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Aza-Cope rearrangement

August 24, 2023

Rearrangements, especially those that can participate in cascade reactions, such as the aza-Cope rearrangements, are of high practical as well as conceptual importance in organic chemistry, due to their ability to quickly build structural complexity out of simple starting materials. The aza-Cope rearrangements are examples of heteroatom versions of the Cope rearrangement, which is a [3,3]-sigmatropic rearrangement that shifts single and double bonds between two allylic components. In accordance with the Woodward-Hoffman rules, thermal aza-Cope rearrangements proceed suprafacially.[1] Aza-Cope rearrangements are generally classified by the position of the nitrogen in the molecule (see figure):

Aza-Cope rearrangement
Named after Arthur C. Cope
Reaction type Rearrangement reaction
Identifiers
RSC ontology ID RXNO:0000197
The 1,2, and 3 aza-Cope rearrangements

The first example of an aza-Cope rearrangement was the ubiquitous cationic 2-aza-Cope rearrangement, which takes place at temperatures 100-200 °C lower than the Cope rearrangement due to the facile nature of the rearrangement.[2] The facile nature of this rearrangement is attributed both to the fact that the cationic 2-aza-Cope is inherently thermoneutral, meaning there's no bias for the starting material or product, as well as to the presence of the charged heteroatom in the molecule, which lowers the activation barrier. Less common are the 1-aza-Cope rearrangement and the 3-aza-Cope rearrangement, which are the microscopic reverse of each other. The 1- and 3-aza-Cope rearrangements have high activation barriers and limited synthetic applicability, accounting for their relative obscurity.[3][4][5]

To maximize its synthetic utility, the cationic 2-aza-Cope rearrangement is normally paired with a thermodynamic bias toward one side of the rearrangement. The most common and synthetically useful strategy couples the cationic 2-aza-Cope rearrangement with a Mannich cyclization, and is the subject of much of this article. This tandem aza-Cope/Mannich reaction is characterized by its mild reaction conditions, diastereoselectivity, and wide synthetic applicability. It provides easy access to acyl-substituted pyrrolidines, a structure commonly found in natural products such as alkaloids, and has been used in the synthesis of a number of them, notably strychnine and crinine.[6] Larry E. Overman and coworkers have done extensive research on this reaction.[1]

The cationic 2-aza-Cope rearrangement

 

The cationic 2-aza-Cope rearrangement, most properly called the 2-azonia-[3,3]-sigmatropic rearrangement, has been thoroughly studied by Larry E. Overman and coworkers. It is the most extensively studied of the aza-Cope rearrangements due to the mild conditions required to carry the arrangement out, as well as for its many synthetic applications, notably in alkaloid synthesis. Thermodynamically, the general 2-aza-Cope rearrangement does not have a product bias, as the bonds broken and formed are equivalent in either direction of the reaction, similar to the Cope rearrangement. The presence of the ionic nitrogen heteroatom accounts for the more facile rearrangement of the cationic 2-aza-Cope rearrangement in comparison to the Cope rearrangement. Hence, it is often paired with a thermodynamic sink to bias a rearrangement product.[1]

In 1950, Horowitz and Geissman reported the first example of the 2-aza-Cope rearrangement, a surprising result in a failed attempt to synthesize an amino alcohol.[2] This discovery identified the basic mechanism of the rearrangement, as the product was most likely produced through a nitrogen analog of the Cope rearrangement. Treatment of an allylbenzylamine (A) with formic acid and formaldehyde leads to an amino alcohol (B). The amino alcohol converts to an imine under addition of acid (C), which undergoes the cationic 2-aza-Cope rearrangement (D). Water hydrolyses the iminium ion to an amine (E). Treating this starting material with only formaldehyde showed that alkylation of the amine group occurred after the cationic 2-aza-Cope rearrangement, a testament to the quick facility of the rearrangement.[2]

 
Horowitz and Geissman report the first aza-Cope rearrangement. This also exemplifies one of the many methods for carrying out iminium ion formation by reductive amination.

Due to the mild heating conditions of the reaction carried out, unlike the more stringent ones for a purely hydrocarbon Cope rearrangement, this heteroatomic Cope rearrangement introduced the hypothesis that having a positive charge on a nitrogen in the cope rearrangement significantly reduces the activation barrier for the rearrangement.[2]

Reaction mechanism

Rate acceleration due to positively charged nitrogen

 

The aza-Cope rearrangements are predicted by the Woodward-Hoffman rules to proceed suprafacially. However, while never explicitly studied, Overman and coworkers have hypothesized that, as with the base-catalyzed oxy-Cope rearrangement, the charged atom distorts the sigmatropic rearrangement from a purely concerted reaction mechanism (as expected in the Cope rearrangement), to one with partial diradical/dipolar character, due to delocalization of the positive charge onto the allylic fragment, which weakens the allylic bond. This results in a lowered activation barrier for bond breaking. Thus the cationic-aza-Cope rearrangement proceeds more quickly than more concerted processes such as the Cope rearrangement.[6][7]

Transition state and stereochemistry

The cationic 2-aza-Cope rearrangement is characterized by its high stereospecificity, which arises from its high preference for a chair transition state. In their exploration of this rearrangement's stereospecificity, Overman and coworkers used logic similar to the classic Doering and Roth experiments,[8] which showed that the Cope rearrangement prefers a chair conformation.[9] By using the cationic 2-aza-Cope/Mannich reaction on pyrrolizidine precursors, they showed that pyrrolizidines with cis substituents from E-alkenes and trans substituents from Z-alkenes are heavily favored, results that are indicative of a chair transition state. If a boat transition state was operative, the opposite results would have been obtained (detailed in image below).[9] As is the trend with many reactions, conversion of the Z-enolate affords lower selectivity due to 1,3 diaxial steric interactions between the enolate and the ring, as well as the fact that substituents prefer quasi-equatorial positioning. This helps explain the higher temperatures required for Z-enolate conversion.[6][9] The boat transition state is even less favored by the cationic-2-aza-Cope rearrangement than it is for the Cope rearrangement: in analogous situations to where the Cope rearrangement takes on a boat transition state, the aza-Cope rearrangement continues in the chair geometry.[1][6][10] These results are in accord with computational chemistry results, which further assert that the transition state is under kinetic control.[11]

 
The rearrangement is shown, as well as the reaction's final products. E-alkenes are pictured in the top half, Z-alkenes in the bottom half. Operative chair transition states are detailed first, boat transition states second. Major products are labeled, and unobserved minor products of boat transition states are depicted. Blue dashed lines indicate a σ bond being broken, red dashed lines indicate a σ bond being formed.

Significantly, these stereochemical experiments imply that the cationic 2-aza-Cope rearrangement (as well as Mannich cyclization) occur faster than enol or iminium tautomerization. If they were not, no meaningful stereochemistry would have been observed, highlighting the facility of this fast reaction.[1]

Additional considerations for stereochemistry

The aza-Cope/Mannich reaction, when participating in ring-expanding annulations, follows the stereochemistry dictated by the most favorable chair conformation, which generally places bulky substituents quasi-equatorially. The vinyl and amine components can have either syn or anti relationships when installed on a ring. This relationship is typically dictated by the amine substituent: bulky substituents lead to syn aza-Cope precursors. While anti vinyl and amine substituents generally only have one favored transition state, leading to a cis fused ring system, the favored product of syn substituents can change, dictated by steric interactions with solvents or large N-substituents, which may take preference over bulky substituents and change the transition state.[12][13]

 
anti starting materials generally lead to cis products. syn starting materials lead to an assortment of products, dependent on the nitrogen substituent's bulk, as shown. Blue denotes σ bond breaking, red denotes σ bond formation.

For simple aza-Cope/Mannich reactions that do not participate in ring-expanding annulation, namely condensations of amino alcohols and ethers, bond rotation occurs more quickly than the Mannich cyclization, and racemic products are observed.[14] This can be avoided by using a chiral auxiliary substituent on the amine. Reactions tethered to rings cannot undergo these bond rotations.[1]

 
Bond rotation leading to racemic product. The aza-Cope rearrangement proceeding the bond rotation is omitted for clarity.

Possible thermodynamic sinks for biasing a rearrangement product

Horowitz and Geissman's first example demonstrates a possible thermodynamic sink to couple with the cationic 2-aza-Cope rearrangement, where the product is biased by the phenyl substituent through aryl conjugation, then captured by hydrolysis of the iminium. Other methods of biasing a product include using substituents which are more stable on substituted carbons, releasing ring strain (for instance, by pairing the rearrangement with cyclopropane opening), intramolecular trapping (pictured), and pairing the rearrangement with the Mannich cyclization.[1][15]

 
The iminium is trapped by the intramolecular nucleophile.

The aza-Cope/Mannich reaction

 
The aza-Cope/Mannich reaction

The aza-Cope/Mannich reaction is a synthetically powerful reaction, as it is able to create complex cyclic molecules from simple starting materials. This tandem reaction provides a thermodynamic bias towards one rearrangement product, as the Mannich cyclization is irreversible and its product, an acyl substituted pyrrolidine ring, more stable than that of the rearrangement.[1][16]

The first aza-Cope/Mannich reaction

Overman and coworkers recognized that the cationic 2-aza-Cope rearrangement could potentially be synthetically powerful if an appropriate thermodynamic sink could be introduced. Their logic was to incorporate a nucleophilic substituent into the starting material, namely an alcohol group, which acts only after rearrangement, converted into an enol primed to attack the iminium ion.

This first report of the reaction was a reaction between aldehydes and 2-alkoxy-3-butenamines, which formed an amino alcohol whose aza-Cope/Mannich reaction product was an acyl-substituted pyrrolidine ring. This simple procedure only involved mild heating for several hours. Significantly, the aza-Cope/Mannich reaction occurs in a single step with excellent yield. This procedure is easily applied to condensation of amino ethers (shown below), where the alcohol has been methylated first.[16] After the aza-Cope/Mannich reaction is carried out, the ketone is formed by addition of NaOH.[16] The amine, in this simple case, cannot form the iminium ion from basic ketones; subsequent methods found ways of incorporating ketones into the reaction.[16][17] The utility of this reaction is evident in the fact that even when a less stable isomer is formed, the reaction proceeds, demonstrating its high thermodynamic favorability.[12][17]

 
This reaction occurred in a single step. The reaction was heated for 5 hours in refluxing benzene. NaOH was added to form the ketone at the final step. Yields typically are around 90%, varying slightly with different substituents.

Reaction mechanism

 

The general product of the reaction can potentially occur via two separate pathways: the aza-Cope/Mannich reaction, or an aza-Prins cyclization/pinacol rearrangement. These mechanisms have different stereochemical properties, which elucidate the dominance of the aza-Cope/Mannich reaction. The aza-Cope/Mannich reaction forces each atom in the [1,5] diene analog to undergo sp2 hybridization, erasing the starting material's stereochemistry at the labelled R' position, while the aza-Prins/pinacol rearrangement retains stereochemistry at the labelled R' position, pointing to a simple test that reveals the active mechanism. An enantiomerically pure starting material at the "R'" position should lead to a racemic product if the dominant mechanism is the aza-Cope/Mannich reaction, while the stereochemistry should be retained if the dominant mechanism is an aza-Prins cyclization/pinacol rearrangement pathway. A simple experiment verified that the product was racemic, providing clear evidence of the aza-Cope Mannich reaction as the operative mechanism. Further experiments verified this, using the knowledge that the carbenium ion formed in an aza-Prins/pinacol pathway would be effected by its substituent's ability to stabilize its positive charge, thus changing the reactivity of the pathway. However, a variety of substituents were shown to have little effect on the outcome of the reaction, again pointing to the aza-Cope Mannich reaction as the operative mechanism.[14] Recent literature from the Shanahan lab supports the rare aza-Prins/pinacol pathway only associated with significantly increased alkene nucleophilicity and iminium electrophilicity.[1][6][18][19]

The aza-Cope/Mannich reaction shows high diastereoselectivity, generally in accordance the results of the stereochemical experiments elucidating the transition state of the cationic 2-aza-Cope rearrangement, which follows as this tandem reaction pathway was an integral part of these experiments. The stereochemistry of the rearrangement is slightly more complicated when the allyl and amine substituents are installed on a ring, and thus cis or trans to one another.

The aza-Cope/Mannich reaction starting material, the amino alcohol, can also be thought of as related to the oxy-Cope rearrangement (below), both for its rate acceleration due to ionic involvement, as well as the analogous enol collapsing function of the Mannich cyclization and the keto-enol tautomerization in the oxy-Cope rearrangement.[7]

 
The oxy-Cope rearrangement

Synthetic applications of the 2-aza-Cope/Mannich reaction

The aza-Cope/Mannich reaction is often the most efficient way to synthesize pyrrolidine rings, and thus has a number of applications in natural product total syntheses. Because of its diastereoselectivity this reaction has added to the catalog of asymmetric synthesis tools, as seen in the many examples of asymmetric alkaloids synthesized using the reaction. As we have seen in the first aza-Cope/Mannich reaction and in the elucidation of the reaction's stereochemistry, the aza-Cope/Mannich reaction can be used to form pyrrolidine rings and pyrrolizidine rings. It can be used to create many additional ring structures useful in synthesis, such as indolizidine cycles and indole rings.[1][7]

(−)-Strychnine total synthesis

Main article: Strychnine total synthesis

The classic example demonstrating the utility of this reaction is the Overman synthesis of strychnine. Strychnine is a naturally occurring highly poisonous alkaloid, found in the tree and climbing shrub genus Strychnos. Strychnine is commonly used as a small vertebrate pesticide. The first strychnine total synthesis, by R. B. Woodward,[20] represented a major step in natural product synthesis: no molecule approaching its complexity had been synthesized before. The next total syntheses were not reported until the late 1980s, using similar methods, namely by using an intermediate available by degradated strychnine. All of these syntheses used harsh conditions. The Overman synthesis sidesteps these problems, and is the first asymmetric total synthesis of strychnine, taking advantage of the diastereoselectivity and mild reaction conditions of the aza-Cope/Mannich reaction. The aza-Cope/Mannich reaction step proceeded in near quantitative yield. The Overman synthesis is accordingly several orders of magnitude more efficient than its predecessors.[20]

 
A retrosynthetic analysis of strychnine: the Wieland-Gumlich aldehyde is a known precursor of strychnine. A precursor of the Wieland-Gumlich aldehyde is shown, with the aza-Cope/Mannich reaction retron highlighted. Strychnine is synthesized from the Wieland-Gumlich aldehyde in 65% yield.
 
Molecule "A" has been reconfigured for clarity. The rearrangement substrate proceeds by heating at 80°C in paraformaldehyde, acetonitrile and anhydrous Na2-SO4. The paraformaldehyde adds the carbon to the nitrogen, resulting in the iminium ion, already pictured. The aza-Cope/Mannich reaction step proceeded in near quantitative yield (98%), 99% ee.[20]

Overman's synthesis of strychnine represents a useful example of the preparation of precursors necessary for the aza-Cope/Mannich rearrangement, representing effective usage of an epoxide ring opening. The key steps of the synthesis of the rearrangement substrate leading to the starting materials necessary for the aza-Cope/Mannich reaction included a Stille reaction to piece together two precursors, an epoxidation of a double bond using tert-Butyl hydroperoxide, a Wittig reaction to convert the ketone to an alkene, and a cyclization step. Amine alkylation (not shown), transforms the molecule to the rearrangement substrate. Significantly, this molecule shows the enantiomeric precision of the aza-Cope/Mannich reaction, as a simple enantiomeric starting material dictates the final enantiomer: the enantiomer of strychnine was produced by using the enantiomer of the starting material.[20][21]

 
Some key steps in the preparation of the aza-Cope/Mannich reaction substrate for the Overman synthesis of strychnine

The Overman synthesis, with in-depth details of the synthesis of the rearrangement substrate, as well as the final steps of the reaction, is detailed here: Overman synthesis of (−)-strychnine.

Synthesis of (−)-crinine

Crinine is an alkaloid of the family Amaryllidaceae, and its asymmetric total synthesis was one of the first using the aza-Cope/Mannich reaction. This synthesis represents a significant step in the development of the aza-Cope/Mannich reaction, as it takes advantage of several of the most useful synthetic strategies characteristic of the reaction. This reaction takes advantage of the cationic-2-aza-Cope rearrangement's high diastereoselectivity, as well as usage of the cyanomethyl group to protect the amine during vinyllithium addition and as a leaving group to promote iminium formation, assisted by addition of silver nitrate.[22] This synthesis is one example of many of the cyanomethyl group providing a synthetically useful route towards pyrrolidine and indolizidine formation.

 
the vinyl substituent was added by vinylithium addition, after which silver nitrate at 50°C afforded the aza-Cope/Mannich product in 80% yield.

Synthesis of bridged tricyclic alkaloids

Overman and coworkers developed methods to synthesize complicated bridged tricyclic structures using the aza-Cope/Mannich reaction. These aza-tricyclic structures are found in the complex Stemona alkaloid family, as well as in potential drugs such as some immunosuppressants. The example shown is a facile reaction combining a 1-aza-bicyclo[2.2.1]heptane salt starting material with paraformaldehyde at 80 °C to form the pivotal aza-tricyclic structure of the Stemona alkaloid molecules. Saliently, despite unfavorable orbital overlap due to the sterics of this ring system, the reaction proceeds with 94% yield, highlighting the power of this reaction even under unfavorable conditions.[23]

 
Paraformaldehyde alkylated the amine and the reaction proceeded at 80°C in toulene and acetonitrile. This step occurred in 94% yield.

General ring opening and expansion

 
the reaction proceeds with addition of Camphorsulfonic acid (CSA) or silver nitrate at room temperature

The aza-Cope/Mannich reaction, when coupled with existing ring cycles, is often used to create indolizidine cycles (a pyrrolidine connected to a cyclohexane ring). This typical ring annulation, where the cyclopentane moiety is opened with the rearrangement and closed with the Mannich cyclization to form a six membered ring attached to a pyrrolidine ring, while the most popular aza-Cope/Mannich annulation, is not the only one. Seven-membered ring cycles are also possible to synthesize, as the enol and iminium ions stay in close enough proximity to undergo Mannich cyclization.[22] Macrocycle synthesis has not been reported using this reaction, due to the lack of proximity between the enol and iminium.[6] Vinyl oxazolidines can also be used as rearrangement substrates. This rearrangement first creates the vinyl oxazolidine from attack on the cyclohexanone by the aminobutenol, which then undergoes the aza-Cope/Mannich reaction using heat and acid (Lewis or protic). This example breaks and then forms a five-membered ring. More complex examples attach the oxazolidine to another ring, presenting additional methods for the formation of indolizidine cycles.[24]

Scope of the aza-Cope/Mannich reaction

The aza-Cope/Mannich reaction has numerous advantages in comparison to other methods. The gentle conditions of the reaction aren't matched: light heating, normally no higher than 80 °C, a wide range of solvents, and addition of 1 stoichiometric equivalent of acid, commonly camphorsulfonic acid (CSA) or a Lewis acid. Other routes toward pyrrolidine synthesis cannot compete with the stereospecificity, widescale applications in structures containing pyrrolidine derivatives, and large scope of possible starting materials. The reaction exhibits high diastereoselectivity, and is robust, proceeding even when faced with poor orbital overlap in the transition state.[1]

 

The advantages of the aza-Cope/Mannich reaction have motivated research on the synthesis of the starting materials for the reaction, which split into two main categories: amine addition and iminium formation (red) and installation of the vinyl substituent (blue). A wide variety of N-substituents (R), alkyl and aryl, can be used in the reaction, some of which affect the stereochemical outcome of the reaction. Vinyl groups are generally limited to those which are either 1,1 or 1,2-Disubstituted (vinyl with substituents at R1, and R1,R2 respectively), with a wide range of electronic and steric variety tolerated.[1]

Amine addition and iminium formation

Epoxide ring opening

The ring strain of epoxides provide useful methodology for installation of an amine group two atoms away from an alcohol group. The epoxide may be first broken by bromide nucleophilic attack. Primary amines, aromatic amines, or lithium anilides can also be used as nucleophiles. Protective O-methylation often follows this step and proceeds easily.

 
In the top example, isoprene oxide is first treated with NBS and MeOH, while in the bottom, methanol is not added. The final products of both are afforded in moderate to high yield (~50-90%).

When sterics allow for attack on only the appropriate carbon (the terminal carbon as opposed to the second carbon), direct attack by an intramolecular nitrogen is effective, as is the case with strychnine synthesis.[16][25]

Iminium ion formation

The most common way to generate the iminium ion from the installed amine is by adding formaldehyde or paraformaldehyde, which undergoes acid-catalyzed condensation to form the iminium. Overman's strychnine synthesis typifies this method.[6][25] Occasionally, intramolecular carbonyls are used.[9] Other methods for iminium ion formation include using cyanomethyl groups or using oxazolidines as carbonyl precursors.

 

Amine alkylation

Amine alkylation represents a common method to get to imine precursors. Amine alkylation by direct SN2 reaction is only occasionally useful in producing starting materials due to the high propensity of amines to overalkylate.[25]Reductive amination is a more common and effective alkylating procedure, typified in the first aza-Cope rearrangement.[16][26][27] The most useful and standard method of amine alkylation is to have the amine form an amide bond, and subsequently reduce it, often with lithium aluminium hydride.[9]

Oxazolidine use

Ketones and sterically hindered aldehydes are not suitable for the basic aza-Cope/Mannich reaction, as the amine cannot form an iminium ion with them. Dehydrative oxazoline formation followed by heating in the presence of a full equivalent of acid present a way to get around this issue. Overman has reported the use of oxizolidines to generate the iminium ion requisite for the reaction. Upon formation, Overman showed that cyclohexanones can be used for the carbonyl component in pyrrolidine synthesis.[17] This reaction proceeded with various forms of cyclohexanones. When an acyclic ketone was substituted, the reaction proceeded with low yield, highlighting the thermodynamic favorability of releasing cyclohexanone from the double bonded carbonyl, as it creates unfavorable bond strain in the chair conformation. This represents one of the most convenient constructions of the 1-azaspiro[4,5]decane ring system, a useful natural product.[17]

 
The reaction takes place in refluxing benzene at 80 °C or at room temperature in the presence of Sodium sulfate which activates iminium ion formation. The final product is a 1-azaspiro[4,5]decane.

Installation of the vinyl substituent

Vinylation of ketones

Vinylation can offer additional synthetic advantages, allowing for expanded functionality of the reaction.[23] Organolithium reagents are typically used. Often, a substituent or protecting group will be added to the nitrogen, although this isn't always necessary. The addition of lithium to the reaction has a major effect on starting material stereochemistry, as the nitrogen coordinates to it. Starting materials affected by this coordination generally result in anti aza-Cope precursors, while those that aren't, such as those containing highly substituted, sterically hindered amines, result in syn precursors. Thus the nature of the nitrogen substituent is of high importance.[6][25]

 
Vinylation leading to a crinine precursor.

Cyanomethyl group use

Cyanomethyl groups represent an easy way to protect an iminium ion during allylic vinylation of the ketone. Cyanamide groups and analogs have been often used in the generation iminium ions. They are typically installed by nucleophilic addition onto an iminium ion, generally produced by amine alkylation with formaldehyde. The iminium ion is thus masked.[28] It follows that usage of a cyanomethyl group provides an efficient way to control the aza-Cope/Mannich reaction. The cyanomethyl group protects the nitrogen at the 2-position during formation of the other allylic analog by logic similar to cyanide-type umpolung. It then later provides a good leaving group for formation of the iminium ion, in accordance with its usage in iminium ion generation.[29] Iminium ion generation from cyanomethyl groups is normally promoted by addition of silver nitrate, although other silver and copper compounds have been used. This added step allows for more precise control of iminium ion generation.[6][29] Importantly, these preparatory reactions must be carried out at -78 °C to prevent cyanomethyl/vinyllithium interaction. This method also allows for many different possible N-substituents, and can be used to simplify the synthesis of octahydroindoles and pyrroles.[1][29]

 
The cyanomethyl group often leaves with the help of silver nitrate. The reaction generally takes place at -78°C.

The 1- and 3-aza-Cope rearrangements

 

The 1- and 3-aza-Cope rearrangements are obscure in comparison to the cationic 2-aza-Cope rearrangement due to their activation energies, which are comparatively much higher than that of the cationic 2-aza-Cope rearrangement.

The 1- and 3-aza-Cope have a bias towards imine formation as opposed to enamine formation, as carbon-nitrogen π-bonding is stronger than carbon-nitrogen σ-bonding, meaning the 3-aza-Cope rearrangement is thermodynamically favored, while the 1-aza-Cope rearrangement is not: the imine is nearly 10kcal/mol less in energy. Thus the 3-aza Cope's large activation barriers are kinetically based. Research on both the 1 and 3-aza-Cope rearrangements has focused on finding good driving forces to lowering the activation barriers. Several versions of these rearrangements have been optimized for synthetic utility. The 1-aza-Cope rearrangement is normally paired with thermodynamic driving forces. The 3-aza-Cope rearrangements are generally performed cationically to lower the kinetic barrier to its thermodynamically favorable product.[30]

These rearrangements follow much of the mechanistic logic of the cationic 2-Aza-Cope rearrangement. The 1- and 3-aza-Cope rearrangements both occur preferentially via chair transition states (and retain stereochemistry, similarly to the cationic 2-aza-Cope rearrangement), and are sped up with the introduction of a positive charge, as this gives the transition state more diradical/dipolar character.[30] The 3-aza-Cope rearrangement (and thus also the 1-aza-Cope rearrangement, which goes through the same transition state) is expected to show even less aromatic character in its transition state in comparison to the Cope rearrangement and cationic-2-aza-Cope rearrangement, contributing to the higher temperatures required (close to the temperatures required for the Cope rearrangement, at times even higher, from 170 to 300 degrees) to overcome the kinetic activation barriers for these arrangements.[3][30][31]

The 3-aza-Cope rearrangement

 
the 3-aza-Cope rearrangement

The 3-aza-Cope reaction was discovered soon after the 2-aza-Cope rearrangement was identified, due to its analogous relationship to the Claisen rearrangement. Indeed, in early papers, this version of the aza-Cope rearrangement is often referred to as the amino-Claisen rearrangement, a misrepresentation of the rearrangement, as this would imply that both a nitrogen and oxygen are in the molecule.[3] This rearrangement can be used to form heterocyclic rings involving carbon, most commonly piperidine.

One of the first examples of this arrangement was identified by Burpitt, who recognized the rearrangement occurring in ammonium salts, which, due to their charged nature, proceeded exothermically without addition of heat—importantly, without a tetrasubstituted nitrogen, the rearrangement did not proceed.[32] Following this logic, much of the research on the 3-aza-Cope rearrangement has focused on charged zwitterionic versions of this reaction, as the charge distribution helps lower the activation barrier: in certain cases, the rearrangement can occur at temperatures as low as -20 °C.[33]

 
An excerpt of a 3-aza-Cope rearrangement in the total synthesis of deserpidine, by Mariano and coworkers. This step proceeded with 30-60% yield, dependent on allylic substituents (not shown).

HIll and Gilman first reported a general uncharged 3-aza-Cope rearrangement in 1967. Upon creation of appropriately substituted enamines, intense heating afforded an almost complete rearrangement to the imine product. However, this rearrangement pathway has limited utility.[34]

The 1-aza-Cope rearrangement

 

The first discovered 1-aza-Cope reaction was a simple analog to the generic Cope reaction and required intense heat to overcome its large thermodynamic activation barrier; most subsequent work on the 1-aza-Cope rearrangement has thus focused on pairing the arrangement with a driving thermodynamic force to avoid these harsh reaction conditions. It has been hypothesized that the 1-aza-Cope rearrangement rate-determining transition state has partial diradical and dipolar transition state character due to the presence of the heteroatom.[4]

Fowler and coworkers have come up with a scheme that mobilizes the 1-aza-Cope rearrangement as a synthetically useful route.[3] Fowler and coworkers recognized that because the barrier for the reaction lies in the nitrogen's thermodynamic preference to stay as an imine, stabilizing the nitrogen could have a thermodynamically beneficial effect. To that end, Fowler and coworkers installed a carbonyl group on the nitrogen, hypothesizing that the lone pair of the nitrogen would be stabilized by participation in an amide bond, and that the electronegativity of this amide group would lower the LUMO of the imine group, making the transition state more favorable.[3] Using this strategy, Fowler and coworkers were able to use the 1-aza-Cope rearrangement to create piperidine and pyridine derivatives. This strategy was shown to be relatively robust, allowing for the formation of products even when forced through a boat transition state, when perturbed with substituent effects, or put in competition with alternative rearrangements.[3] Also significant is the relative ease of production of the reactants, which uses a Diels-Alder reaction paired with relatively simple workup steps, allowing for syntheses using complex cycling.[3]

 
Fowler's modification to the 1-aza-Cope rearrangement. Fowler installs a carbonyl group onto the nitrogen, stabilizing the nitrogen lone pair in an amide bond, which helps make the reaction more thermodynamically favorable, although it still requires extreme heating, at around 500 °C.

Other methods of overcoming this thermodynamic barrier include pairing it with cyclopropane ring strain release, which allows the reaction to proceed at much lower temperatures.[35]

 
This example pairs ring strain release with presumed stabilizing resonance with the aldehyde, and proceeds at room temperature.

References

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  6. ^ a b c d e f g h i Overman, L.E.; Mendelson, L. T.; Jacobsen, E. J. (1983). "Synthesis applications of aza-Cope rearrangements. 12. Applications of cationic aza-Cope rearrangements for alkaloid synthesis. Stereoselective preparation of cis-3a-aryloctahydroindoles and a new short route to Amaryllidaceae alkaloids". J. Am. Chem. Soc. 105 (22): 6629–6637. doi:10.1021/ja00360a014.
  7. ^ a b c Overman, L. E. (1992). "Charge as a key component in reaction design. The invention of cationic cyclization reactions of importance in synthesis". Acc. Chem. Res. 25 (8): 352–359. doi:10.1021/ar00020a005.
  8. ^ Doering, W.v.E.; Roth, W. R. (1962). "The overlap of two allyl radicals or a four-centered transition state in the cope rearrangement". Tetrahedron. 18 (1): 67–74. doi:10.1016/0040-4020(62)80025-8.
  9. ^ a b c d e Doedens, R. J.; Meier, G.P.; Overman, L.E. (1988). "Synthesis applications of cationic aza-Cope rearrangements. Part 17. Transition-state geometry of [3,3]-sigmatropic rearrangements of iminium ions". J. Org. Chem. 53 (3): 685–690. doi:10.1021/jo00238a039.
  10. ^ Vogel, E.; Grimme, W.; Dinne, E. (December 1963). "Thermal Equilibrium between cis-1,2-Divinylcyclo-pentane and cis,cis-1,5-Cyclononadiene". Angewandte Chemie International Edition in English. 2 (12): 739–740. doi:10.1002/anie.196307392.
  11. ^ Lukowski M.; Jacobs K.; Hsueh P.; Lindsay H.A; Milletti M.C. (2009). "Thermodynamic and kinetic factors in the aza-Cope rearrangement of a series of iminium cations". Tetrahedron. 65 (50): 10311–10316. doi:10.1016/j.tet.2009.10.010.
  12. ^ a b McCann, S. F.; Overman, L. E. (1987). "Medium Effects and the Nature of the Rate-Determining Step in Mannich-Type Cyclizations". J. Am. Chem. Soc. 109 (20): 6107–6114. doi:10.1021/ja00254a033.
  13. ^ Overman, L. E.; Trenkle, W. C. (1997). "Controlling Stereoselection in Aza-Cope-Mannich Reactions". Isr. J. Chem. 37: 23–30. doi:10.1002/ijch.199700005.
  14. ^ a b Jacobsen E. J.; Levin J.; Overman L. E. (1988). "Synthesis applications of cationic aza-Cope rearrangements. Part 18. Scope and mechanism of tandem cationic aza-Cope rearrangement-Mannich cyclization reactions". J. Am. Chem. Soc. 110 (13): 4329–4336. doi:10.1021/ja00221a037.
  15. ^ Marshall, J. A.; Babler, J. H. (1969). "Heterolytic fragmentation of 1-substituted decahydroquinolines". J. Org. Chem. 34 (12): 4186–4188. doi:10.1021/jo01264a104.
  16. ^ a b c d e f Overman L. E.; Kakimoto, M. (1979). "Carbon-Carbon Bond Formation via Directed 2-Azonia-[3,3]-Sigmatropic Rearrangements. A New Pyrrolidine Synthesis". J. Am. Chem. Soc. 101 (5): 1310–1312. doi:10.1021/ja00499a058.
  17. ^ a b c d Overman L.E.; Kakimoto M.; Okawara M. (1979). "Directed 2-azonia-[3,3]-sigmatropic rearrangements. a convenient preparation of substituted 1-azaspiro[4,5]decanes". Tetrahedron Letters. 20 (42): 4041–4044. doi:10.1016/s0040-4039(01)86498-4.
  18. ^ Armstrong, A.; Shanahan, S. E. (2005). "aza-Prins-pinacol approach to 7-azabicyclo[2.2.1]heptanes and ring expansion to [3.2.1]tropanes". Org. Lett. 7: 1335. doi:10.1021/ja00221a037.
  19. ^ aza-Prins-pinacol approach to 7-azabicyclo[2.2.1]heptanes and ring expansion to [3.2.1]tropanes Armstrong, A.; Shanahan, S. E. Org. Lett. 2005, 7, 1335
  20. ^ a b c d R. B. Woodward; M. P. Cava; W. D. Ollis; A. Hunger; H. U. Daeniker; K. Schenker (1963). "The total synthesis of strychnine". Tetrahedron. 19 (2): 247–288. doi:10.1016/S0040-4020(01)98529-1. PMID 13305562.
  21. ^ Knight, S.D.; Overman, L. E.; Pairaudeau, G. (1993). "Synthesis applications of cationic aza-Cope rearrangements. 26. Enantioselective total synthesis of (−)-strychnine". J. Am. Chem. Soc. 115 (20): 9293–9294. doi:10.1021/ja00073a057.
  22. ^ a b Overman, L. E.; Sugai, s. (1985). "Total Synthesis of (−)-Crinine. Use of Tandem Cationic Aza-Cope Rearrangement/Mannich Cyclizations for the Synthesis of Enantiomerically Pure Amaryllidaceae Alkaloids". Helv. Chim. Acta. 68 (3): 745–749. doi:10.1002/hlca.19850680324.
  23. ^ a b Brueggemann, M.; McDonald, A. I.; Overman, L.E.; Rosen, M.D.; Schwink, L.; Scott, J.P. (2003). "Total Synthesis of (±)-Didehydrostemofoline (Asparagamine A) and (±)-Isodidehydrostemofoline". J. Am. Chem. Soc. 125 (50): 15284–15285. doi:10.1021/ja0388820. PMID 14664560.
  24. ^ Overman, L. E.; Shim, J. (1993). "Synthesis applications of cationic aza-Cope rearrangements. Part 25. Total synthesis of Amaryllidaceae alkaloids of the 5,11-methanomorphanthridine type. Efficient total syntheses of (−)-pancracine and (.+-.)-pancracine". Organic Reactions. 58 (17): 4662–4672. doi:10.1021/jo00069a032.
  25. ^ a b c d Overman L. E.; Kakimoto, M.; Okazaki, M.E.; Meier, G.P. (1983). "Synthesis applications of aza-Cope rearrangements. 11. Carbon-carbon bond formation under mild conditions via tandem cationic aza-Cope rearrangement-Mannich reactions. A convenient synthesis of polysubstituted pyrrolidines". J. Am. Chem. Soc. 105 (22): 6622–6629. doi:10.1021/ja00360a013.
  26. ^ Overman, L.E.; Fukaya, C. (1980). "Stereoselective total synthesis of (.+-.)-perhydrogephyrotoxin. Synthetic applications of directed 2-azonia-[3,3]-sigmatropic rearrangements". J. Am. Chem. Soc. 102 (4): 1454–1456. doi:10.1021/ja00524a057.
  27. ^ Borch, R. F.; Bernstein, M. D.; Durst H. D. (1971). "Cyanohydridoborate anion as a selective reducing agent". J. Am. Chem. Soc. 93 (12): 2897–2904. doi:10.1021/ja00741a013.
  28. ^ Grierson D. S.; Harris, M.; Husson, H.P. (1980). "Synthesis and chemistry of 5,6-dihydropyridinium salt adducts. Synthons for general electrophilic and nucleophilic substitution of the piperidine ring system". J. Am. Chem. Soc. 102 (3): 1064–1082. doi:10.1021/ja00523a026.
  29. ^ a b c Overman, L. E.; Jacobsen, E. J. (1982). "The cyanomethyl group for nitrogen protection and iminium ion generation in ring-enlarging pyrrolidine annulations. A short synthesis of the amaryllidaceae alkaloid d,1-crinine". Tetrahedron Lett. 67 (51): 2741–2744. doi:10.1016/S0040-4039(00)87446-8.
  30. ^ a b c Jolidon, S.; Hansen, H. J. (1997). "Untersuchungen über aromatische Amino-Claisen-Umlagerungen". Helv. Chim. Acta. 60 (2): 978–1032. doi:10.1002/hlca.19770600329.
  31. ^ Zahedi Ehsan; Ali-Asgari Safa; Keley Vahid (2010). "NBO and NICS analysis of the allylic rearrangements (the Cope and 3-aza-Cope rearrangements) of hexa-1,5-diene and N-vinylprop-2-en-1-amine: A DFT study". Central European Journal of Chemistry. 8 (5): 1097–1104. doi:10.2478/s11532-010-0084-1.
  32. ^ Brannock Kent; Burpitt Robert (1961). "Notes- The Chemistry of Isobutenylamines. II. Alkylation with Allylic and Benzyl Halides". J. Org. Chem. 26 (9): 3576–3577. doi:10.1021/jo01067a645.
  33. ^ Baxter, E. W.; Labaree, D.; Ammon, H. L.; Mariano, P. S. (1990). "Formal total synthesis of deserpidine demonstrating a versatile amino-Claisen rearrangement/Wenkert cyclization strategy for the preparation of functionalized yohimbane ring systems". J. Am. Chem. Soc. 12 (21): 7682–7692. doi:10.1021/ja00177a032.
  34. ^ Hill, R. K.; Gilman, N. W. (1967). "A nitrogen analog of the Claisen rearrangement". Tetrahedron Letters. 8 (15): 1421–1423. doi:10.1016/S0040-4039(00)71596-6.
  35. ^ Boeckman, R. K.; Shair, M.D.; Vargas, R. J.; Stolz, L. A. (1993). "Synthetic and Mechanistic Studies of the retro-Claisen Rearrangement. 2. A Facile route to Medium-Ring Heterocycles via Rearrangement of Vinylcyclopropane- and Cyclobutanecarboxaldehydes". J. Org. Chem. 58 (2): 1295–1297. doi:10.1021/jo00058a001.

Further reading

  • Overman, L. E.; Humphreys, P. G.; Welmaker, G. S. (2011). "The Aza-Cope/Mannich Reaction". Organic Reactions. Vol. 75. pp. 747–820. doi:10.1002/0471264180.or075.04. ISBN 978-0471264187.
  • Overman, L. E. (2009). "Molecular rearrangements in the construction of complex molecules". Tetrahedron. 65 (33): 6432–6446. doi:10.1016/j.tet.2009.05.067. PMC 2902795. PMID 20640042.
  • Siegfried Blechert (1989). "The Hetero-Cope Rearrangement in Organic Synthesis". Synthesis. 1989 (2): 71–82. doi:10.1055/s-1989-27158.

August 24, 2023
cope, rearrangement, rearrangements, especially, those, that, participate, cascade, reactions, such, cope, rearrangements, high, practical, well, conceptual, importance, organic, chemistry, their, ability, quickly, build, structural, complexity, simple, starti. Rearrangements especially those that can participate in cascade reactions such as the aza Cope rearrangements are of high practical as well as conceptual importance in organic chemistry due to their ability to quickly build structural complexity out of simple starting materials The aza Cope rearrangements are examples of heteroatom versions of the Cope rearrangement which is a 3 3 sigmatropic rearrangement that shifts single and double bonds between two allylic components In accordance with the Woodward Hoffman rules thermal aza Cope rearrangements proceed suprafacially 1 Aza Cope rearrangements are generally classified by the position of the nitrogen in the molecule see figure Aza Cope rearrangementNamed after Arthur C CopeReaction type Rearrangement reactionIdentifiersRSC ontology ID RXNO 0000197 The 1 2 and 3 aza Cope rearrangementsThe first example of an aza Cope rearrangement was the ubiquitous cationic 2 aza Cope rearrangement which takes place at temperatures 100 200 C lower than the Cope rearrangement due to the facile nature of the rearrangement 2 The facile nature of this rearrangement is attributed both to the fact that the cationic 2 aza Cope is inherently thermoneutral meaning there s no bias for the starting material or product as well as to the presence of the charged heteroatom in the molecule which lowers the activation barrier Less common are the 1 aza Cope rearrangement and the 3 aza Cope rearrangement which are the microscopic reverse of each other The 1 and 3 aza Cope rearrangements have high activation barriers and limited synthetic applicability accounting for their relative obscurity 3 4 5 To maximize its synthetic utility the cationic 2 aza Cope rearrangement is normally paired with a thermodynamic bias toward one side of the rearrangement The most common and synthetically useful strategy couples the cationic 2 aza Cope rearrangement with a Mannich cyclization and is the subject of much of this article This tandem aza Cope Mannich reaction is characterized by its mild reaction conditions diastereoselectivity and wide synthetic applicability It provides easy access to acyl substituted pyrrolidines a structure commonly found in natural products such as alkaloids and has been used in the synthesis of a number of them notably strychnine and crinine 6 Larry E Overman and coworkers have done extensive research on this reaction 1 Contents 1 The cationic 2 aza Cope rearrangement 1 1 Reaction mechanism 1 1 1 Rate acceleration due to positively charged nitrogen 1 1 2 Transition state and stereochemistry 1 1 3 Additional considerations for stereochemistry 1 1 4 Possible thermodynamic sinks for biasing a rearrangement product 2 The aza Cope Mannich reaction 2 1 The first aza Cope Mannich reaction 2 2 Reaction mechanism 3 Synthetic applications of the 2 aza Cope Mannich reaction 3 1 Strychnine total synthesis 3 2 Synthesis of crinine 3 3 Synthesis of bridged tricyclic alkaloids 3 4 General ring opening and expansion 4 Scope of the aza Cope Mannich reaction 4 1 Amine addition and iminium formation 4 1 1 Epoxide ring opening 4 2 Iminium ion formation 4 2 1 Amine alkylation 4 2 2 Oxazolidine use 4 3 Installation of the vinyl substituent 4 3 1 Vinylation of ketones 4 3 2 Cyanomethyl group use 5 The 1 and 3 aza Cope rearrangements 5 1 The 3 aza Cope rearrangement 5 2 The 1 aza Cope rearrangement 6 References 7 Further readingThe cationic 2 aza Cope rearrangement Edit The cationic 2 aza Cope rearrangement most properly called the 2 azonia 3 3 sigmatropic rearrangement has been thoroughly studied by Larry E Overman and coworkers It is the most extensively studied of the aza Cope rearrangements due to the mild conditions required to carry the arrangement out as well as for its many synthetic applications notably in alkaloid synthesis Thermodynamically the general 2 aza Cope rearrangement does not have a product bias as the bonds broken and formed are equivalent in either direction of the reaction similar to the Cope rearrangement The presence of the ionic nitrogen heteroatom accounts for the more facile rearrangement of the cationic 2 aza Cope rearrangement in comparison to the Cope rearrangement Hence it is often paired with a thermodynamic sink to bias a rearrangement product 1 In 1950 Horowitz and Geissman reported the first example of the 2 aza Cope rearrangement a surprising result in a failed attempt to synthesize an amino alcohol 2 This discovery identified the basic mechanism of the rearrangement as the product was most likely produced through a nitrogen analog of the Cope rearrangement Treatment of an allylbenzylamine A with formic acid and formaldehyde leads to an amino alcohol B The amino alcohol converts to an imine under addition of acid C which undergoes the cationic 2 aza Cope rearrangement D Water hydrolyses the iminium ion to an amine E Treating this starting material with only formaldehyde showed that alkylation of the amine group occurred after the cationic 2 aza Cope rearrangement a testament to the quick facility of the rearrangement 2 Horowitz and Geissman report the first aza Cope rearrangement This also exemplifies one of the many methods for carrying out iminium ion formation by reductive amination Due to the mild heating conditions of the reaction carried out unlike the more stringent ones for a purely hydrocarbon Cope rearrangement this heteroatomic Cope rearrangement introduced the hypothesis that having a positive charge on a nitrogen in the cope rearrangement significantly reduces the activation barrier for the rearrangement 2 Reaction mechanism Edit Rate acceleration due to positively charged nitrogen Edit The aza Cope rearrangements are predicted by the Woodward Hoffman rules to proceed suprafacially However while never explicitly studied Overman and coworkers have hypothesized that as with the base catalyzed oxy Cope rearrangement the charged atom distorts the sigmatropic rearrangement from a purely concerted reaction mechanism as expected in the Cope rearrangement to one with partial diradical dipolar character due to delocalization of the positive charge onto the allylic fragment which weakens the allylic bond This results in a lowered activation barrier for bond breaking Thus the cationic aza Cope rearrangement proceeds more quickly than more concerted processes such as the Cope rearrangement 6 7 Transition state and stereochemistry Edit The cationic 2 aza Cope rearrangement is characterized by its high stereospecificity which arises from its high preference for a chair transition state In their exploration of this rearrangement s stereospecificity Overman and coworkers used logic similar to the classic Doering and Roth experiments 8 which showed that the Cope rearrangement prefers a chair conformation 9 By using the cationic 2 aza Cope Mannich reaction on pyrrolizidine precursors they showed that pyrrolizidines with cis substituents from E alkenes and trans substituents from Z alkenes are heavily favored results that are indicative of a chair transition state If a boat transition state was operative the opposite results would have been obtained detailed in image below 9 As is the trend with many reactions conversion of the Z enolate affords lower selectivity due to 1 3 diaxial steric interactions between the enolate and the ring as well as the fact that substituents prefer quasi equatorial positioning This helps explain the higher temperatures required for Z enolate conversion 6 9 The boat transition state is even less favored by the cationic 2 aza Cope rearrangement than it is for the Cope rearrangement in analogous situations to where the Cope rearrangement takes on a boat transition state the aza Cope rearrangement continues in the chair geometry 1 6 10 These results are in accord with computational chemistry results which further assert that the transition state is under kinetic control 11 The rearrangement is shown as well as the reaction s final products E alkenes are pictured in the top half Z alkenes in the bottom half Operative chair transition states are detailed first boat transition states second Major products are labeled and unobserved minor products of boat transition states are depicted Blue dashed lines indicate a s bond being broken red dashed lines indicate a s bond being formed Significantly these stereochemical experiments imply that the cationic 2 aza Cope rearrangement as well as Mannich cyclization occur faster than enol or iminium tautomerization If they were not no meaningful stereochemistry would have been observed highlighting the facility of this fast reaction 1 Additional considerations for stereochemistry Edit The aza Cope Mannich reaction when participating in ring expanding annulations follows the stereochemistry dictated by the most favorable chair conformation which generally places bulky substituents quasi equatorially The vinyl and amine components can have either syn or anti relationships when installed on a ring This relationship is typically dictated by the amine substituent bulky substituents lead to syn aza Cope precursors While anti vinyl and amine substituents generally only have one favored transition state leading to a cis fused ring system the favored product of syn substituents can change dictated by steric interactions with solvents or large N substituents which may take preference over bulky substituents and change the transition state 12 13 anti starting materials generally lead to cis products syn starting materials lead to an assortment of products dependent on the nitrogen substituent s bulk as shown Blue denotes s bond breaking red denotes s bond formation For simple aza Cope Mannich reactions that do not participate in ring expanding annulation namely condensations of amino alcohols and ethers bond rotation occurs more quickly than the Mannich cyclization and racemic products are observed 14 This can be avoided by using a chiral auxiliary substituent on the amine Reactions tethered to rings cannot undergo these bond rotations 1 Bond rotation leading to racemic product The aza Cope rearrangement proceeding the bond rotation is omitted for clarity Possible thermodynamic sinks for biasing a rearrangement product Edit Horowitz and Geissman s first example demonstrates a possible thermodynamic sink to couple with the cationic 2 aza Cope rearrangement where the product is biased by the phenyl substituent through aryl conjugation then captured by hydrolysis of the iminium Other methods of biasing a product include using substituents which are more stable on substituted carbons releasing ring strain for instance by pairing the rearrangement with cyclopropane opening intramolecular trapping pictured and pairing the rearrangement with the Mannich cyclization 1 15 The iminium is trapped by the intramolecular nucleophile The aza Cope Mannich reaction Edit The aza Cope Mannich reactionThe aza Cope Mannich reaction is a synthetically powerful reaction as it is able to create complex cyclic molecules from simple starting materials This tandem reaction provides a thermodynamic bias towards one rearrangement product as the Mannich cyclization is irreversible and its product an acyl substituted pyrrolidine ring more stable than that of the rearrangement 1 16 The first aza Cope Mannich reaction Edit Overman and coworkers recognized that the cationic 2 aza Cope rearrangement could potentially be synthetically powerful if an appropriate thermodynamic sink could be introduced Their logic was to incorporate a nucleophilic substituent into the starting material namely an alcohol group which acts only after rearrangement converted into an enol primed to attack the iminium ion This first report of the reaction was a reaction between aldehydes and 2 alkoxy 3 butenamines which formed an amino alcohol whose aza Cope Mannich reaction product was an acyl substituted pyrrolidine ring This simple procedure only involved mild heating for several hours Significantly the aza Cope Mannich reaction occurs in a single step with excellent yield This procedure is easily applied to condensation of amino ethers shown below where the alcohol has been methylated first 16 After the aza Cope Mannich reaction is carried out the ketone is formed by addition of NaOH 16 The amine in this simple case cannot form the iminium ion from basic ketones subsequent methods found ways of incorporating ketones into the reaction 16 17 The utility of this reaction is evident in the fact that even when a less stable isomer is formed the reaction proceeds demonstrating its high thermodynamic favorability 12 17 This reaction occurred in a single step The reaction was heated for 5 hours in refluxing benzene NaOH was added to form the ketone at the final step Yields typically are around 90 varying slightly with different substituents Reaction mechanism Edit The general product of the reaction can potentially occur via two separate pathways the aza Cope Mannich reaction or an aza Prins cyclization pinacol rearrangement These mechanisms have different stereochemical properties which elucidate the dominance of the aza Cope Mannich reaction The aza Cope Mannich reaction forces each atom in the 1 5 diene analog to undergo sp2 hybridization erasing the starting material s stereochemistry at the labelled R position while the aza Prins pinacol rearrangement retains stereochemistry at the labelled R position pointing to a simple test that reveals the active mechanism An enantiomerically pure starting material at the R position should lead to a racemic product if the dominant mechanism is the aza Cope Mannich reaction while the stereochemistry should be retained if the dominant mechanism is an aza Prins cyclization pinacol rearrangement pathway A simple experiment verified that the product was racemic providing clear evidence of the aza Cope Mannich reaction as the operative mechanism Further experiments verified this using the knowledge that the carbenium ion formed in an aza Prins pinacol pathway would be effected by its substituent s ability to stabilize its positive charge thus changing the reactivity of the pathway However a variety of substituents were shown to have little effect on the outcome of the reaction again pointing to the aza Cope Mannich reaction as the operative mechanism 14 Recent literature from the Shanahan lab supports the rare aza Prins pinacol pathway only associated with significantly increased alkene nucleophilicity and iminium electrophilicity 1 6 18 19 The aza Cope Mannich reaction shows high diastereoselectivity generally in accordance the results of the stereochemical experiments elucidating the transition state of the cationic 2 aza Cope rearrangement which follows as this tandem reaction pathway was an integral part of these experiments The stereochemistry of the rearrangement is slightly more complicated when the allyl and amine substituents are installed on a ring and thus cis or trans to one another The aza Cope Mannich reaction starting material the amino alcohol can also be thought of as related to the oxy Cope rearrangement below both for its rate acceleration due to ionic involvement as well as the analogous enol collapsing function of the Mannich cyclization and the keto enol tautomerization in the oxy Cope rearrangement 7 The oxy Cope rearrangementSynthetic applications of the 2 aza Cope Mannich reaction EditThe aza Cope Mannich reaction is often the most efficient way to synthesize pyrrolidine rings and thus has a number of applications in natural product total syntheses Because of its diastereoselectivity this reaction has added to the catalog of asymmetric synthesis tools as seen in the many examples of asymmetric alkaloids synthesized using the reaction As we have seen in the first aza Cope Mannich reaction and in the elucidation of the reaction s stereochemistry the aza Cope Mannich reaction can be used to form pyrrolidine rings and pyrrolizidine rings It can be used to create many additional ring structures useful in synthesis such as indolizidine cycles and indole rings 1 7 Strychnine total synthesis Edit Main article Strychnine total synthesis The classic example demonstrating the utility of this reaction is the Overman synthesis of strychnine Strychnine is a naturally occurring highly poisonous alkaloid found in the tree and climbing shrub genus Strychnos Strychnine is commonly used as a small vertebrate pesticide The first strychnine total synthesis by R B Woodward 20 represented a major step in natural product synthesis no molecule approaching its complexity had been synthesized before The next total syntheses were not reported until the late 1980s using similar methods namely by using an intermediate available by degradated strychnine All of these syntheses used harsh conditions The Overman synthesis sidesteps these problems and is the first asymmetric total synthesis of strychnine taking advantage of the diastereoselectivity and mild reaction conditions of the aza Cope Mannich reaction The aza Cope Mannich reaction step proceeded in near quantitative yield The Overman synthesis is accordingly several orders of magnitude more efficient than its predecessors 20 A retrosynthetic analysis of strychnine the Wieland Gumlich aldehyde is a known precursor of strychnine A precursor of the Wieland Gumlich aldehyde is shown with the aza Cope Mannich reaction retron highlighted Strychnine is synthesized from the Wieland Gumlich aldehyde in 65 yield Molecule A has been reconfigured for clarity The rearrangement substrate proceeds by heating at 80 C in paraformaldehyde acetonitrile and anhydrous Na2 SO4 The paraformaldehyde adds the carbon to the nitrogen resulting in the iminium ion already pictured The aza Cope Mannich reaction step proceeded in near quantitative yield 98 99 ee 20 Overman s synthesis of strychnine represents a useful example of the preparation of precursors necessary for the aza Cope Mannich rearrangement representing effective usage of an epoxide ring opening The key steps of the synthesis of the rearrangement substrate leading to the starting materials necessary for the aza Cope Mannich reaction included a Stille reaction to piece together two precursors an epoxidation of a double bond using tert Butyl hydroperoxide a Wittig reaction to convert the ketone to an alkene and a cyclization step Amine alkylation not shown transforms the molecule to the rearrangement substrate Significantly this molecule shows the enantiomeric precision of the aza Cope Mannich reaction as a simple enantiomeric starting material dictates the final enantiomer the enantiomer of strychnine was produced by using the enantiomer of the starting material 20 21 Some key steps in the preparation of the aza Cope Mannich reaction substrate for the Overman synthesis of strychnineThe Overman synthesis with in depth details of the synthesis of the rearrangement substrate as well as the final steps of the reaction is detailed here Overman synthesis of strychnine Synthesis of crinine Edit Crinine is an alkaloid of the family Amaryllidaceae and its asymmetric total synthesis was one of the first using the aza Cope Mannich reaction This synthesis represents a significant step in the development of the aza Cope Mannich reaction as it takes advantage of several of the most useful synthetic strategies characteristic of the reaction This reaction takes advantage of the cationic 2 aza Cope rearrangement s high diastereoselectivity as well as usage of the cyanomethyl group to protect the amine during vinyllithium addition and as a leaving group to promote iminium formation assisted by addition of silver nitrate 22 This synthesis is one example of many of the cyanomethyl group providing a synthetically useful route towards pyrrolidine and indolizidine formation the vinyl substituent was added by vinylithium addition after which silver nitrate at 50 C afforded the aza Cope Mannich product in 80 yield Synthesis of bridged tricyclic alkaloids Edit Overman and coworkers developed methods to synthesize complicated bridged tricyclic structures using the aza Cope Mannich reaction These aza tricyclic structures are found in the complex Stemona alkaloid family as well as in potential drugs such as some immunosuppressants The example shown is a facile reaction combining a 1 aza bicyclo 2 2 1 heptane salt starting material with paraformaldehyde at 80 C to form the pivotal aza tricyclic structure of the Stemona alkaloid molecules Saliently despite unfavorable orbital overlap due to the sterics of this ring system the reaction proceeds with 94 yield highlighting the power of this reaction even under unfavorable conditions 23 Paraformaldehyde alkylated the amine and the reaction proceeded at 80 C in toulene and acetonitrile This step occurred in 94 yield General ring opening and expansion Edit the reaction proceeds with addition of Camphorsulfonic acid CSA or silver nitrate at room temperatureThe aza Cope Mannich reaction when coupled with existing ring cycles is often used to create indolizidine cycles a pyrrolidine connected to a cyclohexane ring This typical ring annulation where the cyclopentane moiety is opened with the rearrangement and closed with the Mannich cyclization to form a six membered ring attached to a pyrrolidine ring while the most popular aza Cope Mannich annulation is not the only one Seven membered ring cycles are also possible to synthesize as the enol and iminium ions stay in close enough proximity to undergo Mannich cyclization 22 Macrocycle synthesis has not been reported using this reaction due to the lack of proximity between the enol and iminium 6 Vinyl oxazolidines can also be used as rearrangement substrates This rearrangement first creates the vinyl oxazolidine from attack on the cyclohexanone by the aminobutenol which then undergoes the aza Cope Mannich reaction using heat and acid Lewis or protic This example breaks and then forms a five membered ring More complex examples attach the oxazolidine to another ring presenting additional methods for the formation of indolizidine cycles 24 Scope of the aza Cope Mannich reaction EditThe aza Cope Mannich reaction has numerous advantages in comparison to other methods The gentle conditions of the reaction aren t matched light heating normally no higher than 80 C a wide range of solvents and addition of 1 stoichiometric equivalent of acid commonly camphorsulfonic acid CSA or a Lewis acid Other routes toward pyrrolidine synthesis cannot compete with the stereospecificity widescale applications in structures containing pyrrolidine derivatives and large scope of possible starting materials The reaction exhibits high diastereoselectivity and is robust proceeding even when faced with poor orbital overlap in the transition state 1 The advantages of the aza Cope Mannich reaction have motivated research on the synthesis of the starting materials for the reaction which split into two main categories amine addition and iminium formation red and installation of the vinyl substituent blue A wide variety of N substituents R alkyl and aryl can be used in the reaction some of which affect the stereochemical outcome of the reaction Vinyl groups are generally limited to those which are either 1 1 or 1 2 Disubstituted vinyl with substituents at R1 and R1 R2 respectively with a wide range of electronic and steric variety tolerated 1 Amine addition and iminium formation Edit Epoxide ring opening Edit The ring strain of epoxides provide useful methodology for installation of an amine group two atoms away from an alcohol group The epoxide may be first broken by bromide nucleophilic attack Primary amines aromatic amines or lithium anilides can also be used as nucleophiles Protective O methylation often follows this step and proceeds easily In the top example isoprene oxide is first treated with NBS and MeOH while in the bottom methanol is not added The final products of both are afforded in moderate to high yield 50 90 When sterics allow for attack on only the appropriate carbon the terminal carbon as opposed to the second carbon direct attack by an intramolecular nitrogen is effective as is the case with strychnine synthesis 16 25 Iminium ion formation Edit The most common way to generate the iminium ion from the installed amine is by adding formaldehyde or paraformaldehyde which undergoes acid catalyzed condensation to form the iminium Overman s strychnine synthesis typifies this method 6 25 Occasionally intramolecular carbonyls are used 9 Other methods for iminium ion formation include using cyanomethyl groups or using oxazolidines as carbonyl precursors Amine alkylation Edit Amine alkylation represents a common method to get to imine precursors Amine alkylation by direct SN2 reaction is only occasionally useful in producing starting materials due to the high propensity of amines to overalkylate 25 Reductive amination is a more common and effective alkylating procedure typified in the first aza Cope rearrangement 16 26 27 The most useful and standard method of amine alkylation is to have the amine form an amide bond and subsequently reduce it often with lithium aluminium hydride 9 Oxazolidine use Edit Ketones and sterically hindered aldehydes are not suitable for the basic aza Cope Mannich reaction as the amine cannot form an iminium ion with them Dehydrative oxazoline formation followed by heating in the presence of a full equivalent of acid present a way to get around this issue Overman has reported the use of oxizolidines to generate the iminium ion requisite for the reaction Upon formation Overman showed that cyclohexanones can be used for the carbonyl component in pyrrolidine synthesis 17 This reaction proceeded with various forms of cyclohexanones When an acyclic ketone was substituted the reaction proceeded with low yield highlighting the thermodynamic favorability of releasing cyclohexanone from the double bonded carbonyl as it creates unfavorable bond strain in the chair conformation This represents one of the most convenient constructions of the 1 azaspiro 4 5 decane ring system a useful natural product 17 The reaction takes place in refluxing benzene at 80 C or at room temperature in the presence of Sodium sulfate which activates iminium ion formation The final product is a 1 azaspiro 4 5 decane Installation of the vinyl substituent Edit Vinylation of ketones Edit Vinylation can offer additional synthetic advantages allowing for expanded functionality of the reaction 23 Organolithium reagents are typically used Often a substituent or protecting group will be added to the nitrogen although this isn t always necessary The addition of lithium to the reaction has a major effect on starting material stereochemistry as the nitrogen coordinates to it Starting materials affected by this coordination generally result in anti aza Cope precursors while those that aren t such as those containing highly substituted sterically hindered amines result in syn precursors Thus the nature of the nitrogen substituent is of high importance 6 25 Vinylation leading to a crinine precursor Cyanomethyl group use Edit Cyanomethyl groups represent an easy way to protect an iminium ion during allylic vinylation of the ketone Cyanamide groups and analogs have been often used in the generation iminium ions They are typically installed by nucleophilic addition onto an iminium ion generally produced by amine alkylation with formaldehyde The iminium ion is thus masked 28 It follows that usage of a cyanomethyl group provides an efficient way to control the aza Cope Mannich reaction The cyanomethyl group protects the nitrogen at the 2 position during formation of the other allylic analog by logic similar to cyanide type umpolung It then later provides a good leaving group for formation of the iminium ion in accordance with its usage in iminium ion generation 29 Iminium ion generation from cyanomethyl groups is normally promoted by addition of silver nitrate although other silver and copper compounds have been used This added step allows for more precise control of iminium ion generation 6 29 Importantly these preparatory reactions must be carried out at 78 C to prevent cyanomethyl vinyllithium interaction This method also allows for many different possible N substituents and can be used to simplify the synthesis of octahydroindoles and pyrroles 1 29 The cyanomethyl group often leaves with the help of silver nitrate The reaction generally takes place at 78 C The 1 and 3 aza Cope rearrangements Edit The 1 and 3 aza Cope rearrangements are obscure in comparison to the cationic 2 aza Cope rearrangement due to their activation energies which are comparatively much higher than that of the cationic 2 aza Cope rearrangement The 1 and 3 aza Cope have a bias towards imine formation as opposed to enamine formation as carbon nitrogen p bonding is stronger than carbon nitrogen s bonding meaning the 3 aza Cope rearrangement is thermodynamically favored while the 1 aza Cope rearrangement is not the imine is nearly 10kcal mol less in energy Thus the 3 aza Cope s large activation barriers are kinetically based Research on both the 1 and 3 aza Cope rearrangements has focused on finding good driving forces to lowering the activation barriers Several versions of these rearrangements have been optimized for synthetic utility The 1 aza Cope rearrangement is normally paired with thermodynamic driving forces The 3 aza Cope rearrangements are generally performed cationically to lower the kinetic barrier to its thermodynamically favorable product 30 These rearrangements follow much of the mechanistic logic of the cationic 2 Aza Cope rearrangement The 1 and 3 aza Cope rearrangements both occur preferentially via chair transition states and retain stereochemistry similarly to the cationic 2 aza Cope rearrangement and are sped up with the introduction of a positive charge as this gives the transition state more diradical dipolar character 30 The 3 aza Cope rearrangement and thus also the 1 aza Cope rearrangement which goes through the same transition state is expected to show even less aromatic character in its transition state in comparison to the Cope rearrangement and cationic 2 aza Cope rearrangement contributing to the higher temperatures required close to the temperatures required for the Cope rearrangement at times even higher from 170 to 300 degrees to overcome the kinetic activation barriers for these arrangements 3 30 31 The 3 aza Cope rearrangement Edit the 3 aza Cope rearrangementThe 3 aza Cope reaction was discovered soon after the 2 aza Cope rearrangement was identified due to its analogous relationship to the Claisen rearrangement Indeed in early papers this version of the aza Cope rearrangement is often referred to as the amino Claisen rearrangement a misrepresentation of the rearrangement as this would imply that both a nitrogen and oxygen are in the molecule 3 This rearrangement can be used to form heterocyclic rings involving carbon most commonly piperidine One of the first examples of this arrangement was identified by Burpitt who recognized the rearrangement occurring in ammonium salts which due to their charged nature proceeded exothermically without addition of heat importantly without a tetrasubstituted nitrogen the rearrangement did not proceed 32 Following this logic much of the research on the 3 aza Cope rearrangement has focused on charged zwitterionic versions of this reaction as the charge distribution helps lower the activation barrier in certain cases the rearrangement can occur at temperatures as low as 20 C 33 An excerpt of a 3 aza Cope rearrangement in the total synthesis of deserpidine by Mariano and coworkers This step proceeded with 30 60 yield dependent on allylic substituents not shown HIll and Gilman first reported a general uncharged 3 aza Cope rearrangement in 1967 Upon creation of appropriately substituted enamines intense heating afforded an almost complete rearrangement to the imine product However this rearrangement pathway has limited utility 34 The 1 aza Cope rearrangement Edit The first discovered 1 aza Cope reaction was a simple analog to the generic Cope reaction and required intense heat to overcome its large thermodynamic activation barrier most subsequent work on the 1 aza Cope rearrangement has thus focused on pairing the arrangement with a driving thermodynamic force to avoid these harsh reaction conditions It has been hypothesized that the 1 aza Cope rearrangement rate determining transition state has partial diradical and dipolar transition state character due to the presence of the heteroatom 4 Fowler and coworkers have come up with a scheme that mobilizes the 1 aza Cope rearrangement as a synthetically useful route 3 Fowler and coworkers recognized that because the barrier for the reaction lies in the nitrogen s thermodynamic preference to stay as an imine stabilizing the nitrogen could have a thermodynamically beneficial effect To that end Fowler and coworkers installed a carbonyl group on the nitrogen hypothesizing that the lone pair of the nitrogen would be stabilized by participation in an amide bond and that the electronegativity of this amide group would lower the LUMO of the imine group making the transition state more favorable 3 Using this strategy Fowler and coworkers were able to use the 1 aza Cope rearrangement to create piperidine and pyridine derivatives This strategy was shown to be relatively robust allowing for the formation of products even when forced through a boat transition state when perturbed with substituent effects or put in competition with alternative rearrangements 3 Also significant is the relative ease of production of the reactants which uses a Diels Alder reaction paired with relatively simple workup steps allowing for syntheses using complex cycling 3 Fowler s modification to the 1 aza Cope rearrangement Fowler installs a carbonyl group onto the nitrogen stabilizing the nitrogen lone pair in an amide bond which helps make the reaction more thermodynamically favorable although it still requires extreme heating at around 500 C Other methods of overcoming this thermodynamic barrier include pairing it with cyclopropane ring strain release which allows the reaction to proceed at much lower temperatures 35 This example pairs ring strain release with presumed stabilizing resonance with the aldehyde and proceeds at room temperature References Edit a b c d e f g h i j k l m Overman L E Humphreys P G Welmaker G S 2011 The Aza Cope Mannich Reaction Organic Reactions Vol 75 pp 747 820 doi 10 1002 0471264180 or075 04 ISBN 978 0471264187 a b c d Horowitz R M Geissman T A 1950 A Cleavage Reaction of a Allylbenzylamines J Am Chem Soc 72 4 1518 1522 doi 10 1021 ja01160a025 a b c d e f g Chu M Wu P L Givre S Fowler F W 1986 The 1 AZA Cope rearrangement Tetrahedron Letters 27 4 461 464 doi 10 1016 S0040 4039 00 85505 7 a b Wu P L Fowler F W 1988 The 1 aza Cope rearrangement 2 The Journal of Organic Chemistry 53 26 5998 6005 doi 10 1021 jo00261a003 Cook G R Barta N S Stille J R 1992 Lewis acid promoted 3 aza Cope rearrangement of N alkyl N allyl enamines The Journal of Organic Chemistry 57 2 461 467 doi 10 1021 jo00028a016 a b c d e f g h i Overman L E Mendelson L T Jacobsen E J 1983 Synthesis applications of aza Cope rearrangements 12 Applications of cationic aza Cope rearrangements for alkaloid synthesis Stereoselective preparation of cis 3a aryloctahydroindoles and a new short route to Amaryllidaceae alkaloids J Am Chem Soc 105 22 6629 6637 doi 10 1021 ja00360a014 a b c Overman L E 1992 Charge as a key component in reaction design The invention of cationic cyclization reactions of importance in synthesis Acc Chem Res 25 8 352 359 doi 10 1021 ar00020a005 Doering W v E Roth W R 1962 The overlap of two allyl radicals or a four centered transition state in the cope rearrangement Tetrahedron 18 1 67 74 doi 10 1016 0040 4020 62 80025 8 a b c d e Doedens R J Meier G P Overman L E 1988 Synthesis applications of cationic aza Cope rearrangements Part 17 Transition state geometry of 3 3 sigmatropic rearrangements of iminium ions J Org Chem 53 3 685 690 doi 10 1021 jo00238a039 Vogel E Grimme W Dinne E December 1963 Thermal Equilibrium between cis 1 2 Divinylcyclo pentane and cis cis 1 5 Cyclononadiene Angewandte Chemie International Edition in English 2 12 739 740 doi 10 1002 anie 196307392 Lukowski M Jacobs K Hsueh P Lindsay H A Milletti M C 2009 Thermodynamic and kinetic factors in the aza Cope rearrangement of a series of iminium cations Tetrahedron 65 50 10311 10316 doi 10 1016 j tet 2009 10 010 a b McCann S F Overman L E 1987 Medium Effects and the Nature of the Rate Determining Step in Mannich Type Cyclizations J Am Chem Soc 109 20 6107 6114 doi 10 1021 ja00254a033 Overman L E Trenkle W C 1997 Controlling Stereoselection in Aza Cope Mannich Reactions Isr J Chem 37 23 30 doi 10 1002 ijch 199700005 a b Jacobsen E J Levin J Overman L E 1988 Synthesis applications of cationic aza Cope rearrangements Part 18 Scope and mechanism of tandem cationic aza Cope rearrangement Mannich cyclization reactions J Am Chem Soc 110 13 4329 4336 doi 10 1021 ja00221a037 Marshall J A Babler J H 1969 Heterolytic fragmentation of 1 substituted decahydroquinolines J Org Chem 34 12 4186 4188 doi 10 1021 jo01264a104 a b c d e f Overman L E Kakimoto M 1979 Carbon Carbon Bond Formation via Directed 2 Azonia 3 3 Sigmatropic Rearrangements A New Pyrrolidine Synthesis J Am Chem Soc 101 5 1310 1312 doi 10 1021 ja00499a058 a b c d Overman L E Kakimoto M Okawara M 1979 Directed 2 azonia 3 3 sigmatropic rearrangements a convenient preparation of substituted 1 azaspiro 4 5 decanes Tetrahedron Letters 20 42 4041 4044 doi 10 1016 s0040 4039 01 86498 4 Armstrong A Shanahan S E 2005 aza Prins pinacol approach to 7 azabicyclo 2 2 1 heptanes and ring expansion to 3 2 1 tropanes Org Lett 7 1335 doi 10 1021 ja00221a037 aza Prins pinacol approach to 7 azabicyclo 2 2 1 heptanes and ring expansion to 3 2 1 tropanes Armstrong A Shanahan S E Org Lett 2005 7 1335 a b c d R B Woodward M P Cava W D Ollis A Hunger H U Daeniker K Schenker 1963 The total synthesis of strychnine Tetrahedron 19 2 247 288 doi 10 1016 S0040 4020 01 98529 1 PMID 13305562 Knight S D Overman L E Pairaudeau G 1993 Synthesis applications of cationic aza Cope rearrangements 26 Enantioselective total synthesis of strychnine J Am Chem Soc 115 20 9293 9294 doi 10 1021 ja00073a057 a b Overman L E Sugai s 1985 Total Synthesis of Crinine Use of Tandem Cationic Aza Cope Rearrangement Mannich Cyclizations for the Synthesis of Enantiomerically Pure Amaryllidaceae Alkaloids Helv Chim Acta 68 3 745 749 doi 10 1002 hlca 19850680324 a b Brueggemann M McDonald A I Overman L E Rosen M D Schwink L Scott J P 2003 Total Synthesis of Didehydrostemofoline Asparagamine A and Isodidehydrostemofoline J Am Chem Soc 125 50 15284 15285 doi 10 1021 ja0388820 PMID 14664560 Overman L E Shim J 1993 Synthesis applications of cationic aza Cope rearrangements Part 25 Total synthesis of Amaryllidaceae alkaloids of the 5 11 methanomorphanthridine type Efficient total syntheses of pancracine and pancracine Organic Reactions 58 17 4662 4672 doi 10 1021 jo00069a032 a b c d Overman L E Kakimoto M Okazaki M E Meier G P 1983 Synthesis applications of aza Cope rearrangements 11 Carbon carbon bond formation under mild conditions via tandem cationic aza Cope rearrangement Mannich reactions A convenient synthesis of polysubstituted pyrrolidines J Am Chem Soc 105 22 6622 6629 doi 10 1021 ja00360a013 Overman L E Fukaya C 1980 Stereoselective total synthesis of perhydrogephyrotoxin Synthetic applications of directed 2 azonia 3 3 sigmatropic rearrangements J Am Chem Soc 102 4 1454 1456 doi 10 1021 ja00524a057 Borch R F Bernstein M D Durst H D 1971 Cyanohydridoborate anion as a selective reducing agent J Am Chem Soc 93 12 2897 2904 doi 10 1021 ja00741a013 Grierson D S Harris M Husson H P 1980 Synthesis and chemistry of 5 6 dihydropyridinium salt adducts Synthons for general electrophilic and nucleophilic substitution of the piperidine ring system J Am Chem Soc 102 3 1064 1082 doi 10 1021 ja00523a026 a b c Overman L E Jacobsen E J 1982 The cyanomethyl group for nitrogen protection and iminium ion generation in ring enlarging pyrrolidine annulations A short synthesis of the amaryllidaceae alkaloid d 1 crinine Tetrahedron Lett 67 51 2741 2744 doi 10 1016 S0040 4039 00 87446 8 a b c Jolidon S Hansen H J 1997 Untersuchungen uber aromatische Amino Claisen Umlagerungen Helv Chim Acta 60 2 978 1032 doi 10 1002 hlca 19770600329 Zahedi Ehsan Ali Asgari Safa Keley Vahid 2010 NBO and NICS analysis of the allylic rearrangements the Cope and 3 aza Cope rearrangements of hexa 1 5 diene and N vinylprop 2 en 1 amine A DFT study Central European Journal of Chemistry 8 5 1097 1104 doi 10 2478 s11532 010 0084 1 Brannock Kent Burpitt Robert 1961 Notes The Chemistry of Isobutenylamines II Alkylation with Allylic and Benzyl Halides J Org Chem 26 9 3576 3577 doi 10 1021 jo01067a645 Baxter E W Labaree D Ammon H L Mariano P S 1990 Formal total synthesis of deserpidine demonstrating a versatile amino Claisen rearrangement Wenkert cyclization strategy for the preparation of functionalized yohimbane ring systems J Am Chem Soc 12 21 7682 7692 doi 10 1021 ja00177a032 Hill R K Gilman N W 1967 A nitrogen analog of the Claisen rearrangement Tetrahedron Letters 8 15 1421 1423 doi 10 1016 S0040 4039 00 71596 6 Boeckman R K Shair M D Vargas R J Stolz L A 1993 Synthetic and Mechanistic Studies of the retro Claisen Rearrangement 2 A Facile route to Medium Ring Heterocycles via Rearrangement of Vinylcyclopropane and Cyclobutanecarboxaldehydes J Org Chem 58 2 1295 1297 doi 10 1021 jo00058a001 Further reading EditOverman L E Humphreys P G Welmaker G S 2011 The Aza Cope Mannich Reaction Organic Reactions Vol 75 pp 747 820 doi 10 1002 0471264180 or075 04 ISBN 978 0471264187 Overman L E 2009 Molecular rearrangements in the construction of complex molecules Tetrahedron 65 33 6432 6446 doi 10 1016 j tet 2009 05 067 PMC 2902795 PMID 20640042 Siegfried Blechert 1989 The Hetero Cope Rearrangement in Organic Synthesis Synthesis 1989 2 71 82 doi 10 1055 s 1989 27158 Retrieved from https en wikipedia org w index php title Aza Cope rearrangement amp oldid 1148108883, wikipedia, wiki, book, books, library,

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