Robinson annulation transform

Tran orm-based or long-range strategies The retrosynthetic analysis is directed toward the application of powerful synthesis transforms. Functional groups are introduced into the target compound in order to establish the retion of a certain goal transform (e.g., the transform for the Diels-Alder reaction, Robinson annulation, Birch reduction, halolactonization, etc.). 

Carbonyl condensation reactions are perhaps the most versatile methods available for synthesizing complex molecules. By putting a few fundamental reactions together in the proper sequence, some remarkably useful transformations can be carried out. One such example is the Robinson annulation reaction for tire synthesis of polycyclic molecules. The word annulation comes from the Latin annulus, meaning "ring," so an annulation reaction builds a new ring onto a molecule. 

In this example, the /3-diketone 2-methyJ-l,3-cyclopentanedione is used to generate the enolate ion required for Michael reaction and an aryl-substituted a,/3-unsaturated ketone is used as the acceptor. Base-catalyzed Michael reaction between the two partners yields an intermediate triketone, which then cyclizes in an intramolecular aldol condensation to give a Robinson annulation product. Several further transformations are required to complete the synthesis of estrone. 

Anionic domino processes are the most often encountered domino reactions in the chemical literature. The well-known Robinson annulation, double Michael reaction, Pictet-Spengler cyclization, reductive amination, etc., all fall into this category. The primary step in this process is the attack of either an anion (e. g., a carban-ion, an enolate, or an alkoxide) or a pseudo anion as an uncharged nucleophile (e. g., an amine, or an alcohol) onto an electrophilic center. A bond formation takes place with the creation of a new real or pseudo-anionic functionality, which can undergo further transformations. The sequence can then be terminated either by the addition of a proton or by the elimination of an X group. 

Since both oxidative splitting of the double bond and aldol condensation represent reliable and general reactions, their sequence serves as an efficient route for the transformation of readily available cyclohexene systems e.g. formed via the Diels-Alder reaction or Robinson annulation) into functionalized cyclopentene derivatives. This standard operational mode is extensively used in total syntheses. One of the numerous examples, the synthesis of helminthosporal 463, the sesquiterpenoid toxin of fungi, is shown in Scheme 2.150. In the initial phases of the synthesis, commercially available (—)-carvomenthone 464 was transformed into 465 via Michael reaction with methyl vinyl ketone to give 466 and subsequent intramolecular aldol condensation. 

A series of further transformations 10- - 11 were intended to create the functionality needed to form ring B. To achieve the Robinson annulation (see Section 2.3.3), 11 was formylated at C-8 and then reacted with ethyl vinyl ketone. This operation produced not only ring B, but introduced as well the... 

The Hajos-Parrish reaction can be regarded as the enantioselective version of the Robinson annulation. In the early stages of the synthetic effort targeting the mixed polyketide-terpenoid metabolite (-)-austalide B, L.A. Paquette and co-workers used this transformation to prepare the key bicyclic precursor in enantiopure form. Ethyl vinyl ketone was reacted with 2-methyl-1,3-cyclopentanedione in the presence of catalytic amounts of L-valine to afford the bicyclic diketone with a 75% ee. 

The next breakthrough was made by Pracejus in 1960 who also used alkaloids as catalysts, namely 0-acetlyquinine in the addition of methanol to phenylmethylke-tene in an impressive ee of 74 % [20]. Then in 1973 the (5)-proUne (27) catalysed Robinson annulation was discovered by Hajos and Parrish and independently by Wiechert and co-workers [21, 22]. High levels of enantioselectivity of up to 93 % were observed using 3 mol% of catalyst in the transformation which later became known as the Hajos-Parrish-Eder-Sauer-Wiechert reaction (Scheme 4.9). 

The more useful synthetic applications based on chemistry in this chapter are formation of allylic halides from conjugated dienes, Michael addition of organocuprates to conjugated compounds, and the Robinson annulation. The homework has synthetic problems that address these transformations. 

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