Aldol condensation internal

The 3.8-nonadienoate 91, obtained by dimerization-carbonylation, has been converted into several natural products. The synthesis of brevicomin is described in Chapter 3, Section 2.3. Another royal jelly acid [2-decenedioic acid (149)] was prepared by cobalt carbonyl-catalyzed carbonylation of the terminal double bond, followed by isomerization of the double bond to the conjugated position to afford 149[122], Hexadecane-2,15-dione (150) can be prepared by Pd-catalyzed oxidation of the terminal double bond, hydrogenation of the internal double bond, and coupling by Kolbe electrolysis. Aldol condensation mediated by an organoaluminum reagent gave the unsaturated cyclic ketone 151 in 65% yield. Finally, the reduction of 151 afforded muscone (152)[123]. n-Octanol is produced commercially as described beforc[32]. 

The condensation of acetone can also occur over acidic sites as shown by a number of authors [1,9], Generally, when this occurs other products are formed such as isobutene and acetic acid, by the cracking of DAA. Additionally mesitylene can be formed by the internal 2,7-aldol condensation of 4,6-dimethylhepta-3,5-dien-2-one which is in turn obtained by the aldol condensation of MO with a deprotonated acetone molecule [7, 8], As these species are not observed we can concluded that any acidic sites on the silica support are playing no significant role in the condensation of acetone. 

In the crossed aldol condensation between carbonyl partners there are four possible product stereoisomers (eq. [1]). Consequently, there are two stereochemical aspects associated with the reaction The first deals with internal stereochemical control or diastereoselec-tion [A( ) vs. B( )], and the second deals with absolute stereochemi-... 

At 673 K the product distribution over the palladium catalysts (Figure 4) was still highly selective to MIBK (> 80%) however further aldol condensation of acetone with MO to form the three intermediates, phorone, 4,4 -dimethyl hepta-2,6-dione and 2,4-dimethyl hept-2,4-dien-6-one was observed. These species were formed by aldol condensation of acetone with MO at different points in the molecule (10). All can continue to react either by subsequent aldol condensation, Michael addition, or hydrogenation as per Figure 1. There was no detectable isophorone produced, the product of internal 1,6-aldol reaction of... 

The enone lactone 410 could also be obtained in a single operation from the ozonolysis in methanol of hemi-ketal [3 (118). In this reaction, 41 produced first the diketone 14 which underwent an internal aldol condensation to 415 which is nicely set up to give K) vi a the intermediate 416. 

Internal aldol condensations (condensations where both carbonyl groups are on the same chain) lead to ring formation. 

After Michael addition of 17 to 2-methyl-1,3-cyclohexanedione (19) and the first aldol condensation, the double bond in 20 is reduced to give 21. The acetoxy group in 21 is unmasked by hydrolysis and oxidation, and subsequent aldol condensation gives 22. Again, the terminal double bond in 22 is oxidized with PdCk to methyl ketone, and subsequent hydrogenation of the internal double bond affords the trione 23, from which the steroid A-ring 24 is formed by aldol condensation [34],... 

Pentanedione is in equilibrium with two enolate ions after treatment with base. Enolate A is stable and unreactive, while enolate B can undergo internal aldol condensation to form a cyclobutenone product. But, because the aldol reaction is reversible and the cyclobutenone product is highly strained, there is little of this product present when equilibrium is reached. At equilibrium, only the stable, diketone enolate ion A is present. 

This example is to illustrate procedure, not demonstrate the power of the method, therefore the choice of an olefin with relatively simple kinetics Cyclohexene exists only as internal a s-olefin, so that olefin isomerization and production of isomeric aldehydes and alcohols need not be considered, and the aldehyde formed carries its -CHO group on a secondary carbon atom, so that aldol condensation remains insignificant (these complications will be included in the next example). 

Substituted cyclopentenones ate formed by internal aldol condensation of y-diketones in the presence of basic catalysts. 

Certain substituted cyclohexenones are made by an analogous internal aldol condensation and decarboxylation of his-estets resulting from condensation of aldehydes with acetoacetic ester. 

Two different modes of reaction have been reported for steroidal A -3-ketones 20). Potassium persulphate in sulphuric acid gave the 4 0xa"3 ketone (23), considered to arise by an initial Baeyer-Villiger oxidation to the unsaturated lactone (21) as an enol lactone of the C(g)-aldehyde (22) this could suffer further degradation through a second Baeyer-Villiger attack on the aldehyde group [64], Other. workers [6 ] used peroxytrifluoroacetic acid and obtained the 5a-carboxy--4"Oxa 3-ketone (25) and the bridged product (26), apparently derived by an internal aldol condensation of the intermediate lactone-aldehyde (24). 

A further paper elaborates upon the internal aldol condensation of an 8,9-seco-8,9,11-trione to give so-called linear steroid analogues. ... 

Alkylation of isovaleramide with 1,3-dichlorobut-2-ene yields (139) after methyl-ation acid-catalysed hydrolysis and internal aldol condensation gives ( )-piperitone. The value of piperitenone and isopiperitenone formation, probably via electrocyclic reaction of the pyrolytic acetic acid-elimination product from A - and A -isomers of (49), cannot be assessed in the absence of reaction yields. (S)-(-)-Pulegone is obtained in good yield from (- )-citronellol by oxidation with pyridinium chlorochromate followed by double-bond isomerization. Low-temperature reduction of ( —)-carvone to ( —)-cz5-carveol (140) and... 

The important intermediate 66 of the steroid synthesis has been prepared by the application of the same reaction sequence to 2-methyl-1,3-cyclohexanedione (65) (Scheme 22). A synthesis of (+) 19-nortestosterone (69) starts with the Michael addition of the optically active oxo ester 67 to 1,7-octadien-3-one (59) catalyzed by sodium hydride, the ester group being removed by heating in aqueous HMPA with sodium iodide to give the dione 68. The aldol condensation catalyzed by sodium hydroxide proceeds in 90% yield. The terminal double bond is oxidized with PdCl2/CuCl to the methyl ketone and the internal olefinic double bond subsequently hydrogenated. The final reaction step involves aldol condensation in refluxing... 

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