a, 3-unsaturated ester 100. From this Z-unsaturated ester 100, the three consecutive asymmetric units were constructed via epoxide 101 (m-CPBA), which was selectively opened by lithium dimethylcuprate to produce 102. After deprotection-protection, the alcohol 102 was converted to the phosphonium iodide 103 via a tosylate intermediate(Scheme 21). 

Full details have been given for the synthesis of a variety of a-diazo-esters (113) and of chiral oc-thio-esters (114). a,8-Epoxy-esters (115) can be obtained from the parent unsaturated esters either by using a new epoxidation reagent prepared from fluorine gas and aqueous acetonitrile or lithium t-butylhydroperoxide ( ). When this latter reagent is added to unsaturated esters derived from chiral alcohols, reasonable diastereoselection is observed but, as yet, not enough (up to 60%) to rival the Sharpless method. All four isomers of the useful epoxy-esters [(116) (2R,3S) isomer] have been obtained from the... 

The insoluble surface slicks and thicker films of organic matter are interesting. On the open sea, these thin layers probably are primarily of natural origin and consist of C8-Cj2 fatty acids (both saturated and unsaturated), esters, alcohols, olefins, and alkanes (17, 18, 19, 20,16). Natural petroleum seeps, fats from decaying plants and animals, rainout from air, and coagulation of soluble organics by rising bubbles represent potential sources (21). 

S)-5-Hydroxymethyl-2(5H)-furanone (8), derived from D-ribono-lactone, was used as an intermediate in a synthesis of the 6a-carbocycline analogue (9), with a Pauson-Khand reaction being used to build up the ring system from enyne (10) (Scheme 4). When alcohol (8) underwent Diels-Alder reaction with cyclopentadiene, either the (2S, 3R)-isomer (11) or its enantiomer could be produced by appropriate manipulation of the initial adduct face-selective Lewis-acid-catalysed Diels-Alder reactions of a,iS-unsaturated esters derived from D-mannitol could be used to produce the (R,R)-isomer (12) or its enantiomer.This chemistry was extended to give syntheses of (+)-0-santalene (13) and its enantiomer from (8) the starting material was prepared as described in Vol. 20 p.260, but a number of other papers dealing with routes to this intermediate are mentioned in the next section. 

The (Z)-monolignols (hydroxycinnamyl alcohols) 49 were found along with their predominant ( )-isomers in a number of plants. Still-Gennarri reaction was successful applied to the preparation of (Z)-unsaturated esters 48 from aldehyde 47. The ester 48 was further converted to (Z)-coniferyl alcohol 49 in the synthesis of (Z)-monolignols. ... 

A terpene yielding isofenchyl alcohol on hydration, which Wallach considers to be one of the fenchenes, was artificially prepared by converting nopinone into a hydroxy ester by means of bromoacetic ester and zinc-dust. The hydroxy ester is dehydrated by potassium bisulphate, and so yields an unsaturated ester, which on saponification yields an acid from which the terpene results by distillation. This fenchene has the following characters —... 

A salient structural feature of intermediate 18 (Scheme 2b), the retrosynthetic precursor of aldehyde 13, is its y,r5-unsaturated ester moiety. As it turns out, the Johnson ortho ester variant of the Clai-sen rearrangement is an excellent method for the synthesis of y,<5-unsaturated esters.11 In fact, the Claisen rearrangement, its many variants included, is particularly valuable in organic synthesis as a method for the stereocontrolled construction of trans di- and tri-substituted carbon-carbon double bonds.12,13 Thus, it is conceivable that intermediate 18 could be fashioned in one step from allylic alcohol 20 through a Johnson ortho ester Claisen rearrangement. In... 

In an effort to make productive use of the undesired C-13 epimer, 100-/ , a process was developed to convert it into the desired isomer 100. To this end, reaction of the lactone enolate derived from 100-) with phenylselenenyl bromide produces an a-selenated lactone which can subsequently be converted to a,) -unsaturated lactone 148 through oxidative syn elimination (91 % overall yield). Interestingly, when 148 is treated sequentially with lithium bis(trimethylsilyl)amide and methanol, the double bond of the unsaturated lactone is shifted, the lactone ring is cleaved, and ) ,y-unsaturated methyl ester alcohol 149 is formed in 94% yield. In light of the constitution of compound 149, we were hopeful that a hydroxyl-directed hydrogenation52 of the trisubstituted double bond might proceed diastereoselectively in the desired direction In the event, however, hydrogenation of 149 in the presence of [Ir(COD)(py)P(Cy)3](PF6)53 produces an equimolar mixture of C-13 epimers in 80 % yield. Sequential methyl ester saponification and lactonization reactions then furnish a separable 1 1 mixture of lactones 100 and 100-) (72% overall yield from 149). 

A reiterative application of a two-carbon elongation reaction of a chiral carbonyl compound (Homer-Emmonds reaction), reduction (DIBAL) of the obtained trans unsaturated ester, asymmetric epoxidation (SAE or MCPBA) of the resulting allylic alcohol, and then C-2 regioselective addition of a cuprate (Me2CuLi) to the corresponding chiral epoxy alcohol has been utilized for the construction of the polypropionate-derived chain ]R-CH(Me)CH(OH)CH(Me)-R ], present as a partial structure in important natural products such as polyether, ansamycin, or macro-lide antibiotics [52]. A seminal application of this procedure is offered by Kishi s synthesis of the C19-C26 polyketide-type aliphatic segment of rifamycin S, starting from aldehyde 105 (Scheme 8.29) [53]. 

A variety of chiral amides as well as oxazolidones388 and imidazolidones389,390 may easily be prepared from amino alcohols that are derived from amino acids391 392. The addition of the lithium enolates of these amides under kinetically controlled conditions to a,/i-unsaturated esters yields optically active pentanedioates. Both syn- and //-5-amino-5-oxopcntanoates may be obtained with good diastereomeric ratios192. 

Oxidation Processes Scheidt and co-workers have employed cascade oxidation pathways from aUyhc or propargylic alcohols to afford unsaturated ester products 25. In situ oxidation of an unsaturated alcohol 21 to the enal 22 using MnO, ... 

The enantioselective synthesis in Scheme 13.22 is based on stereoselective reduction of an a, (3-unsaturated aldehyde generated from (—)-(.V)-limonene (Step A). The reduction was done by Baker s yeast and was completely enantioselective. The diastereoselectivity was not complete, generating an 80 20 mixture, but the diastere-omeric alcohols were purified at this stage. After oxidation to the aldehyde, the remainder of the side chain was introduced by a Grignard addition. The ester function... 

Conversion of ketone 80 to the enol silane followed by addition of lithium aluminum hydride to the reaction mixture directly provides the allylic alcohol 81 [70]. Treatment of crude allylic alcohol 81 with tert-butyldimethylsilyl chloride followed by N-b ro m o s u cc i n i m i de furnishes the a-bromoketone 82 in 84 % yield over the two-step sequence from a.p-unsaturated ester 80. Finally, a one-pot Komblum oxidation [71] of a-bromoketone 82 is achieved by way of the nitrate ester to deliver the glyoxal 71. It is worth noting that the sequence to glyoxal 71 requires only a single chromatographic purification at the second to last step (Scheme 5.10). 

After successful installation of the first two stereocenters, our attention was focused on elaboration of the terminal alkene in 64 (Scheme 6.9). Treatment with disiamylborane followed by oxidative workup afforded primary alcohol 65 in good yield (70-85 %). A side product containing a mixture of two diastereomers (66) was also observed and resulted from conjugate addition of the alkoxide formed during basic workup onto the unsaturated ester. Maintaining the temperature at 0 °C by a slow, dropwise quench during the oxidative workup was necessary to minimize the amount of the undesired cyclization product (66). Subsequent oxidation of the primary alcohol 65 using Dess-Martin periodinane [28] and a Pinnick oxidation afforded carboxylic acid 67 [29]. 

Hydroboration and oxidation of 160 yields an alcohol that is subsequently oxidized with PDC to give ketone compound 161. Enolization and triflation converts this compound to enol triflate 162, which can be further converted to x,/i-unsaturated ester 163 upon palladium-mediated carbonylation methox-ylation. The desired alcohol 164 can then be readily prepared from 163 via DIBAL reduction. Scheme 7 50 shows these conversions. 

Reduction of the enolizable keto ester 477 supplied two alcohols, 479 and 480, from both of which the same unsaturated ester 481 could be obtained by easy water elimination. Accordingly, the reduction of 478 yielded alcohols 482, 483, and 484 in addition to 479 and 480 derivable from 477, formed by previous C-18 epimerization of 478. Water elimination of 482 gave 18a-methoxyapoalloyo-himbine (485). By demethylating the three major products 479, 480, and 482, the corresponding C-18-hydroxy derivatives 486, 487, and 488 could be prepared. 

The group name is intended to cover esters derived from sulfenic, sulfinic and sulfonic acids, some of which are thermally unstable. This is especially so for esters of unsaturated alcohols, which are also liable to polymerise, catalysed by the liberated acids. Individually indexed compounds are ... 

Unsaturated alcohols can be obtained from unsaturated esters under special precautions. Catalytic hydrogenation over zinc chromite converted butyl oleate to oleyl alcohol (9-octadecenol) in 63-65% yield even under very energetic conditions (283-300°, 200atm) [52]. 

Treatment of the alcohol ( ) with trifluoromethylsulfonic anhydride (triflic anhydride) at -78 C afforded the ester (1 ) which could be isolated and characterized. We knew from previous experience (2J that sulfonyl esters vicinal to an isopropylidene acetal are relatively stable. The triflate T,) reacted cleanly with potassium azide and 18-crown-6 in dichloromethane at room temperature. The crystalline product [68% overall from (1 )] was not the azide ( ) but the isomeric A -triazoline ( )- Clearly the initially formed azide (18) had undergone intramolecular 1,3-cyclo-addition to the double bond of the unsaturated ester (21- ). The stereochemistry of the triazoline (1 ), determined by proton nmr spectroscopy, showed that the reaction was stereospecific. There are several known examples of this reaction ( ), including one in the carbohydrate series ( ). When the triazoline was treated with sodium ethoxide ( ) the diazoester ( ) was rapidly formed by ring-opening and was isolated in 85% yield, Hydrogenolysis of the diazo group of (M) gave the required pyrrolidine ester ( ) (90%). 

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