Anenamine is anunsaturated compound derived by the condensation of analdehyde orketone with a secondaryamine.[1][2] Enamines are versatile intermediates.[3][4]
The word "enamine" is derived from the affixen-, used as the suffix ofalkene, and the rootamine. This can be compared withenol, which is a functional group containing both alkene (en-) andalcohol (-ol). Enamines are considered to be nitrogen analogs of enols.[6]
If one or both of the nitrogen substituents is a hydrogen atom it is thetautomeric form of animine. This usually will rearrange to the imine; however there are several exceptions (such asaniline). The enamine-imine tautomerism may be considered analogous to theketo-enol tautomerism. In both cases, a hydrogen atom switches its location between the heteroatom (oxygen or nitrogen) and the second carbon atom.
Enamines are both good nucleophiles and good bases. Their behavior as carbon-based nucleophiles is explained with reference to the following resonance structures.
Enamines are labile and therefore chemically useful moieties which can be easily produced from commercially available starting reagents. A common route for enamine production is via an acid-catalyzed nucleophilic reaction of ketone[7] or aldehyde[8] species containing anα-hydrogen with secondary amines. Acid catalysis is not always required, if the pKaH of the reacting amine is sufficiently high (for example,pyrrolidine, which has a pKaH of 11.26). If the pKaH of the reactingamine is low, however, then acid catalysis is required through both the addition and the dehydration steps[9] (commondehydrating agents includeMgSO4 andNa2SO4).[10] Primary amines are usually not used for enamine synthesis due to the preferential formation of the more thermodynamically stable imine species.[11] Methyl ketone self-condensation is a side-reaction which can be avoided through the addition ofTiCl4[12] into the reaction mixture (to act as a waterscavenger).[13][14] An example of an aldehyde reacting with a secondary amine to form an enamine via acarbinolamine intermediate is shown below:
Even though enamines are more nucleophilic than their enol counterparts, they can still react selectively, rendering them useful for alkylation reactions. The enamine nucleophile can attackhaloalkanes to form the alkylatediminium salt intermediate which then hydrolyzes to regenerate a ketone (a starting material in enamine synthesis). This reaction was pioneered byGilbert Stork, and is sometimes referred to by the name of its inventor (theStork enamine alkylation). Analogously, this reaction can be used as an effective means ofacylation. A variety of alkylating and acylating agents including benzylic, allylic halides can be used in this reaction.[15]
In a reaction much similar to the enamine alkylation, enamines can be acylated to form a finaldicarbonyl product. The enamine starting material undergoes a nucleophilic addition toacyl halides forming the iminium salt intermediate which can hydrolyze in the presence of acid.[16]
Strong bases such asLiNR2 can be used to deprotonate imines and form metalloenamines. Metalloenamines can prove synthetically useful due to their nucleophilicity (they are more nucleophilic than enolates). Thus they are better able to react with weaker electrophiles (for example, they can be used to openepoxides.[17]) Most prominently, these reactions have allowed forasymmetric alkylations of ketones through transformation to chiral intermediate metalloenamines.[18]
β-halo immonium compounds can be synthesized through thehalogenation reaction of enamines with halides indiethyl ether solvent. Hydrolysis will result in the formation of α-halo ketones.[19] Chlorination, bromination, and even iodination have been shown to be possible. The general reaction is shown below:
Enamines can be efficientlycross-coupled with enol silanes through treatment withceric ammonium nitrate. These reactions were reported by the Narasaka group in 1975, providing a route to stable enamines as well as one instance of a 1,4-diketone (derived from amorpholine amine reagent).[20] Later, these results were exploited by theMacMillan group with the development of anorganocatalyst which used the Narasaka substrates to produce 1,4 dicarbonyls enantioselectively, with good yields.[21] Oxidative dimerization of aldehydes in the presence of amines proceeds through the formation of an enamine followed by a finalpyrrole formation.[22] This method for symmetric pyrrole synthesis was developed in 2010 by the Jia group, as a valuable new pathway for the synthesis of pyrrole-containing natural products.[23]
Enamines chemistry has been implemented for the purposes of producing a one-pot enantioselective version of theRobinson annulation. The Robinson annulation, published by Robert Robinson in 1935, is a base-catalyzed reaction that combines a ketone and amethyl vinyl ketone (commonly abbreviated to MVK) to form acyclohexenone fused ring system. This reaction may be catalyzed byproline to proceed through chiral enamine intermediates which allow for good stereoselectivity.[24] This is important, in particular in the field of natural product synthesis, for example, for the synthesis of theWieland-Miescher ketone – a vital building block for more complex biologically active molecules.[25][26]
Enamines act as nucleophiles that require less acid/base activation for reactivity than their enolate counterparts. They have also been shown to offer a greater selectivity with fewer side reactions. There is a gradient of reactivity among different enamine types, with a greater reactivity offered by ketone enamines than their aldehyde counterparts.[27] Cyclic ketone enamines follow a reactivity trend where the five membered ring is the most reactive due to its maximally planar conformation at the nitrogen, following the trend 5>8>6>7 (the seven membered ring being the least reactive). This trend has been attributed to the amount of p-character on the nitrogen lone pair orbital - the higher p character corresponding to a greater nucleophilicity because the p-orbital would allow for donation into the alkene π- orbital. Analogously, if the N lone pair participates in stereoelectronic interactions on the amine moiety, the lone pair will pop out of the plane (willpyramidalize) and compromise donation into the adjacent π C-C bond.[28][29]
There are many ways to modulate enamine reactivity in addition to altering the steric/electronics at the nitrogen center including changing temperature, solvent, amounts of other reagents, and type of electrophile. Tuning these parameters allows for the preferential formation of E/Z enamines and also affects the formation of the more/less substituted enamine from the ketone starting material.[30]
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