Robinson annulation
The Robinson annulation is a chemical reaction in organic chemistry used to construct a six-membered carbocyclic ring fused to an existing ring system, typically forming a cyclohexenone derivative. It combines a Michael addition of a ketone enolate to an α,β-unsaturated carbonyl compound with an intramolecular aldol condensation, creating two new carbon-carbon bonds in a single process.[1][2]
Overview
This tandem reaction is highly efficient for building fused ring systems, making it a cornerstone of synthetic organic chemistry for complex polycyclic structures.[3]
General reaction
Under basic conditions, the reaction typically involves a cyclic ketone, such as cyclohexanone, and an α,β-unsaturated ketone like methyl vinyl ketone (MVK), yielding an α,β-unsaturated ketone product.[2][3]
Historical background
Developed in 1935 by British chemist Sir Robert Robinson and William S. Rapson during efforts to synthesize sterols, the reaction was first applied to a key intermediate in cholesterol synthesis.[4] Robinson, Nobel laureate in Chemistry in 1947 for work on plant products including alkaloids, recognized its potential for natural product synthesis.[1][5]
Overview
General reaction
The Robinson annulation is a tandem reaction comprising a Michael addition followed by an aldol condensation, which collectively forge a six-membered α,β-unsaturated ketone ring in organic synthesis. This process enables the efficient construction of nonaromatic carbocycles by linking a ketone enolate equivalent to an α,β-unsaturated carbonyl acceptor, ultimately yielding fused or spiro ring systems central to complex molecular architectures.[6]
In the canonical reaction, a ketone bearing an α-methylene group serves as the nucleophilic partner, undergoing conjugate addition to an α,β-unsaturated ketone such as methyl vinyl ketone (MVK), followed by cyclization to deliver a cyclohexenone product, often as a fused bicyclic motif.[2] For instance, 2-methylcyclohexanone and MVK react under basic conditions to produce an octalone derivative, exemplifying the method's utility in building angularly fused rings.
The annulation's prowess lies in its ability to assemble carbocyclic frameworks prevalent in natural products, particularly the 6-6 fused systems found in steroids and terpenoids, where it facilitates rapid access to the core scaffold through sequential carbon-carbon bond formations. While predominantly applied to six-membered ring annulations, the reaction's scope extends to other ring sizes via substrate tuning, such as employing cyclic enones or alternative Michael acceptors to generate five- or seven-membered rings in targeted syntheses.[2]
Historical background
The Robinson annulation was discovered in 1935 by British organic chemist Robert Robinson in collaboration with William S. Rapson, who reported a new method for synthesizing substituted cyclohexenones through the combination of a Michael addition and an aldol condensation.[4] This breakthrough emerged during Robinson's research at the University of Oxford aimed at constructing complex polycyclic structures found in natural products, particularly alkaloids and steroids, where efficient ring-forming strategies were essential for total synthesis efforts.[7]
The initial application of the annulation appeared in Robinson's synthetic approaches to cholesterol and related sterols, enabling the formation of two new carbon-carbon bonds in a single sequence to build the core ring system of these molecules.[3] This work was set against the backdrop of 1930s advancements in biogenetic theory, where Robinson pioneered hypotheses on alkaloid biosynthesis, linking microbial and plant pathways to structural elucidation and synthetic design.[8] His contributions to alkaloid research were recognized in the 1947 Nobel Prize in Chemistry, awarded for investigations into biologically important plant products, especially alkaloids; the annulation represented a separate innovative synthetic method for steroid frameworks.[9]
Following World War II, the Robinson annulation gained widespread adoption in steroid chemistry, facilitating scalable syntheses of hormone precursors amid growing demand for therapeutic steroids.[10] This evolution culminated in industrial applications, such as the production of estrone and the Wieland–Miescher ketone, where the reaction's efficiency in constructing fused ring systems supported pharmaceutical manufacturing processes.[2]
Mechanism
Core steps
The Robinson annulation proceeds through a sequence of two key transformations under basic conditions: a Michael addition followed by an intramolecular aldol condensation. The reaction typically employs alkoxide bases such as sodium ethoxide (NaOEt) in ethanol at reflux, which facilitates enolate generation and promotes both steps in a one-pot manner.[4] This ionic mechanism is classified as a [3+3] annulation, involving the formal combination of a 1,3-dicarbonyl equivalent and an α,β-unsaturated carbonyl acceptor to form a six-membered ring.
In the first step, base-catalyzed deprotonation of the starting ketone at the α-position generates a nucleophilic enolate, which undergoes conjugate addition to an α,β-unsaturated ketone acceptor, such as methyl vinyl ketone (MVK). This Michael addition yields a 1,5-diketone intermediate. For example, the enolate derived from cyclohexanone adds to MVK as follows:
\begin{align*}
&\ce{cyclohexanone + base ->[alpha position] enolate} \\
&\ce{enolate + CH2=CHC(O)CH3 -> 2-(CH2CH2C(O)CH3)cyclohexan-1-one}
\end{align*}
where the product is 2-(3-oxobutyl)cyclohexan-1-one.[11]
The second step involves deprotonation of the 1,5-diketone at the methyl group adjacent to one carbonyl, followed by intramolecular nucleophilic attack on the other carbonyl to form a β-hydroxy ketone intermediate via aldol addition. Subsequent dehydration eliminates water, yielding the α,β-unsaturated ketone product. This cyclization and elimination can be represented as:
\begin{align*}
&\ce{2-(3-oxobutyl)cyclohexan-1-one} \\
&\ce{->[base] cyclized β-hydroxy [ketone](/page/Ketone) ->[dehydration] fused α,β-unsaturated [ketone](/page/Ketone)}
\end{align*}
The overall transformation from cyclohexanone and MVK produces 4,4a,5,6,7,8-hexahydronaphthalen-2(3H)-one (also known as Δ^{9,10}-2-octalone).[4][12]
Stereochemistry
The Robinson annulation generates up to two new stereocenters during the process, one at the α-carbon of the donor ketone from the Michael addition and another at the carbon from the aldol addition (the ring fusion sites in the product).[13] In typical reactions involving cyclic ketones and methyl vinyl ketone, the product is a fused bicyclic system such as trans-octalone, where the ring fusion adopts a trans configuration due to the stability of the chair-chair conformation.[13]
Stereochemical control in the annulation arises from a combination of kinetic and thermodynamic factors. The Michael addition creates a stereocenter at the α-carbon of the donor. This center can epimerize under basic conditions due to the acidity of the adjacent α-proton, allowing equilibration to the more stable configuration that leads to the trans-fused product during the aldol step or dehydration. Under forcing conditions with excess base, thermodynamic control predominates, favoring the trans fusion with diastereoselectivities exceeding 95:5 in many cases.[14]
The geometry of the enone acceptor significantly influences facial selectivity in the Michael addition. For instance, in (E)-configured α,β-unsaturated ketones, the approach of the enolate donor is directed to the less hindered face, leading to predictable stereopatterns that propagate through the annulation; this mirrors aspects of Diels-Alder stereospecificity when the annulation is viewed as a stepwise alternative.[14]
A notable example of stereoselectivity is observed in the Hajos-Parrish-Eder-Sauer-Wiechert reaction, an organocatalytic variant using L-proline that achieves high enantioselectivity (up to 93% ee) and diastereoselectivity (>95:5 dr) in forming the trans-fused bicyclic enedione from 2-methylcyclohexane-1,3-dione and methyl vinyl ketone, with the acid-catalyzed dehydration step preserving the stereochemical integrity.
Variations
Standard conditions
The classic Robinson annulation is typically carried out under basic conditions using a strong base such as sodium ethoxide (NaOEt) or potassium tert-butoxide (KOtBu), often in a protic solvent like ethanol or an aprotic solvent such as toluene, with reflux for 4–24 hours to facilitate both the Michael addition and subsequent aldol condensation steps.[5] These conditions promote enolate formation from the ketone substrate while minimizing competing pathways, with the choice of base influencing the reaction rate and selectivity for simple cyclic or acyclic ketones paired with methyl vinyl ketone.[15]
Solvent effects play a key role in optimizing the reaction; protic solvents like ethanol solvate the ionic intermediates effectively at reflux temperatures (around 78°C), aiding proton transfer, whereas aprotic solvents such as toluene (reflux at ~110°C) allow for higher temperatures to drive the cyclization but require careful monitoring to prevent side reactions like self-condensation of the enone component.[5] Temperature control is essential, as excessive heat can lead to polymerization of the α,β-unsaturated ketone, while milder conditions may favor the initial Michael adduct over full annulation.[3]
Following the reaction, workup typically involves an acid quench (e.g., with dilute HCl) to effect dehydration of the β-hydroxy ketone intermediate, yielding the α,β-unsaturated enone product, followed by extraction with an organic solvent and purification by distillation or chromatography.[15] For simple substrates, overall yields range from 50–80%, though efficiency depends on substrate compatibility.[5] Key limitations include sensitivity to highly enolizable ketones, which can undergo over-alkylation or promote unwanted aldol side products, and the potential for enone polymerization under prolonged basic conditions.[5]
Substrate modifications
Substrate modifications in the Robinson annulation involve altering the standard ketone donor or the Michael acceptor to introduce functional groups, control regioselectivity, or access diverse ring-substituted products while maintaining the core Michael addition-aldol condensation sequence. These changes enhance the reaction's versatility for synthesizing complex polycyclic systems, particularly in natural product synthesis.
Ketone variations often employ β-ketoesters or 1,3-dicarbonyl compounds to generate enolates with enhanced acidity, leading to functionalized annulation products. For example, ethyl acetoacetate serves as an effective donor in the Michael addition, incorporating an ester group that remains intact through the subsequent aldol cyclization and dehydration, yielding 6-ethoxycarbonyl-substituted cyclohexenones suitable for decarboxylation or other transformations. Similarly, 2-methylcyclohexane-1,3-dione reacts with methyl vinyl ketone (MVK) to form the Wieland-Miescher ketone, a bicyclic enedione with a methyl substituent at the ring fusion, demonstrating how 1,3-dicarbonyl ketones enable the synthesis of highly functionalized decalones. Using simple alkyl-substituted cyclic ketones like 2-methylcyclohexanone with MVK produces octahydro-1H-naphthalenones with an angular methyl group, where the enolate forms preferentially at the less substituted alpha position to dictate regioselectivity in the Michael step.
Alternatives to MVK as the Michael acceptor expand the substitution pattern of the new ring, particularly for introducing aryl or alkyl groups. Chalcones, α,β-unsaturated ketones derived from benzaldehyde and acetophenone, act as acceptors to afford aryl-substituted cyclohexenones; for instance, chalcone undergoes annulation with ethyl acetoacetate under basic conditions to yield 6-ethoxycarbonyl-3,5-diphenylcyclohex-2-en-1-one, where the phenyl groups from the chalcone occupy the 3- and 5-positions of the product. Acrylates, such as ethyl acrylate, can serve as ester-functionalized acceptors in modified conditions, producing β-ketoester intermediates that cyclize to enone-esters, though yields may be lower due to the reduced electrophilicity compared to enones; this variation is useful for accessing products with ester groups at the beta position for subsequent reductions or cross-couplings.
The reaction exhibits good tolerance for certain functional groups on the substrates, allowing incorporation without interference in the base-catalyzed steps. Esters, as seen in β-ketoesters, survive the conditions and influence regioselectivity by directing enolate formation toward the more acidic methylene. Halides, such as chloro or bromo substituents on the aromatic ring of chalcone acceptors, are compatible, enabling halogenated products for palladium-catalyzed functionalizations, though alpha-haloketones may lead to side reactions via elimination. These tolerances arise from the mild basic conditions typically employed, minimizing nucleophilic attack on sensitive groups.
Despite its broad scope, the Robinson annulation has limitations with highly hindered substrates, where steric congestion impedes enolate approach or aldol cyclization. For example, α,α-disubstituted β-ketoesters or bulky cyclic ketones like 2,6-dimethylcyclohexanone often result in low yields or incomplete annulation due to unfavorable transition states in the Michael addition, necessitating aprotic conditions or alternative catalysts to overcome these barriers. Such hindered systems highlight the need for careful substrate design to avoid failed cyclizations and ensure efficient ring formation.
The Wichterle reaction represents a modification of the Robinson annulation wherein 1,3-dichloro-cis-2-butene serves as the Michael acceptor in place of methyl vinyl ketone, enabling the formation of substituted cyclohexenones under acidic conditions.[16] This variant facilitates regioselective alkylation during the Michael addition step, followed by intramolecular aldol condensation, and is particularly useful for introducing chlorine substituents that can be further functionalized.[16] Unlike the standard Robinson annulation, which relies on enolates from ketones, the Wichterle approach leverages the allylic dichloride for enhanced reactivity in protic media, altering the substitution pattern at the β-position of the enone product.[16]
The Hauser annulation extends the Robinson principle by employing phthalide anions as nucleophilic donors in a Michael addition to α,β-unsaturated carbonyl acceptors, followed by Dieckmann condensation and aromatization to yield fused quinone systems.[17] This reaction sequence typically involves deprotonation of the phthalide with a strong base like potassium tert-butoxide, addition to the acceptor, and subsequent cyclization with elimination of sulfinate if a sulfone is incorporated for umpolung.[17] A representative scheme is the reaction of 3-lithio- or 3-potassio-phthalide with methyl vinyl ketone, leading to 1,2-naphthoquinone derivatives after workup and oxidation:
Phthalide anion + CH2=CH-C(O)CH3 → Michael adduct → Dieckmann cyclization → β-ketoester → [decarboxylation](/page/Decarboxylation)/[aromatization](/page/Aromatization) → 1,2-naphthoquinone
Phthalide anion + CH2=CH-C(O)CH3 → Michael adduct → Dieckmann cyclization → β-ketoester → [decarboxylation](/page/Decarboxylation)/[aromatization](/page/Aromatization) → 1,2-naphthoquinone
This process differs from the carbocyclic Robinson annulation by incorporating an aromatic phthalide unit, resulting in fused quinones rather than simple alicyclic enones, and has been widely applied in angucycline synthesis.[17]
A double Robinson annulation involves sequential Michael additions and aldol condensations to construct angularly fused polycyclic systems, such as triquinanes, by treating a bis-enolizable ketone with excess methyl vinyl ketone under basic conditions.[18] This extension modifies the fusion pattern from the standard bicyclic output to more complex angular triquinane motifs, enhancing molecular rigidity for natural product scaffolds like quassinoids.[18]
The aza-Robinson annulation, an N-analog developed in 2023, utilizes cyclic imides as donors in a base-catalyzed conjugate addition to vinyl ketones, followed by acid-mediated cyclization to afford fused bicyclic amides with nitrogen incorporation at the ring junction.[19] Employing NaOEt for the Michael step and TfOH for the subsequent imide activation and aldol-type closure, this variant synthesizes piperidine-fused systems like (−)-coniceine.[19] In contrast to the all-carbon standard, the aza version introduces heteroatoms via the imide, altering the ring composition to include lactam functionality and enabling access to alkaloid frameworks.[19]
These related annulations diverge from the classic Robinson process primarily by varying the donor/acceptor components or reaction cascades, thereby introducing heteroatoms (as in aza- and Hauser variants) or expanding fusion patterns (as in double annulation) to access diverse heterocyclic or polycyclic architectures.[17][19][18]
Asymmetric methods
Asymmetric methods for the Robinson annulation focus on achieving high enantioselectivity and diastereoselectivity through chiral catalysts, enabling the synthesis of enantioenriched bicyclic enones. Organocatalytic approaches, particularly those employing proline or its derivatives, have been pivotal in the Hajos-Parrish variant, where L-proline catalyzes the tandem Michael addition and aldol condensation of a 2-methyl-1,3-cyclohexanedione with methyl vinyl ketone, affording the product in up to 95% ee. This seminal work demonstrated proline's bifunctional role in enamine formation for the Michael step and subsequent aldol cyclization, with enantioselectivities routinely exceeding 90% under mild conditions. Imidazolidinone catalysts, such as those developed by MacMillan, utilize iminium activation for the conjugate addition of α,β-unsaturated aldehydes to ketones, achieving enantioselectivities up to 96% and diastereoselectivities greater than 20:1 in representative examples. These methods excel in substrate scope for activated donors but face challenges with non-activated cyclic ketones due to lower reactivity.[20][21]
Metal-catalyzed strategies complement organocatalysis by enabling dynamic kinetic resolution (DKR) of racemic substrates. Chiral copper(II) complexes, often with bis(oxazoline) ligands, promote tandem decarboxylative Michael/aldol processes on α-aryl-α-hydroxyacetates with α,β-unsaturated ketones, delivering bicyclic products with enantioselectivities up to 92% ee and diastereoselectivities up to 10:1. These Lewis acid activations facilitate racemization at the α-position, allowing selective reaction with one enantiomer and broad applicability to aryl-substituted systems. Palladium complexes have been explored for related asymmetric allylic alkylations leading to annulation precursors, though with moderate enantioselectivities around 85% ee in select cases. Overall, metal methods provide orthogonal selectivity to organocatalysis but require careful ligand optimization to minimize side reactions.[22]
Recent advances emphasize one-pot asymmetric annulations, integrating multiple steps for efficiency. Proline-catalyzed double cascade sequences combining Knoevenagel condensation, hydrogenation, and Robinson annulation access Wieland-Miescher ketone analogues, achieving 99% ee and diastereoselectivities >95:5 in a streamlined process. Iminium-activated variants using chiral imidazolidinones have enabled enantioselective annulations with enals, yielding products with 94% ee in gram-scale reactions while addressing scalability issues through recyclable polymer-supported catalysts. Despite these progresses, challenges persist in scaling, including catalyst recovery and maintaining high selectivity under non-optimized conditions for complex substrates.[23][24]
Applications
Natural product syntheses
The Robinson annulation played a central role in early steroid synthesis, particularly through Robert Robinson's efforts in the 1930s to construct cholesterol and related sterols. Introduced in 1935 as a method for synthesizing substituted cyclohexenones relevant to sterol structures, the reaction allowed for the efficient formation of fused ring systems essential to the steroid nucleus.[25] Subsequent refinements, such as those by du Feu, McQuillin, and Robinson in 1937, expanded its application to more complex steroid frameworks, enabling key advances in understanding and replicating natural steroid architectures.[26] In modern contexts, the annulation remains vital for preparing cortisone precursors, exemplified by the Wieland–Miescher ketone—a product of annulating 2-methylcyclohexane-1,3-dione with methyl vinyl ketone—that serves as a versatile intermediate for total syntheses of corticosteroids like cortisone acetate.
In terpenoid synthesis, the Robinson annulation excels at building decalin cores characteristic of diterpenoids. A landmark application was its use in the first total synthesis of podocarpic acid, a resin acid structurally akin to abietic acid, achieved by Wenkert and Tahara in 1960 through annulation of 1-methyl-2-naphthol with methyl ethynyl ketone followed by further transformations.[27] This approach highlighted the reaction's utility in assembling the fused cyclohexenone moieties found in abietic acid and related podocarpic acids, which are derived from geranylgeranyl pyrophosphate in nature. For taxol-related terpenoids, the annulation constructs critical fragments; for instance, Banerjee and Carrasco employed it in 1983 to synthesize taxodione, a polycyclic diterpenoid precursor to taxol, by annulating a substituted cyclohexanone with methyl vinyl ketone to form the requisite enone ring.[28]
The annulation also facilitates alkaloid synthesis by enabling fused ring formations in tropane and indole systems. In tropane alkaloids, variants of the reaction, often termed aza-Robinson annulations, mimic biosynthetic pathways to construct the bridged bicyclic core, as seen in adaptations of Robinson's 1917 tropinone synthesis that incorporate Michael-aldol cascades for tropane fusions. For indole alkaloids, the standard carbocyclic annulation builds non-aromatic rings fused to the indole nucleus; classic examples include its role in total syntheses of Aspidosperma alkaloids like vincadifformine, where it assembles the quinolizidine moiety via enone formation from tryptamine-derived ketones.
Historically, the Robinson annulation's development in the 1930s revolutionized access to complex polycycles, enabling the first total syntheses of steroids and terpenoids prior to 1950 by providing a stereocontrolled route to angularly fused six-membered rings that were otherwise challenging to construct.[25] This impact extended to alkaloids, where it supported early biomimetic strategies for fused heterocycles, underscoring its enduring value in pre-1950 natural product chemistry.
Recent developments
In recent years, the Robinson annulation has continued to play a pivotal role in the total synthesis of complex natural products, with applications spanning terpenoids and alkaloids as highlighted in comprehensive reviews.[18] A notable advancement in 2023 introduced an aza-Robinson annulation strategy for constructing fused bicyclic amides, particularly relevant for alkaloid synthesis. This method employs a sodium ethoxide-catalyzed conjugate addition of cyclic imides to vinyl ketones, followed by triflic acid-mediated intramolecular aldol condensation, enabling the formation of fused piperidine systems with overall yields of 40–44% in four steps for targets like (±)-coniceine and quinolizidine 207D.[19] The approach demonstrates broad substrate scope, with isolated yields up to 91% for the two-step annulation, and regioselectivities ranging from 1:1 to 6.7:1 for substituted phthalimides, marking the first direct application of aza-Robinson annulation to these alkaloid scaffolds.[19]
Applications to diterpene synthesis have also seen renewed focus, with Robinson annulation facilitating the construction of substituted carbocyclic rings in terpenoid frameworks. A 2025 review underscores its utility in synthesizing selected diterpenes, emphasizing the reaction's efficiency in building the requisite fused ring systems essential for these C20 natural products.[29] For instance, organocatalytic variants, such as those using polystyrene-supported diamines, have been integrated into terpene routes, achieving high enantioselectivity in the annulation of methyl vinyl ketone with cyclic ketones like 2-methyl-1,3-cycloheptanone.[30]
Emerging integrations involve cascade sequences that enhance synthetic efficiency, such as the inherent Michael addition-aldol tandem in the aza-Robinson variant, which proceeds under mild base catalysis without requiring harsh conditions.[19] Trends toward sustainability are evident in organocatalytic protocols that reduce catalyst loadings and enable milder reaction temperatures, as seen in recent terpenoid syntheses, promoting greener alternatives to traditional base-promoted methods.[30] These developments highlight the Robinson annulation's adaptability, with selectivities and yields in modern applications often exceeding 80% for key intermediates.[18]