Robinson annulation cyclohexenone synthesis

The synthesis of cyclohexenone derivatives by Michael addition followed by intramolec ular aldol condensation is called the Robinson annulation, after Sir Robert Robinson who popularized its use By annulatwn we mean the building of a ring onto some start mg molecule (The alternative spelling annelation is also often used)... 

FUJIMOTO - BELLEAU Cyclohexenone Synthesis Synthesis of fused cyclohexenones from lactones (an alternative to the Robinson annulation). 

The first step of the Robinson annulation is simply a Michael reaction. An enamine or an enolate ion from a jS-keto ester or /3-diketone effects a conjugate addition to an a-,/3-unsaturated ketone, yielding a 1,5-diketone. But as we saw in Section 23.6,1,5-diketones undergo intramolecular aldol condensation to yield cyclohexenones when treated with base. Thus, the final product contains a six-membered ring, and an annulation has been accomplished. An example occurs during the commercial synthesis of the steroid hormone estrone (figure 23.9). 

Robinson annulation reaction (Section 23.12) A synthesis of cyclohexenones by sequential Michael reaction and intramolecular aldol reaction. 

The copper-catalyzed conjugate addition of methyl magnesium iodide to cyclohexenone and trapping the enolate as its trimethylsilyl enol ether, followed by a trityl hexachloro-antinomate-catalyzed Mukaiyama reaction, is apphed to / -(—jcarvone. C-2, C-3 functionalized chiral cyclohexanones are converted into their a-cyano ketones, which are submitted to Robinson annulation with methyl vinyl ketone. Highly functionalized chiral decalones are obtained that can be used as starting compounds in the total synthesis of enantiomerically pure clerodanes (equation 70). 

Enolate D of Figure 13.71 can undergo an aldol reaction with the C=0 double bond of the ketone. The bicyclic compound A is formed as the condensation product. It is often possible to combine the formation and the consecutive reaction of a Michael adduct in a one-pot reaction. The overall reaction then is an annulation of a cyclohexenone to an enolizable ketone. The reaction sequence of Figure 13.71 is the Robinson annulation, an extraordinarily important synthesis of six-membered rings. 

Finally, the presence of a cyclohexenone ring in the target suggests that a Robinson annulation might be employed in its synthesis ... 

Carbonyl condensation reactions are widely used in synthesis. One example of their versatility is the Robinson annulation reaction, which leads to the formation of substituted cyclohexenones. Treatment of a /8-diketone or fi-keto ester with an a,p-unsaturated ketone leads first to a Michael addition, which is followed by intramolecular aldol cyclization. Condensation reactions are also used widely in nature for the biosynthesis of such molecules as fats and steroids. 

Michael reaction with an o , S-unsaturated ketone followed by an intramolecular aldol reaction has proven to be a valuable method for the synthesis of 2-cyclohexenones. An especially important example of a Michael-aldol sequence is the Robinson annulation, in which treatment of a cyclic ketone, 8-ketoester, or S-diketone with an a,)8-unsaturated ketone in the presence of a base catalyst forms a cyclohexenone ring fused to the original ring. When the following racemic 8-ketoester, for example, is treated with methyl vinyl ketone in the presence of sodium ethoxide in ethanol, the Michael adduct forms and then, in the presence of sodium ethoxide, undergoes a base-catalyzed intramolecular aldol reaction followed by dehydration to give a racemic substituted cyclohexenone. 

Total syntheses of diterpenoid hydrokempenones have been accomplished by Paquette et al.,f using the Pd-catalyzed [3 + 2] cycloaddition methodology. One example is outlined on Scheme 43 and describes the synthesis of an isomeric compound 208 of 3/3-hydroxy-7/3-kemp-8(9)-en-6-one, a defense secretion agent of the neotropical species Nasutitermes octopilis. 3-AUcoxy-2-cyclohexenone 204 was efficiently functionalized and transformed to bicylic adduct 205 via a Robinson annulation reaction. Reduction of the double bond followed by condensation of dimethyl carbonate and oxidation gave the keto ester 206, which was treated with [2-(acetoxymethyl)-3-allyl]trimethylsilane, palladium acetate, and triisopropyl phosphite in refluxing tetrahydrofuran to afford a 98% yield of 207. Substituted methylenecyclopentane 207 was then functionalized by stereoselective reduction and protections, and final closure was done under basic conditions after an ozonolysis step. A modified Barton-McCombie reaction produced the desired tetracyclic adduct 208. 

To determine the starting materials needed for the synthesis of a 2-cyclohexenone by a Robinson annulation, first draw a line that bisects both the double bond and the (T bond between the jS- and y-carbons on the other side of the molecule. The 8-carbon comes from the o ,jS-unsaturated carbonyl compound the y-carbon is the a-carbon of the enolate ion of the second carbonyl compound that will add to the 8-carbon in the Michael reaction. The double bond was formed by the reaction of the enolate ion of the o , S-unsaturated carbonyl compound and the carbonyl carbon of the second carbonyl compound. 

The conjugate addition of enolate anions to activated 3-trimethylsilyl-3-buten-2-one helped solve another long-standing problem in organic synthesis by permitting the annulation reaction to be carried out in aprotic solvents under conditions where enolate equilibration is avoided. The annulation of thermodynamically unstable lithium enolates with MVK, where equilibration to the more stable enolate occurs prior to Michael addition, often yields a mixture of stractmal isomers. For exan le, Boeckman successfully employed 3-trimethylsilyl-3-buten-2-one in a Robinson annulation sequence (eq 2). Thus treatment of cyclohexenone with lithium dimethylcuprate in diethyl ether and then with 3-trimethylsilyl-3-buten-2-one gives the desired Michael adduct, which is converted into the functionalized octalone in 52% overall yield. ... 

The alcohol adducts from Q -(trimethylsilyl)vinyllithium and aldehydes have found many uses in organic synthesis. The ketones obtained by oxidation (eq 4) are especially good Michael acceptors and have been used in a modified Robinson annulation reaction for the construction of cyclohexenones. Cyclopropana-tion leads to cyclopropylsilane adducts, which can be converted into a variety of cyclopentenes (eq 5). Halogenation followed by stannylation gives synthons (eq 6) useful for making substituted vinylsilanes through radical reactions. ... 

Zhao and coworkers devised enantioselective syntheses of chiral cyclohexenones using primary-secondary diamine-catalyzed cascade reactions (Scheme 3.17). Diamine 13b promoted a cascade Michael-aldol-dehydration reaction between ketoester 77 and enones 78, affording highly functionalized chiral cyclohexenones 79 in good yields and with high enantioselectivities, although the diastereoselectiv-ity was poor [52]. The same group also applied a similar approach for an enantioselective synthesis of fluorinated cyclohexenones via Robinson annulation reaction [53]. 

Very recently, Kotsuki and coworkers reported an enantioselective Robinson annulation reaction for the synthesis of cyclohexenone derivatives bearing a quaternary center. Chiral vicinal diamine-chiral Bronsted acid conjugate 168 was found to be the optimal catalyst. The reactions afforded chiral cyclohexenone with moderate yields and good enantioselectivity [75], It was proposed that simultaneous enamine activation of donor and iminium activation of acceptor were involved in the catalytic cycle (Scheme 5.47). 

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