Esters retrosynthetic analysis

The only other functional group is the conjugated unsaturated ester. This functionality is remote from the stereocenters and the ketone functionality, and does not play a key role in most of the reported syntheses. Most of the syntheses use cyclic starting materials. Those in Schemes 13.4 and 13.5 lead back to a para-substituted aromatic ether. The syntheses in Schemes 13.7 and 13.8 begin with an accessible terpene intermediate. The syntheses in Schemes 13.10 and 13.11 start with cyclohexenone. Scheme 13.3 presents a retrosynthetic analysis leading to the key intermediates used for the syntheses in... 

In Yamada s retrosynthetic analysis (Scheme 11), elisabethin C (26) is traced back to lactone 64 which would be converted into 26 by deoxygenation and chain elongations. Key intermediate 64 could be obtained by a stereoselective Dieckmann cyclization. The required ester lactone precursor 65 would be accessible from 66 by a series of oxidation reactions. Further disconnection would lead to commercially available (+)-carvone (67). Stereoselective successive alkylation of 67 and reduction of the enone should deliver 66 [30]. 

The retrosynthetic analysis also involves disconnection of the "strategic bond" C(2)-C(3) and the sequence is very similar to that described above by Szychowski and MacLean Heading 75.2.5). The actual synthesis, however, rather than the intermediate 48b shown in Scheme 13.2.13 -whose hydrogenation leads to the wrong stereochemistry (51)- requires the tetrahydro derivative 52 from which ester 47b can be obtained stereoselectively by catalytic hydrogenation with Adam s... 

The structural similarity between claenone (42) and stolonidiol (38) enabled Yamada to exploit an almost identical strategy for the total synthesis of (-)-stolonidiol (38) [40]. A short retrosynthetic analysis is depicted in Fig. 12. An intramolecular HWE reaction of 68 was successfully applied for the macrocyclization. The highly substituted cyclopentanone 69 was made available by a sequence that is highlighted by the sequential Michael-Mi-chael addition between the enolate 53 and the a, -unsaturated ester 70 followed by a retro-aldol addition. However, as is the case for the claenone (42) synthesis, the synthesis of stolonidiol (38) is characterized by numerous functional and protecting group transformations that are a consequence of Yamada s synthetic strategy. 

In continuation of our investigations on asymmetric nucleophilic acylations with lithiated a-aminonitriles [40], we envisaged the asymmetric synthesis of 3-substituted 5-amino-4-oxo esters A, bearing both a-amino ketone and 5-amino ester functionalities (Scheme 1.1.14) [41]. Since a-amino ketones are precursors of chiral p-amino alcohols [42, 43] and chiral amines [43], their asymmetric synthesis has the potential to provide valuable intermediates for the synthesis of biologically active compounds, including peptidomimetics [44]. The retrosynthetic analysis of A leads to the a-aminoacyl carbanion B and p-ester carbocation... 

Borrelidin 1 has attracted attention because it inhibits angiogenesis, and so potentially blocks tumor growth, with an IC of 0.8 nM. Retrosynthetic analysis of 1 led the investigators to the prospective intermediates 2 and 3. To assemble these two fragments, they interatively deployed the elegant enantio- and diastereoselective intermolecular reductive ester aldol condensation that they had recently developed. This transformation is exemplified by the homologation of 4 to 6 catalyzed by the enantiomerically-pure Ir complex 5. 

SAMPLE SOLUTION (a) To apply the principles of retrosynthetic analysis to this case, we disconnect both ethyl groups from the tertiary carbon and identify them as arising from the Grignard reagent. The phenyl group originates in an ester of the type C6H5C02R (a benzoate ester). 

To begin the retrosynthetic analysis, note that the acetate ester is easily produced from the corresponding alcohol A. Therefore conversion of A to M using acetic anhydride/pyridine could be used in the synthetic step. (Remember For each retrosynthetic step, a reaction must be available to accomplish the synthetic step.)... 

Our retrosynthetic analysis for lipid I is presented below [Scheme 2], Our protected version of lipid I employed acetate protective groups for the carbohydrate hydroxyls, methyl esters for each of the carboxyl groups in the pentapeptide side chain, and trifluoroacetate for the terminal amino group of the lysine residue. These base-cleavable protective groups could be removed in a single operation in the final step of our synthesis and would not subject the sensitive diphosphate linkage to acidic reagents or reaction conditions. 

The preparation of (83) (Expt 8.29) is an example of the Hantzsch pyridine synthesis. This is a widely used general procedure since considerable structural variation in the aldehydic compound (aliphatic or aromatic) and in the 1,3-dicarbonyl component (fi-keto ester or /J-diketone) is possible, leading to the synthesis of a great range of pyridine derivatives. The precise mechanistic sequence of ring formation may depend on the reaction conditions employed. Thus if, as implied in the retrosynthetic analysis above, ethyl acetoacetate and the aldehyde are first allowed to react in the presence of a base catalyst (as in Expt 8.29), a bis-keto ester [e.g. (88)] is formed by successive Knoevenagel and Michael reactions (Section 5.11.6, p. 681). Cyclisation of this 1,5-dione with ammonia then gives the dihydropyridine derivative. Under different reaction conditions condensation between an aminocrotonic ester and an alkylidene acetoacetate may be involved. 

Cyclopropanecarboxylic acid may be prepared by a malonic ester synthesis, as retrosynthetic analysis shows. 

Previously, Ireland-Claisen ester-enolate rearrangement of the corresponding a-propionyloxy-allylsilane led to model system 5.44 Therefore, elaboration to 4 via rearrangement of 15 was pursued. To complete our retrosynthetic analysis, a plausible route to 15 was devised, involving straightforward homologation of 2P,3a-disubstituted cyclohexanone 17 to cyclohexene-carboxaldehyde 16, which in turn undergoes silylanion addition and subsequent acylation (Eq. 8). 

Let s try a synthesis. Suppose the target is ethyl 2-methyl-3-oxo-2-propylpentanoate. The presence of the /3-ketoester functionality suggests employing an alkylation reaction and/or an ester condensation. In one potential pathway, the propyl group can be attached by alkylation of a simpler /3-ketoester. Further retrosynthetic analysis suggests that the new target (ethyl 2-methyl-3-oxopentanoate) can be prepared from ethyl propanoate by a Claisen ester condensation. 

The diester has a 1,3-diCO relationship and could be disconnected but we have in mind using malonate so we would rather disconnect the alternative 3-amino carbonyl compound (the MezN group has a 1,3-relationship with both ester groups) by a 1,3-diX disconnection giving an unsaturated ester. This ot,p-unsaturated ester disconnects nicely to a heterocyclic aldehyde and diethyl malonate, doxplcomlne retrosynthetic analysis II... 

The next compound was needed by ICI when chemists there were developing a thromboxane antagonist to inhibit blood clot formation. You can immediately spot the 1,3-relationship between the ester and the hydroxyl group, so 1,3-diO disconnection is called for. thromboxane antagonist intermediate retrosynthetic analysis... 

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