Iminium Ion Formation

Very recently, a highly efficient synthesis of the erythrina and B-homoerythrina skeleton by an AlMe3-mediated three-step domino condensation-type/iminium ion formation/iminium ion cyclization sequence has been reported by Tietze and co-... 

As expected, some sequences also occur where a domino anionic/pericyclic process is followed by another bond-forming reaction. An example of this is an anionic/per-icyclic/anionic sequence such as the domino iminium ion formation/aza-Cope/ imino aldol (Mannich) process, which has often been used in organic synthesis, especially to construct the pyrrolidine framework. The group of Brummond [450] has recently used this approach to synthesize the core structure 2-885 of the immunosuppressant FR 901483 (2-886) [451] (Scheme 2.197). The process is most likely initiated by the acid-catalyzed formation of the iminium ion 2-882. There follows an aza-Cope rearrangement to produce 2-883, which cyclizes under formation of the aldehyde 2-884. As this compound is rather unstable, it was transformed into the stable acetal 2-885. The proposed intermediate 2-880 is quite unusual as it does not obey Bredf s rule. Recently, this approach was used successfully for a formal total synthesis of FR 901483 2-886 [452]. 

Cooke and coworkers reported on the synthesis of the amino acid N-benzyl-4-acetylproline (2-889) (Scheme 2.198) [453], as this might represent an interesting synthon for the preparation of bioactive compounds. These authors also used a domino iminium ion formation/aza-Cope/Mannich protocol. Thus, treatment of the secondary amine 2-885 with glyoxylic acid (2-888) primarily provided the corresponding iminium ion, which led to 2-889 in 64% yield as a mixture of diastereom-ers. 

In a series of important papers, MacMillan described the alkylation of electron rich aromatic and heteroaromatic nucleophiles with a,P-unsaturated aldehydes, using catalysts based upon the imidazoUdinone scaffold, further establishing the concept and utility of iminium ion activation. In line with the cycloaddition processes described above, the sense of asymmetric induction of these reactions can be rationalised through selective (F)-iminium ion formation between the catalyst and the a,P-unsaturated aldehyde substrate, with the benzyl arm of the catalyst blocking one diastereoface of the reactive Jt-system towards nucleophilic attack (Fig. 3). 

It is worth noting that use of unprotected diarylprolinol 33 provides an effective platform for the epoxidation of a,P-unsaturated ketones [148, 149]. Within these reports it was proposed that an alternative mode of activation of the substrate could be taking place. Hydrogen bonding catalysis, rather than iminium ion formation, could explain the results and would be consistent with the non-polar reaction medium adopted within these reactions. 

Aziridines represent an important class of building block within synthesis. This structural motif is also embedded within a number of biologically significant natural products, and thus robust and efficient methods for their construction represent an important contribution to the synthetic toolkit. Cordova reported an enantiose-lective aziridination of a,P-unsaturated aldehydes catalysed by diarylprolinol ether 30 using protected hydroxylamine 91 as the nitrogen source (Scheme 38) [150]. The reaction was proposed to proceed via iminium ion formation followed by... 

Ogilvie monitored the Diels-Alder reaction between cinnamaldehyde and cyclopentadiene by H NMR using his hydrazide catalyst 18 and was able to conclude that under the reaction conditions adopted (18-TfOH 100 mol% CDjNOj/D O (19 1) 0.1 M) cycloaddition was the rate limiting step of the catalytic cycle, iminium ion formation and hydrolysis being rapid [48]. In addition, it was also shown that under these reaction conditions the key cycloaddition step was reversible. Although this unexpected reversibility was slow, the possibility of exploiting this in a dynamic resolution procedure appears tempting. 

Hydrogen bonding to substrates such as carbonyl compounds, imines, etc., results in electrophilic activation toward nucleophilic attack (Scheme 3.1). Thus, hydrogen bonding represents a third mode of electrophihc activation, besides substrate coordination to, for example, a metal-based Lewis acid or iminium ion formation (Scheme 3.1). Typical hydrogen bond donors such as (thio)ureas are therefore often referred to as pseudo-Lewis-acids. ... 

In 2004, List reported that several ammonium salts including dibenzylammonium trifluoroacetate catalyzed the chemoselective 1,4 reduction of a, 5-unsaturated aldehydes with Hantszch esters as hydride sources [40]. It is assumed that substrate activation via iminium ion formation results in selective 1,4 addition of hydride. Subsequently, List [41] and MacMillan [42] reported asymmetric versions of this reaction promoted by chiral imidazoUdinone salts. In this context, several reports of this metal-free reductive process catalyzed by chiral phosphoric acids have appeared in the recent literature. 

Other less common but highly effective trapping techniques include cyanide trapping via iminium ion formation and methoxylamine or semicarbazide for reactive... 

Activation of Michael Acceptors by Iminium Ion Formation, Activation of Carbonyl Donors by Enamine Formation... 

The MacMillan catalysts (42, 45), the Jorgensen catalyst (51), and proline itself can promote Michael additions by iminium ion formation with the acceptor enal or enone (A, Scheme 4.22). Secondary amines can also activate a carbonyl donor by enamine formation (Scheme 4.22, B) [36, 37]. 

In order to test the iminium-activation strategy, MacMillan first examined the capacity of various amines to enantioselectively catalyze the Diels-Alder reaction between dienes and a,/ -unsaturated aldehyde dienophiles [6]. Preliminary experimental findings and computational studies proved the importance of four objectives in the design of a broadly useful iminium-activation catalyst (1) the chiral amine should undergo efficient and reversible iminium ion formation (2) high... 

For the most efficient bifunctional catalysts, it was found that proton abstraction from the iminium ion is not fully rate-limiting but that iminium-ion formation influences the overall rate (for a recent paper dealing with this aspect, see Hine et al., 1979). 

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