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Imine formation ketone

The second reaction starts with nucleophilic attack by the amine on the more electrophilic carbonyl group - the ketone. Imine formation is followed by cyclization and this second step is i normal nucleophilic substitution at the carbonyl group of an ester (Chapter 12). The imine double bond moves into the ring to secure conjugation with the ester. [Pg.106]

Amin omethyl-3,5,5-trimethyl cyclohexyl amine (21), commonly called isophoronediamine (IPD) (51), is made by hydrocyanation of (17) (52), (53) followed by transformation of the ketone (19) to an imine (20) by dehydrative condensation of ammonia (54), then concomitant hydrogenation of the imine and nitrile functions at 15—16 MPa (- 2200 psi) system pressure and 120 °C using methanol diluent in addition to YL NH. Integrated imine formation and nitrile reduction by reductive amination of the ketone leads to alcohol by-product. There are two geometric isomers of IPD the major product is ds-(22) [71954-30-5] and the minor, tram-(25) [71954-29-5] (55). [Pg.210]

We have previously discussed that keto-aldehydes react with anilines first at the aldehyde carbon to form the aldimine. Subsequent condensation with another aniline formed a bis-imine or enamino-imine. The aniline of the ketimine normally cyclizes on the aldimine (24 —> 26). Conversely, cyclization of the aldimine could be forced with minimal aniline migration to the ketimine using PPA (30 —> 31). The use of unsymmetrical ketones has not been thoroughly explored a few examples are cited below. One-pot enamine formation and cyclization occurred when aniline 48 was reacted with dione 49 in the presence of catalytic p-TsOH and heat. Imine formation occurred at the less-hindered ketone, and cyclization with attack on the reactive carbonyl was preferred. ... [Pg.395]

Analogous to the selectivity observed for the conversion of 48 into 50, pyridyl 51 formed enamine 52 which underwent cyclization to give 4-pyridyl-substituted quinoline 53. Again, imine formation first occurs on the less hindered ketone and subsequent cyclization on the more reactive carbonyl occurred in high yield. ... [Pg.395]

Mechanism of imine formation by reaction of an aldehyde or ketone with a primary amine. [Pg.711]

Imine formation from such reagents as hydroxylamine and 2,4-dinitro-phenylhydrazine is sometimes useful because the products of these reactions— oximes and 2,4-dinitrophenylhydrazones (2,4-DNPs), respectively—are often crystalline and easy to handle. Such crystalline derivatives are occasionally prepared as a means of purifying and characterizing liquid ketones or aldehydes. [Pg.712]

Reaction of an aldehyde or ketone with a secondary amine, R2NH, rather than a primary amine yields an enamine. The process is identical to imine formation up to the iminium ion stage, but at this point there is no proton on nitrogen that can be lost to form a neutral imine product. Instead, a proton is lost from the neighboring carbon (the a carbon), yielding an enamine (Figure 19.10). [Pg.713]

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. [Pg.714]

An attractive alternative to these novel aminoalcohol type modifiers is the use of 1-(1-naphthyl)ethylamine (NEA, Fig. 5) and derivatives thereof as chiral modifiers [45-47]. Trace quantities of (R)- or (S)-l-(l-naphthyl)ethylamine induce up to 82% ee in the hydrogenation of ethyl pyruvate over Pt/alumina. Note that naphthylethylamine is only a precursor of the actual modifier, which is formed in situ by reductive alkylation of NEA with the reactant ethyl pyruvate. This transformation (Fig. 5), which proceeds via imine formation and subsequent reduction of the C=N bond, is highly diastereoselective (d.e. >95%). Reductive alkylation of NEA with different aldehydes or ketones provides easy access to a variety of related modifiers [47]. The enantioselection occurring with the modifiers derived from NEA could be rationalized with the same strategy of molecular modelling as demonstrated for the Pt-cinchona system. [Pg.58]

Ketone imine anions can also be alkylated. The prediction of the regioselectivity of lithioenamine formation is somewhat more complex than for the case of kinetic ketone enolate formation. One of the complicating factors is that there are two imine stereoisomers, each of which can give rise to two regioisomeric imine anions. The isomers in which the nitrogen substituent R is syn to the double bond are the more stable.114... [Pg.50]

Compared to the cyclic ketones, the coupling of aliphatic aldehydes to prepare 3-substituted indoles was less successful, except for phenyl acetaldehyde, which afforded 3-phenyl indole 83 in 76% yield (Scheme 4.22). The lack of imine formation or the instability of the aliphatic aldehyde towards the reaction conditions may be responsible for the inefficiency of these reactions. Therefore, a suitable aldehyde equivalent was considered. With the facile removal of a 2-trialkylsilyl group from an indole, an acyl silane was tested as a means of preparing 3-substituted indoles. Indeed, coupling of acetyl trimethylsilane with the iodoaniline 24 gave a 2 1 mixture of 2-TMS-indole 84 and indole (85) in a combined 64% yield. Evidently, the reaction conditions did lead to some desilylation. Regardless, the silyl group of 84 was quantitatively removed upon treatment with HC1 to afford indole (85). [Pg.138]

We saw that reaction of amines with aldehydes or ketones led to imine formation, rather than the simple aminoalcohol addition prodnct (see Section 7.7.1). This was because, in acidic solntion, the protonated aminoalcohol had two possible leaving groups, and water rather than the amine was the better leaving group. Dehydration occurs, leading to the imine. [Pg.270]

We thus have standard imine formation in this case, the secondary amine leads to an iminium cation. This is attacked by the ketone nncleophile. This cannot be an enolate anion because of the mild acidic conditions under which the reaction proceeds, so we formnlate it as involving the enol tantomer. Accordingly, we need to include an acid-catalysed enolization step. [Pg.662]

We shall consider the sequence as firstly imine formation (an abbreviated form of this mechanism is shown), followed by imine-enamine tautomerism. This provides a nucleophilic centre and allows a subsequent aldol-type reaction with enamine plus ketone. The pyrrole ring is produced by proton loss and a dehydration. [Pg.669]

The aldehyde can be replaced by an imine and the reaction is then called the aza-Baylis-Hillman reaction [87, 88]. (3-Amino-a-methylene structures obtained in this way could further be converted to a range of biologically important molecules, such as p-amino acids [89]. First reaction of this kind was published in 1984 [90]. Tosylimines and ethylacrylate reacted in the presence of DABCO as catalyst to give p-aminoesters. First three-component aza-Baylis-Hillman reaction was published in 1989 by Bertenshaw and Kahn [91], with imine formation in situ from an aldehyde and an amine. In the presence of triphenylphosphine as catalyst, the reaction with methylacrylate led to the formation of the p-amino-ot-methylene esters and ketones in good yields (Scheme 38). [Pg.191]

Polyquinolines (PQ) are obtained by the Friedlander reaction of a bis-o-aminoaromatic aldehyde (or ketone) with an aromatic hisketomethylene reactant [Concilio et al., 2001 Stille, 1981]. The quinoline ring is formed hy a combination of an aldol condensation and imine formation (Eq. 2-221). Polymerization is carried out at 135°C in m-cresol with poly (phosphoric acid) as the catalyst. The reaction also proceeds under base catalysis, but there... [Pg.162]

Although the fluoride anion is not a good leaving group (because of the great strength of the C-F bond), ketones, imines and jS-fluoroesters easily afford this S-elimination reaction (Fig. 22) [77], The S-elimination process remains efficient for CF2 and CF3 compounds, while the C-F bond is stronger. Indeed, fluorine atoms render more acidic the a proton, which makes easier the formation of the anion. [Pg.576]

Secondary amine reacts with aldehyde and ketone to produce enamine. An enamine is an a,P-unsaturated tertiary amine. Enamine formation is a reversihle reaction, and the mechanism is exactly the same as the mechanism for imine formation, except the last step of the reaction. [Pg.219]

One of the most spectacular and useful template reactions is the Curtis reaction , in which a new chelate ring is formed as the result of an aldol condensation between a methylene ketone or inline and an imine salt. The initial example of this reaction was the formation of a macrocyclic nickel(II) complex from tris(l,2-diaminoethane)nickel(II) perchlorate and acetone (equation 53).182 The reaction has been developed by Curtis and numerous other workers and has been reviewed.183 In mechanistic terms there is some circumstantial evidence to suggest that the nucleophile is an uncoordinated aoetonyl carbanion which adds to a coordinated imine to yield a coordinated amino ketone (equation 54). If such a mechanism operates then the template effect is largely, if not wholly, thermodynamic in nature, as described for imine formation. Such a view is supported by the fact that the free macrocycle salts can be produced by acid catalysis alone. However, this fact does not... [Pg.449]

Ammonia reacts with the ketone carbonyl group to give an imine (C=NH), which is then reduced to the amine function of the a-amino acid. Both imine formation and reduction are enzyme-catalyzed. The reduced form of nicotinamide adenine diphosphonu-cleotide (NADPH) is a coenzyme and acts as a reducing agent. The step in which the imine is reduced is the one in which the chirality center is introduced and gives only L-glutamic acid. [Pg.1131]

The presence of a colored solid confirms the presence of a ketone or aldehyde, but the imine formation does not indicate whether the unknown is a ketone or aldehyde. A second classification test is used to distinguish the two functionalities. This test is called the Tpllens test, and die significant reaction is shown in Reaction 2. [Pg.118]

One published synthesis of this amine 17 is by reductive animation.2 Note that it is not necessary, nor usually desirable, to isolate the rather unstable imine as reduction with NaB(CN)H3 or NaB(OAc)3H occurs under the conditions of imine formation.3 Since the imine is in equilibrium with the starting materials, slightly acidic conditions must be used so that the protonated imine is reduced more rapidly than the aldehyde or ketone. These two reducing agents are stable down to about pH 5. [Pg.54]


See other pages where Imine formation ketone is mentioned: [Pg.205]    [Pg.217]    [Pg.1305]    [Pg.166]    [Pg.1215]    [Pg.10]    [Pg.250]    [Pg.347]    [Pg.1553]    [Pg.1565]    [Pg.70]    [Pg.662]    [Pg.246]    [Pg.308]    [Pg.1056]    [Pg.249]    [Pg.280]    [Pg.285]    [Pg.497]    [Pg.276]    [Pg.901]    [Pg.126]    [Pg.167]    [Pg.212]    [Pg.71]    [Pg.127]   
See also in sourсe #XX -- [ Pg.724 , Pg.725 , Pg.726 , Pg.744 ]

See also in sourсe #XX -- [ Pg.724 , Pg.725 , Pg.726 , Pg.744 ]

See also in sourсe #XX -- [ Pg.724 , Pg.725 , Pg.726 , Pg.744 ]

See also in sourсe #XX -- [ Pg.672 , Pg.673 , Pg.689 ]

See also in sourсe #XX -- [ Pg.746 , Pg.748 , Pg.763 ]

See also in sourсe #XX -- [ Pg.708 , Pg.722 ]




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