Wolff rearrangement

Stereochemistry of α-diazo ketones

Understanding the stereochemistry of α-diazo ketones is essential in elucidating the mechanism of the Wolff rearrangement. α-diazocarbonyl compounds are generally locally planar, with large rotational barriers (55–65 kJ/mol) due to C-C olefin character between the carbonyl and α-carbon, illustrated in the rightmost resonance structure.^[6] Such a large barrier slows molecular rotations sufficiently to lead to an equilibrium between two conformers, an s-trans and s-cis-conformer. s-cis-Conformers are electronically favored due to Coulombic attraction between the oxygen with a partial negative charge and the cationic nitrogen, as seen in the rightmost resonance structure.^[1] If R₁ is large and R₂ is hydrogen, s-cis is sterically favored. If R₁ and R₂ are large, s-trans is sterically favored; if both substituents are sufficiently large, the steric repulsion can outweigh the Coulombic attraction, leading to a preference for s-trans. Small and medium cyclic substrates are constrained in the s-cis conformation.

Concerted mechanism

When the α-diazo ketone is in the s-cis conformation, the leaving group (N₂) and the migrating group (R₁) are antiperiplanar, which favors a concerted mechanism, in which nitrogen extrusion occurs concurrently with 1,2-alkyl shift. There is evidence this mechanism occurs in both thermolytic and photolytic methods, when the s-cis-conformer is strongly favored.^[7]

CIDNP studies show that photochemical rearrangement of diazoacetone, which largely exists in the s-cis-conformer, is concerted.^[8] Product ratios from direct and triplet-sensitized photolysis have been used as evidence for proposals that claim that concerted products arise from the s-cis-conformer and stepwise products occur through the s-trans-conformer.^[9]

Stepwise mechanism

s-trans-α-Diazo ketones do not have an antiperiplanar relationship between the leaving and migrating group, and thus are thought to generally rearrange stepwise. The stepwise mechanism begins with nitrogen extrusion, forming an α-ketocarbene. The α-ketocarbene can either undergo a 1,2-alkyl shift, to give the ketene product, or can undergo a 4π electrocyclic ring closure, to form an antiaromatic oxirene. This oxirene can reopen in two ways, to either α-ketocarbene, which can then form the ketene product.

There are two primary arguments for stepwise mechanisms. The first is that rate constants of Wolff rearrangements depend on the stability of the formed carbene, rather than the migratory aptitude of the migrating group.^[10] The most definitive evidence is isotopic scrambling of the ketene, as predicted by an oxirene intermediate, which can only occur in the stepwise path. In the scheme below, the red carbon is ¹³C labelled. The symmetric oxirene intermediate can open either way, scrambling the ¹³C label. If the substituents R₁ and R₂ are the same, one can quantify the ratio of products stemming from the concerted and stepwise mechanisms; if the substituents are different, the oxirene will have a preference in the direction it opens, and a ratio cannot be quantified, but any scrambling indicates some reactant is going through a stepwise mechanism.^[1] In photolysis of diazo acetaldehyde, 8% of the label is scrambled, indicating that 16% of product is formed via the oxirene intermediate.^[11] Under photolysis, the biphenyl (R1=R₂=phenyl) substrate shows 20–30% label migration, implying 40–60% of product goes through the oxirene intermediate.^[12] α-diazocyclohexanone shows no label scrambling under photolytic conditions, as it is entirely s-cis, and thus all substrate goes through the concerted mechanism, avoiding the oxirene intermediate.^[13]

Isotopic labeling studies have been used extensively to measure the ratio of product stemming from a concerted mechanism versus a stepwise mechanism.^[14] These studies confirm that reactants that prefer s-trans conformations tend to undergo stepwise reaction. The degree of scrambling is also affected by carbene stability, migratory abilities, and nucleophilicity of solvent. The observation that the migratory ability of a substituent is inversely proportional to amount of carbene formed, indicates that under photolysis, there are competing pathways for many Wolff reactions.^[14] The only Wolff rearrangements that show no scrambling are s-cis constrained cyclic α-diazo ketones.^[13]

Mechanistic conclusion

Under both thermolytic and photolytic conditions, there exist competing concerted and stepwise mechanisms. Many mechanistic studies have been carried out, including conformational, sensitization, kinetic, and isotopic scrambling studies. These all point to competing mechanisms, with general trends. α-Diazo ketones that exist in the s-cis conformation generally undergo a concerted mechanism, whereas those in the s-trans conformation undergo a stepwise mechanism.^[1] α-diazo ketones with better migratory groups prefer a concerted mechanism.^[1] However, for all substrates except cyclic α-diazo ketones that exist solely in the s-cis conformation, products come from a combination of both pathways.^[1] Transition metal mediated reactions are quite varied; however, they generally prefer forming the metal carbene intermediate.^[2] The complete mechanism under photolysis can be approximated in the following figure:

Migratory trends

The mechanism of the Wolff rearrangement is dependent on the aptitude of the migratory group. Migratory abilities have been determined by competition studies. In general, hydrogen migrates the fastest, and alkyl and aryl groups migrate at approximately the same rate, with alkyl migrations favored under photolysis, and aryl migrations preferred under thermolysis.^[15] Substituent effects on aryl groups are negligible, with the exception of NO₂, which is a poor migrator.^[15] In competition studies, electron deficient alkyl, aryl, and carbonyl groups cannot compete with other migrating groups, but are still competent.^[16][17][18] Heteroatoms, in general, are poor migratory groups, because their ability to donate electron density from their p orbitals into the π* C=O bond decreases migratory ability.^[1] The trend is as follows:^[1]

Photochemical reactions: H > alkyl ≥ aryl >> SR > OR ≥ NR2

Thermal reactions H > aryl ≥ alkyl (heteroatoms do not migrate)

Arndt-Eistert procedure

The Arndt–Eistert reaction^[19] involves the acylation of diazomethane with an acid chloride, to yield a primary α-diazo ketone. The carbon terminus of diazomethane adds to the carbonyl, to create a tetrahedral intermediate, which eliminates chloride. The chloride then deprotonates the intermediate to give the α-diazo ketone product.

These α-diazo ketones are unstable under acidic conditions, as the α-carbon can be protonated by HCl and S_N2 displacement of nitrogen can occur by chloride.

Franzen modification to Dakin-West reaction

The Dakin–West reaction is a reaction of an amino acid with an acid anhydride in the presence of a base to form keto-amides. The Franzen modification^[20] to the Dakin–West reaction^[21] is a more effective way to make secondary α-diazo ketones. The Franzen modification nitrosates the keto-amide with N₂O₃ in acetic acid, and the resulting product reacts with methoxide in methanol to give the secondary α-diazo ketone.

Diazo-transfer reactions

Diazo-transfer reactions are commonly used methods, in which an organic azide, usually tosylazide, and an activated methylene (i.e. a methylene with two withdrawing groups) react in the presence of a base to give an α-diazo-1,3-diketone.^[22] The base deprotonates the methylene, yielding an enolate, which reacts with tosylazide and subsequently decomposes in the presence of a weak acid, to give the α-diazo-1,3-diketone.

The necessary requirement of two electron withdrawing groups makes this reaction one of limited scope. The scope can be broadened to substrates containing one electron withdrawing group by formylating a ketone via a Claisen condensation, followed by diazo-transfer and deformylative group transfer.^[23]

One of the greatest advantages of this method is its compatibility with unsaturated ketones. However, to achieve kinetic regioselectivity in enolate formation and greater compatibility with unsaturated carbonyls, one can induce enolate formation with lithium hexamethyldisilazide and subsequently trifluoroacylate rather than formylate.^[24]

Homologation reactions

In the Arndt-Eistert homologation reaction, a carboxylic acid and thionyl chloride are reacted to generate an acid chloride. The acid chloride then reacts with diazomethane (R₂ = H), or occasionally a diazoalkyl, via the Arndt-Eistert procedure, to generate an α-diazo ketone, which will undergo a metal-catalyzed or photolyzed Wolff rearrangement, to give a ketene. The ketene can be trapped with any weak acid, such as an alcohol or amine, to form the ester or amide. However, trapping with water, to form the acid is the most common form.

In the most basic form, where R₂= H, RXH=H₂O, the reaction lengthens the alkyl chain of a carboxylic acid by a methylene. However, there is great synthetic utility in the variety of reactions one can carry out, by varying the diazoalkyl and weak acid. The migrating group, R₁ migrates with complete retention.^[2] A very useful application of the Arndt-Eistert homologation forms the homologated aldehyde by either trapping the ketene with N-methyl aniline and reducing with lithium aluminium hydride, or trapping the ketene with ethanethiol and reducing with Raney nickel.^[25][26]

There exist many hundreds of examples of the Arndt-Eistert homologation in the literature.^[27] Prominent examples in natural product total synthesis include the syntheses of (−)-indolizidine and (+)-macbecin.^[28][29] A recent example of the Arndt-Eistert homologation is a step in the middle stage of Sarah Reisman's synthesis of (+)-salvileucalin B.^[30]

Ring contractions

If the reactant is a cyclic α-diazo ketone, then Wolff-rearrangement products will be the one-carbon ring-contracted product. These reactions are generally concerted due to the s-cis conformation, and are photocatalyzed. The reaction below shows the concerted mechanism for the ring contraction of α-diazocyclohexanone, followed by trapping of the ketene with a weakly acidic nucleophile.

The first known example is the ring contracted Wolff rearrangement product of α-diazocamphor, and subsequent kinetic hydration of the ketene from the more sterically accessible "endo" face, to give exo-1,5,5-trimethylbicyclo[2.1.1]hexane-6-carboxylic acid.^[31]

Ring contractions have been used extensively to build strained ring systems, as ring size does not impede the Wolff rearrangement, but often impedes other reactions. There are many examples where the Wolff rearrangement is used to contract cyclopentanone to cyclobutane.^[32] The rearrangement is commonly used to form strained bicyclic and ring-fused systems. There exist a handful of examples of ring contractions from cyclobutanones to cyclopropanes.^[33] The Wolff rearrangement is capable of contracting cyclohexanones to cyclopentanes, but is infrequently used to do so, because the Favorskii rearrangement accomplishes this transformation and the Wolff precursor is often more challenging to synthesize.^[2] However, an example of a cyclohexanone ring contraction using deformylative diazo transfer, followed by a Wolff rearrangement, is Keiichiro Fukumoto's synthesis of (±)-∆⁹⁽¹²⁾-capnellene.^[34]

Cycloaddition reactions

Ketene intermediates produced via the Wolff rearrangement are well known to undergo [2 + 2] thermal cycloadditions with olefins to form four-membered rings in both intermolecular and intramolecular reactions, examples of both are shown below.^[35][36][37] Ketenes are able to undergo what is normally considered a forbidden [2 + 2] cycloaddition reaction because the ketene acts in an antarrafactial manner, leading to the Woodward-Hoffmann allowed [π_s² + π_a²] cycloaddition.^[36] Ketene [2 + 2] cycloadditions can be difficult reactions and give poor yields due to competing processes. The high energy aldoketene is very reactive and will cyclize with the diazo ketone starting material to produce butenolides and pyrazoles.^[2]

Ketene [2 + 2] cycloaddition reactions have been used in many total syntheses since Corey's use of the [2 + 2] cyclization in synthesizing the prostaglandins.^[35] Robert Ireland's synthesis of (±)-aphidicolin uses the Wolff rearrangement to do a tandem ring-contraction, and [2 + 2] cycloaddition.^[38]

The Danheiser benzannulation photolyses α-diazo ketones and traps with an alkyne, which undergoes a pericyclic cascade, to ultimately form versatilely substituted phenols.^[39] The first step in the benzannulation is the photolysis of an α-diazo ketone to form a vinylketene. The vinylketene then undergoes a [2 + 2] cycloaddition with an alkyne to form a 2-vinylcyclobutenone, which does a 4π electrocyclic ring-opening to generate a dienylketene. The dienylketene subsequently undergoes a 6π electrocyclic ring-closure followed by tautomerization, to form the phenolic benzannulated product.

Vinylogous Wolff rearrangements

The vinylogous Wolff rearrangement consists of a β,γ-unsaturated diazo ketone undergoing a Wolff rearrangement, and a formal 1,3-shift of the CH₂CO₂R group. The vinylogous Wolff rearrangement yields a γ,δ-unsaturated carboxylic acid derivative, which is the same retron as for the Claisen rearrangement. The variant was discovered when it was noticed that thermolysis of 1-diazo-3,3,3-triarylpropan-2-ones gave unexpected isomeric products.^[40]

Copper (II) and rhodium (II) salts tend to give vinylogous Wolff rearranged products, and CuSO₄ and Rh₂(OAc)₄ are the most commonly used catalysts.^[41] This is because they promote metal carbene formation, which can add to the olefin to form a cyclopropane, which can reopen via a retro [2 + 2] to form a formally 1,3-shifted ketene (vis-à-vis a normal Wolff rearranged ketene), which can be trapped by a nucleophile to give the vinylogous Wolff product.^[42]