Dialdehydes intramolecular aldol reaction

Intramolecular Aldol Reaction Starting from Dialdehydes... 

The situation is complex. In another study we examined the cyclization of compound 54 catalyzed by cyclodextrin bis-imidazoles [140]. This dialdehyde can perform the intramolecular aldol reaction using the enol of either aldehyde to add to the other aldehyde, forming either 55 or 56. In solution with simple buffer catalysis both compounds are formed almost randomly, but with the A,B isomer 46 of the bis-imidazole cyclodextrin there was a 97 % preference for product 56. This is consistent with the previous findings that the catalyst promotes enolization near the bound phenyl ring, but in this case the cyclization is most selective with the A,B isomer 46, not the A,D that we saw previously. Again the enolization is reversible, and the selectivity reflects the addition of an enol to an aldehyde group. The predominant product is a mixture of two stereoisomers, 56A and 56B. Both were formed, and were racemic despite the chirality of the cyclodextrin ring. 

Intramolecular aldol reaction. The regioselectivity of the intramolecular aldol coiulensalion of the dialdehyde (I) Ls markedly affected by the base used. Thus use of-... 

An exception to the generalization that the enamine of the more hindered aldehyde acts as the nucleophilic arm in intramolecular aldol reactions of unsymmetrical dialdehydes is seen in equation (103). -2 The regioselectivity of this cyclization is apparently very high none of the other isomer was detectable by HPLC or NMR the 57% yield quoted is the overall yield of the alcohol obtained by sodium borohy-... 

As stated above, the studies of Wieland and Miescher, as well as Woodward, on the intramolecular aldol reaction of diketones and dialdehydes were encouraged by this previous work. Wieland, Miescher, and Woodward studied the application of the intramolecular aldol reaction, catalyzed by secondary amine salts, to the synthesis of steroids and believed that their aldolizations proceed via enamine intermediates [ 10]. This was corroborated by the mechanistic studies carried out by Spencer in 1965 [11]. Based on these works, Hajos and Parrish (1974) andEder, Sauer, and Wiechert... 

Draw the two different aldol products that result from intramolecular aldol reactions involving the di-aldehyde 3-methylhexanedial and base. For each product indicate which aldehyde of the dialdehyde acted as a nucleophile and which acted as an electrophile. Call the ends the 1-aldehyde and the 6-aldehyde. 

In order to gain more insight into this proposed mechanism, Montgomery and co-workers tried to isolate the intermediate metallacycle. This effort has also led to the development of a new [2 + 2 + 2]-reaction.226 It has been found that the presence of bipyridine (bpy) or tetramethylethylenediamine (TMEDA) makes the isolation of the desired metallacycles possible, and these metallacycles are characterized by X-ray analysis (Scheme 56).227 Besides important mechanistic implications for enyne isomerizations or intramolecular [4 + 2]-cycloadditions,228 the TMEDA-stabilized seven-membered nickel enolates 224 have been further trapped in aldol reactions, opening an access to complex polycyclic compounds and notably triquinanes. Thus, up to three rings can be generated in the intramolecular version of the reaction, for example, spirocycle 223 was obtained in 49% yield as a single diastereomer from dialdehyde 222 (Scheme 56).229... 

The proline-mediated intramolecular aldol condensation of dialdehyde substrates was also reported by List in 2003, affording enantioselective synthesis of cyclic p-hydroxy aldehydes via a 6-e ofexo-aldolization reaction (Scheme 11.7d). 

Wittig-Homer reaction with 1,4- and 1,5-dialdehydes.1 Reaction of these aldehydes with 1 equiv. of a Wittig-Horner phosphonate in an aqueous medium with K2C03 as base is accompanied by an intramolecular aldolization to provide five- or six-membered cycloalkenols. 

The Hajos-Parrish-Eder-Sauer-Wiechert synthesis (Scheme 5) was the first example of an intramolecular proline-catalyzed asymmetric aldol reaction. Systematically, this reaction can be described as a 6-enolendo cyclization. In 2003, List et al. described the first example of an intramolecular enolexo aldolization 85). This approach was then used by Pearson and Mans for the synthesis of (-i-)-cocaine 92, starting from the weso-dialdehyde 90 on treatment with (S)-12 86). This desymmetrization process gave 91 as a mixture of epimers with good enantio-selectivity. The tropane skeleton 91 could be further transformed into +)-92 by conventional means (Scheme 21). 

Keeping in mind that 1 was projected as a key intermediate for the synthesis of a variety of steroids, the Woodward group next turned to contraction of the D-ring to the required acyl cyclopentene. The diol was liberated and cleaved to a dialdehyde using periodic acid. The dialdehyde was then subjected to piperidinium ion mediated intramolecular aldol-dehydration to provide 18. The aldol-dehydration also provided the regioisomeric enal as a minor product. The regioselectivity of this reaction was attributed to the apparent steric accessibility of the C17 methylene in the intermediate dialdehyde relative to the C15 methylene. The synthesis of 1 was completed in a straightforward manner. 

A different behavior is exhibited by naphthalene-1,8-dicarbocal-dehyde (73). No m-naphthane derivatives are obtained on reaction with nitromethane, nitroethane or other methylene components. The basic medium, required for aldol type additions, causes the dialdehyde to undergo Cannizzaro reaction to the naphthopyranon (74) via an intramolecular 1,5-hydride shift, which is sterically favoured by the peri-position of the two aldehyde functions 28). 

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