Imines mechanistic

A series of pyrrolo[l,2-c]imidazole mesomeric betaines (106) have been prepared in good yield by condensation of 2-formylpyrroles (114) with aromatic imines. Mechanistically, the reaction might proceed by condensation of the imines with 2-formylpyrroles to give 2,3-dihydro-17/-pyrrolo[l, 2-... 

The reaction of [Cr(tpp)Cl] with styrene ozonide yields an unusual isoporphyrin complex (Scheme 4). Although the overall stoichiometry corresponds to hydration of an imine, mechanistic studies suggested nucleophilic attack by an enamine upon the oxonide. Chromium(IV) intermediates are definitely precluded/ ... 

The mechanistic pathway of the ordinary Friedlander synthesis is not rigorously known. Two steps are formulated. In a first step a condensation reaction, catalyzed by acid or base, takes place, that can lead to formation of two different types of products (a) an imine (Schiff base) 4, or (b) an o ,/3-unsaturated carbonyl compound 5 ... 

Hydrolysis of this PMP-n-keto acid imine in step 4 then completes the first part of the transamination reaction. The hydrolysis is the mechanistic reverse of... 

Due to mechanistic requirements, most of these enzymes are quite specific for the nucleophilic component, which most often is dihydroxyacetone phosphate (DHAP, 3-hydroxy-2-ox-opropyl phosphate) or pyruvate (2-oxopropanoate), while they allow a reasonable variation of the electrophile, which usually is an aldehyde. Activation of the donor substrate by stereospecific deprotonation is either achieved via imine/enamine formation (type 1 aldolases) or via transition metal ion induced enolization (type 2 aldolases mostly Zn2 )2. The approach of the aldol acceptor occurs stereospecifically following an overall retention mechanism, while facial differentiation of the aldehyde is responsible for the relative stereoselectivity. 

The mechanistic analogy to the Streckcr synthesis becomes obvious in the addition of the isocyanide to the imine to produce the a-amino nitrilium intermediate. Since all four components are involved in this step, it might be expected that every chiral component (chiral groups R1, R2, R3, R4) contributes to diastereofacial differentiation in the nucleophilic attack on the imine. However, in peptide syntheses by four-component condensation5, the chiral isocyanide or a chiral carboxylic acid component has only limited influence on the diastereoselectivity of the a-amino amide formation5. 

The mechanistic possibilities for the imine formation by a base-promoted 1,2-elimination reaction are shown in Scheme 3. 

In a series of three papers, Noguchi and co-workers have reported their continuing studies on the formation of heterocycle-fused azepine systems <96X13081, 96X13097, 96X13111>. A typical example is the conversion of the aldehyde 15 into the azepines 16 and 17 (Scheme 3). Xhe reaction also proceeds with imines when the dihydroazepine prior to bridging can be isolated. Mechanistic and stereochemical aspects of the reaction have been explored. 

Fig. 41 Mechanistic proposal for highly electron-poor imines...

A mechanistic rationale for the observed cw-selectivity has been proposed based on preorganisation of the Breslow-type intermediate and imine through hydrogen bonding 253, with an aza-benzoin oxy-Cope process proposed. Reaction via a boat transition state delivers the observed cw-stereochemistry of the product (Scheme 12.57). Related work by Nair and co-workers (using enones 42 in place of a,P-unsaturated sulfonylimines 251, see Section 12.2.2) generates P-lactones 43 with fran -ring substituents, while the P-lactam products 252 possess a cw-stereo-chemical relationship. 

A variety of double bonds give reactions corresponding to the pattern of the ene reaction. Those that have been studied from a mechanistic and synthetic perspective include alkenes, aldehydes and ketones, imines and iminium ions, triazoline-2,5-diones, nitroso compounds, and singlet oxygen, 10=0. After a mechanistic overview of the reaction, we concentrate on the carbon-carbon bond-forming reactions. The important and well-studied reaction with 10=0 is discussed in Section 12.3.2. 

Formation of a bis-allylated product of 4-nitrobenzoyl chloride by the reaction with allyltrimethyltin in the presence of a benzylpalladium(ll) complex was observed by Stille and co-workers in 1983.4 Trost and King also reported allylation of aldehydes by allyltin reagents in 1990.456 However, the precise mechanism was unclear until the extended studies were performed by Yamamoto and co-workers since 1995.4S7,4S7a 4S7 Aldehydes and imines react with allyltin reagents in the presence of a palladium catalyst (Equations (95) and (96)), and imines are chemoselectively allylated in the presence of aldehydes (Equation (97)).4S7,4S7l 4 b Mechanistic studies using NMR spectroscopy proved that bis-7t-allylpalladium complex 203 is a key nucleophilic intermediate (Figure 3). 

Theoretical studies have been carried out on all the late transition metal catalysts la [10-13], lb [14] and lc [15] in Figure 1. It is not the objective here to review all the computational results. We shall instead describe the general mechanistic insight that has been gained from the theoretical studies with the main emphasis on Brookhart s bis-imine catalysts. The experimental work on late transition metal olefin polymerization catalysts has been reviewed recently by Ittel [16] et al. 

Interest is mounting in this state, promoted once again by its possible implication in biological systems. Galactose oxidase, for example, is a copper enzyme which catalyses the oxidation of galactose to the corresponding aldehyde. The tervalent oxidation state may be prepared from Cu(II) by chemical, anodic and radical oxidation. Cu(III) complexes of peptides and macrocycles have been most studied, particularly from a mechanistic viewpoint. The oxidation of I" by Cu(III)-deprotonated peptide complexes and by imine-oxime complexes have a similar rate law... 

Imine metathesis has continued to be a popular exchange reaction for DCLs. Various groups have found novel systems in which the reaction can be applied, as well as interesting ways to halt the equilibration. For example, Wessjohann and coworkers have demonstrated that Ugi reactions can efficiently halt equilibration of an imine DCL, combining an irreversible diversification process with areversible library selection [24]. Xu and Giusep-pone have integrated reversible imine formation with a self-duplication process [25], and Ziach and Jurczak have examined the ability of ions to template the synthesis of complex azamacrocycles [26]. The mechanistically related reactions of hydrazone [27] and oxime [28] exchange have also been explored as suitable foundations for DCL experiments. 

Another process mechanistically related to imine exchange is the dynamic production of pyrazolotriazinones reported in 2005 by Wipf and coworkers [29]. After first verifying that reaction of either 16 or 17 with equimolar quantifies of isobutyraldehyde and hydrocinnamaldehyde at 40°C in water (pH 4.0) resulted in the same 3 7 mixture of 16 and 17 at equilibrium (Fig. 1.6, Eq. 1), the authors demonstrated that a library could be generated by reaction of pyrazolotriazinone 16 with a series of aldehydes (Fig. 1.6, Eq. 2). Direct metathesis of pyrazolotriazinones was also demonstrated, as was reaction with ketones. Importantly, equilibration was halted by raising the pH to 7. 

Hydrolysis under basic conditions is mechanistically similar, also proceeding through a hydroxy-imine. The tautomeric amide then undergoes basic hydrolysis (see Section 7.9.2). 

The sequence can be rationalized mechanistically as involving nucleophilic attack of ammonia onto the aldehyde to produce an imine, which then acts as the electrophile for further nucleophilic attack, this time by the cyanide ion (see Section 7.7.1). The racemic amino acid is then formed by acid-catalysed hydrolysis of the nitrile function, as above (Box 7.9). 

This approach to the isoquinoline ring, albeit a reduced isoquinoline, is mechanistically similar to the Bischler-Napieralski synthesis, in that it involves electrophilic attack of an iminium cation on to an aromatic ring. In this case, the imine intermediate is formed by reacting a phenylethylamine with an aldehyde. 

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