Imines with ketones

NbCI3-(DME) and NbCI4(THF)2 catalysts in the synthesis of Vic diamines, 2-aminoalcohols or 2,3-disubstituted-1-naphthols by coupling of imines, imines with ketones or dialdehydes acetylenes... 

Scheme 3.3 L-Proline-catalysed Mannich reactions of cyclic imines with ketones.

Synthesis of 1,2-aminoalcohols via cross-coupling of imines with ketones or aldehydes can be achieved using TifOPr-r /c-CsHgMgCl in Et20, although some ketones form cm-2,3-dialkyl aziridines predominantly. ... 

Ketones and imines with adjacent perfluoroalkyl moieties show sharply reduced abilities to interact with electrophiles. Hexafluoroacetone is not protonated even in superacidic media... 

Spectroscopic investigation of enamines conjugated with ketone, ester and nitrile groups established the prevalence of enamine rather than imine-enol tautomers in examples of secondary amines (206-212). Similar studies have been made with enamines of acylpyridines and acetophenones (213,214). 

Imine formation is reversible. Show all the steps involved in the acid-catalyzed reaction of an imine with water (hydrolysis) to yield an aldehyde or ketone plus primary amine. 

Step 1 of Figure 29.14 Transimination The first step in transamination is trans-imination—the reaction of the PLP—enzyme imine with an a-amino acid to give a PLP—amino acid imine plus expelled enzyme as the leaving group. The reaction occurs by nucleophilic addition of the amino acid -NH2 group to the C=N bond of the PLP imine, much as an amine adds to the C=0 bond of a ketone or aldehyde in a nucleophilic addition reaction (Section 19.8). The pro-tonated diamine intermediate undergoes a proton transfer and expels the lysine amino group in the enzyme to complete the step. 

Finally, chromium imine carbenes underwent photoreaction with imines to give azadienes (metathesis) (Eq. 36), with azobenzene to give both metathesis and cycloaddition products (Eq. 37), and with ketones to give oxazolines... 

The addition of ammonia to aldehydes or ketones does not generally give useful products. According to the pattern followed by analogous nucleophiles, the initial products would be expected to be hemiaminals, but these compounds are generally unstable. Most imines with a hydrogen on the nitrogen spontaneously poly-... 

Condensation of heptamethyldisilazane 525 a (=424) with ketones or aldehydes such as benzaldehyde, in the presence of catalytic amounts of trimethylsilyl triflate 20, in CH2CI2 or C1(CH2)2C1, at room temperature or on gentle heating, gives imines such as 528 in nearly quantitative yield [102] (Scheme 5.33). 

Scheme 5.9 NHC-Ni catalysed [3-I-2] cycloaddition reaction of cyclopropyl ketones or cyclopropyl imines with enones...

The reductive alkylation of a primary amine with ketone leads to the formation of a stable imine. In the presence of hydrogen and a hydrogenation catalyst, the imine is reduced to a secondary amine. Similarly, a diamine reacts stepwise to form dialkylated secondary amines. However, several side reactions are possible for these reactions as outlined by Greenfield (12). The general scheme depicting the reaction between primary amine or diamine to yield secondary amine through a Schiff base is shown in Figure 17.1. 

The nitrogen analogs of ketones and aldehydes are called imines, azomethines, or Schiff bases, but imine is the preferred name and we use it here. These compounds can be prepared by condensation of primary amines with ketones or aldehydes.102 The equilibrium constants are unfavorable, so the reaction is usually driven forward by removal of water. 

Some remarkable chemistry is observed when silenes react with heteroatom systems, in particular carbonyl compounds (]>C=0) and imines Q>C=N—R). The reaction with ketones was first described by Sommer (203), who postulated formation of an intermediate siloxetane which could not be observed and hence was considered to be unstable even at room temperature, decomposing spontaneously to a silanone (normally isolated as its trimer and other oligomers) and the observed alkene [Eq. (14)]. Many efforts have been made to demonstrate the existence of the siloxetane, but it is only very recently that claims have been advanced for the isolation of this species. In one case (86) an alternative formulation for the product obtained has been advanced (204). In a second case (121) involving reaction of a highly hindered silene with cyclopentadienones,... 

The groups of Loupy and Jun have presented a chelation-assisted rhodium(I)-cata-lyzed ortho-alkylation of aromatic imines with alkenes (Scheme 6.57) [119]. The use of 2 mol% of Wilkinson s catalyst, RhCl(PPh3)3, and 5 equivalents of the corresponding alkene under solvent-free conditions proved to be optimal, providing the desired ortho-alkylated ketones in high yields after acidic hydrolysis. Somewhat lower yields were obtained when the imine preparation and the ortho-alkylation were realized in a one-pot procedure. 

The Friedlander reaction is the acid- or base-catalyzed condensation of an ortho-acylaniline with an enolizable aldehyde or ketone. Henichart and coworkers have described microwave-assisted Friedlander reactions for the synthesis of indoli-zino[l,2-b]quinolincs, which constitute the heterocyclic core of camptothecin-type antitumor agents (Scheme 6.238) [421], The process involved the condensation of ortho-aminobenzaldehydcs (or imines) with tetrahydroindolizinediones to form the quinoline structures. Employing 1.25 equivalents of the aldehyde or imine component in acetic acid as solvent provided the desired target compounds in 57-91% yield within 15 min. These transformations were carried out under open-vessel conditions at the reflux temperature of the acetic acid solvent. 

The TEAF system can be used to reduce ketones, certain alkenes and imines. With regard to the latter substrate, during our studies it was realized that 5 2 TEAF in some solvents was sufficiently acidic to protonate the imine (p K, ca. 6 in water). Iminium salts are much more reactive than imines due to inductive effects (cf. the Stacker reaction), and it was thus considered likely that an iminium salt was being reduced to an ammonium salt [54]. This explains why imines are not reduced in the IPA system which is neutral, and not acidic. When an iminium salt was pre-prepared by mixing equal amounts of an imine and acid, and used in the IPA system, the iminium was reduced, albeit with lower rate and moderate enantioselectivity. Quaternary iminium salts were also reduced to tertiary amines. Nevertheless, as other kinetic studies have indicated a pre-equilibrium with imine, it is possible that the proton formally sits on the catalyst and the iminium is formed during the catalytic cycle. It is, of course, possible that the mechanism of imine transfer hydrogenation is different to that of ketone reduction, and a metal-coordinated imine may be involved [55]. 

In contrast to the allyltitaniums derived from acrolein cyclic acetals, such as 1,2-dicyclo-hexylethylene acetal shown in Scheme 9.8, those derived from acrolein acyclic acetals react with ketones and imines exclusively at the y-position. As shown in Eq. 9.29, the reaction with chiral imines having an optically active 1-phenylethylamine moiety proceeds with high diastereoselectivity, thus providing a new method for preparing optically active 1-vinyl-2-amino alcohol derivatives with syn stereochemistry [53], The intermediate allyltita-nium species has also found use as a starting material for a carbozincation reaction [54],... 

Reactions with seven- to nine-membered cydic allylic carbonates or halides give the corresponding cydic allyltitanium compounds. These reagents add to aldehydes and imines with moderate to excellent diastereoselectivities [59]. The allyltitanium compound generated from 1-vinylcyclopropyl carbonate reacts regioselectively with aldehydes and ketones at the less substituted carbon atom to provide alkylidenecydopropane derivatives, as shown in Scheme 13.29 [60], The regiochemical outcome of the reaction can be rationalized by assuming an equilibrium between two allyltitanium spedes that favors the less strained tertiary structure. 

As such, a more thorough description of the energetics of nitroso compounds may well logically appear in a future Patai volume on functional groups devoted to carbon-containing double bonds such as monoalkenes, imines and ketones and aldehydes, since oximes would seem to belong with these functionalities. 

Prochirality Planar molecules possessing a double bond such as alkenes, imines, and ketones, which do not contain a chiral carbon in one of the side chains, are not chiral. When these molecules coordinate to a metal a chiral complex is formed, unless the alkene etc. has C2V symmetry. In other words, even a simple alkene such as propene will form a chiral complex with a transition metal. So will trans-2-butene, but cis-2-butene won t. If a bare metal atom coordinates to cis-2-butene the complex has a mirror plane, and hence the complex is not chiral. It is useful to give some thought to this and find out whether or not alkenes and hetero-alkenes form chiral complexes. One can also formulate it as follows complexation of a metal to the one face of the alkene gives rise to a certain enantiomer, and complexation to the other face gives rise to the other enantiomer. 

This procedure is an adaptation of that described by Emmons for the preparation of oxaziranes from imines using peracetic acid. Other procedures which may be more useful for oxazirane preparation in specific instances are the oxidation of imines with iw-chloroperbenzoic acid and the reaction of aldehydes or ketones with hydroxylamine 0-sulfonic acid in alkaline solution. 2-<-Butyl-3-phenyloxazirane has also been prepared by photolysis of a-phenyl-N-f-butylnitrone (a general reaction of considerable theoretical interest since it represents direct conversion of electromagnetic energy to chemical energy) and in low yields by ozonoly-sis of N-f-butylbenzaldimine. ... 

Additions of organometallics to the C=N bond of imines, oximes, hydrazones, and nitrones have been reviewed, with emphasis on the issues of reactivity and selectivity. Recent advances in enantioselective addition to imines of ketones are highlighted. 

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. 

There is a distinct relationship between keto-enol tautomerism and the iminium-enamine interconversion it can be seen from the above scheme that enamines are actually nitrogen analogues of enols. Their chemical properties reflect this relationship. It also leads us to another reason why enamine formation is a property of secondary amines, whereas primary amines give imines with aldehydes and ketones (see Section 7.7.1). Enamines from primary amines would undergo rapid conversion into the more stable imine tautomers (compare enol and keto tautomers) this isomerization cannot occur with enamines from secondary amines, and such enamines are, therefore, stable. 

Scheme 58 [3+2] Cycloaddition of azomethine imines with a, 3-unsaturated ketones...

M. Shi and Y.-L. Shi reported the synthesis and application of new bifunctional axially chiral (thio) urea-phosphine organocatalysts in the asymmetric aza-Morita-Baylis-Hillman (MBH) reaction [176, 177] of N-sulfonated imines with methyl vinyl ketone (MVK), phenyl vinyl ketone (PVK), ethyl vinyl ketone (EVK) or acrolein [316]. The design of the catalyst structure is based on axially chiral BINOL-derived phosphines [317, 318] that have already been successfully utilized as bifunctional catalysts in asymmetric aza-MBH reactions. The formal replacement of the hydrogen-bonding phenol group with a (thio)urea functionality led to catalysts 166-168 (Figure 6.51). 

Fluoral hydrate and hemiacetals are industrial products. They are stable liquids that are easy to handle, and they react as fluoral itself in many reactions. Thus, in the presence of Lewis acids, they react in Friedel-Crafts reactions. They also react very well with organometallics (indium and zinc derivatives) and with silyl enol ethers.Proline-catalyzed direct asymmetric aldol reaction of fluoral ethyl hemiac-etal with ketones produced jS-hydroxy-jS-trifluoromethylated ketones with good to excellent diastereo- (up to 96% de) and enantioselectivities. With imine reagents, the reaction proceeds without Lewis acid activation. The use of chiral imines affords the corresponding 8-hydroxy ketones with a 60-80% de (Figure 2.49). ° ... 

Other examples of functionalized thiocarbonyl ylides that have been generated by the desilylation method are those bearing an imino group (49) (see Scheme 5.7). These ylides readily undergo [3 + 2] cycloaddition with aromatic aldehydes to afford l,3-thioxolane-2-imines of type 24 (X = RiN). The reaction with ketones is sluggish, however, and the cycloadducts are obtained in very low yield. 

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