Imines formation from carbonyl compounds

TiCl4 also effectively promotes formation of imines and enamines from carbonyl compounds (Scheme 31). The combination of imine formation using TiCl4 and reduction leads to reductive alkylation of an amine moiety.113,114... 

Common reactions of the ylide include (i) [2,3]-sigmatropic rearrangement of allylic, propargylic, and allenic ylides (ii) [l,2]-shift (Stevens rearrangement) (iii) 1,3-dipolar cycloaddition of the ylide generated from carbonyl compounds or imines with dipolarophiles, usually G=G or C=C bonds and (iv) nucleophilic addition/elimination, leading to the formation of epoxides or cyclopropanes (Figure 2). 

Preparation of imines and enamines from carbonyl compounds and amines can be achieved with a dehydrating agent under acid/base catalysis [563]. Basically, primary amines afford imines unless isomerization to an enamine is favored as a result of conjugation, etc (see Eq. 252), and secondary amines afford iminium salts or enamines. These transformations can be conducted efficiently with a catalytic or stoichiometric amount of a titanium salt such as TiCU or Ti(0-/-Pr)4. Equation (247) illustrates an advantageous feature of this method in the imination of a hindered ketone. f-Butyl propyl ketone resisted the formation of the imine even by some methods reported useful for sterically hindered ketones [564,565]. The TiCU-based method works well, however, for this compound, giving the desired imine in high yield within a relatively short reaction period [566]. Imine derivatives such as iV-sulfonylimines could be... 

Scheme 223. Ylide Formation from Diazo Compounds Bearing a Carbonyl or Imine Group...

Classically, imines have been obtained via derivatisation of carbonyl compounds although problems exist in the use of unreactive carbonyl compounds and/or volatile imines. This transformation has nevertheless been achieved in excellent yields in the absence of solvent merely by treating carbonyl compounds dispersed on alumina with amines that have been similarly dispersed on alumina, Trimethylsily1 trifluoromethanesulphonate has been found to catalyse formation of imines from carbonyl compounds and 1,N-bis-(trimethysilyl )amines, these reactions also proceeding in excellent yield.The same research group also discovered that sulphen-imines could be isolated from reactions between tJ-bis (trimethyl-... 

The formation of imines, oximes, hydrazones, and related derivatives from carbonyl compounds is reversible. Write a detailed mechanism for the acid-catalyzed hydrolysis of eyclohexanone semicarbazone to cyclohexanone and semicarbazide. 

The Kabachnik-Fields reaction is a three-component hydrophosphonylation of imines formed in the reaction mixture from carbonyl compounds and amines [75]. In 2008, List and coworkers reported on such a reaction catalyzed by chiral phosphoric acids that combines a dynamic kinetic resolution with the concomitant generation of a new stereogenic center (Scheme 42.30). The resolution is possible when chiral racemic aldehydes 135 are used. This is because the imine formed in the first step of the reaction is in equilibrium with its achiral enamine tautomer, thereby racemizing the starting material continuously. Since one of the two enantiomers is selectively activated by the chiral phosphoric acid catalyst, the addition of phosphite 136 affords the exclusive formation of one diastereomer. All phos-phonate products 137 were obtained with good yields and moderate to excellent diastereo- and enantioselectivity [76]. 

Amines can react with various carbonyl compounds and their derivatives in aqueous media to give the corresponding imine derivatives. These reactions have been discussed in related chapters. The synthetically most useful reaction of this type is the formation of imines and imine derivatives from the condensation of amines with aldehydes and ketones. Water is an excellent solvent for such condensation reactions. For example, water was found to be an ideal solvent for a high-yield, fast preparation of easily hydrolyzable 2-pyrrolecarbaldimines.23 In the presence of Cu2+, the reaction afforded the corresponding Cu(II) chelates (Eq. 11.19). 

Ugi and Domling have shown that the U-4CR can also be combined with other MCRs, thus creating sequences which involve up to nine different substrates [33]. An example of such an approach is the combination of an Ugi-4CR with the as-yet not mentioned Asinger reaction (A-3CR or A-4CR). The latter allows the formation of thiazolines from ammonia, carbonyl compounds and sulfides [34]. As shown in Scheme 9.7, a mixture of a-bromoisobutyraldehyde, isobutyraldehyde, sodium hy-drogensulfide and ammonia yields the imine 9-38 which, by reaction with t-butyl-isocyanide, methanol, and C02, led to the final product 9-39 [35]. 

The combined reaction thus involves initial formation of the iminium ion from the carbonyl compound and amine at pH 6, and this intermediate is then reduced by the complex metal hydride to give the amine. This can also he a way of making methyl-suhstituted amines via intermediate imines with formaldehyde. 

One problem in the anti-selective Michael additions of A-metalated azomethine ylides is ready epimerization after the stereoselective carbon-carbon bond formation. The use of the camphor imines of ot-amino esters should work effectively because camphor is a readily available bulky chiral ketone. With the camphor auxiliary, high asymmetric induction as well as complete inhibition of the undesired epimerization is expected. The lithium enolates derived from the camphor imines of ot-amino esters have been used by McIntosh s group for asymmetric alkylations (106-109). Their Michael additions to some a, p-unsaturated carbonyl compounds have now been examined, but no diastereoselectivity has been observed (108). It is also known that the A-pinanylidene-substituted a-amino esters function as excellent Michael donors in asymmetric Michael additions (110). Lithiation of the camphor... 

Ethers, sulfides, amines, carbonyl compounds, and imines are among the frequently encountered Lewis bases in the ylide formation from such metal carbene complex. The metal carbene in the ylide formation can be divided into stable Fisher carbene complex and unstable reactive metal carbene intermediates. The reaction of the former is thus stoichiometric and the latter is usually a transition metal complex-catalyzed reaction of a-diazocarbonyl compounds. The decomposition of a-diazocarbonyl compounds with catalytic transition metal complex has been the most widely used approach to generate reactive metal carbenes. For compressive reviews, see Refs 1,1a. 

Thermodynamic template reactions allow the formation of hydrazones from hydrazines and carbonyl compounds, in the same manner as simple imines are formed. However, in many cases it is more convenient to form hydrazones in non-template reactions, as they are generally easier carbonyl derivatives to isolate than are simple imines. Hydrazone complexes often are capable of further manipulation and both aspects of synthesis and reactivity will be combined in this section. 

It is known that electrochemical reduction of oximes in protic media occurs in two steps the N—O bond is first reduced to form an imine and the latter is then reduced to afford a primary amine1,29. Tallec has shown that the amine from oxime 33 can be trapped intramolecularly (equation 16)35. Interestingly, the SS diastereomer predominates the chiral pyrrolidine ring derivative serves to control the stereochemistry of formation of the new benzylic chiral center. Electrochemical reductive cross-coupling of O-methyl oximes with carbonyl compounds in isopropanol at a tin cathode affords adducts (equation 17) which can be reduced further to 2-amino alcohols36. In this fashion, menthone could... 

The reduction is usually effected catalytically in ethanol solution using hydrogen under pressure in the presence of Raney nickel. As in the reduction of nitriles (Section 5.16.1, p. 771), which also involves the intermediate imine, ammonia or the amines should be present in considerable excess to minimise the occurrence of undesirable side reactions leading to the formation of secondary and tertiary amines. These arise from the further reaction of the carbonyl compound with the initially formed amine product. Selected experimental conditions for these reductive alkylation procedures have been well reviewed.210 Sodium borohydride has also been used as an in situ reducing agent and is particularly effective with mixtures of primary amines and aliphatic aldehydes and ketones.211... 

Even if the imine may not be isolated, the transient species may sometimes be trapped by reaction with a suitable nucleophile. This is the basis of the reductive amination reaction in which an amine is formed from the reaction of ammonia with a carbonyl compound in the presence of a reducing agent such as sodium borohydride or formate. Use of a primary or secondary amine results in the specific formation of secondary or tertiary amines respectively (Fig. 5-45). This synthetic method allows the preparation of high yields of amines, in contrast to the unselective and uncontrollable reaction of alkylating agents with amines. A specific example involving the preparation of a-phenylethylamine from acetophenone is presented in Fig. 5-46. 

The position of the equilibrium between imine and carbonyl may be perturbed by interaction with a metal ion. We saw in Chapter 2 how back-donation of electrons from suitable orbitals of a metal ion may stabilise an imine by occupancy of the jc level. It is possible to form very simple imines which cannot usually be obtained as the free ligands by conducting the condensation of amine and carbonyl compounds in the presence of a metal ion. Reactions which result in the formation of imines are considered in this chapter even in cases where there is no evidence for prior co-ordination of the amine nucleophile to a metal centre. Although low yields of the free ligand may be obtained from the metal-free reaction, the ease of isolation of the metal complex, combined with the higher yields, make the metal-directed procedure the method of choice in many cases. An example is presented in Fig. 5-47. In the absence of a metal ion, only low yields of the diimine are obtained from the reaction of diacetyl with methylamine. When the reaction is conducted in the presence of iron(n) salts, the iron(n) complex of the diimine (5.23) is obtained in good yield. 

In recent years, it has been shown that co-ordinated phosphines may also undergo reactions with carbonyl compounds. This is well exemplified in the reactions of [(MeHPCH2CH2PHMe)2Pd]2+ (Fig. 5-51). The reaction with formaldehyde yields a complex of an open-chain hydroxymethyl substituted ligand, the same species that is obtained from reaction of the free ligand. This is the phosphorus analogue of the aminol intermediate in imine formation. It is extremely unusual to obtain RP=CR2 systems in the absence of sterically demanding substituents. 

Probably one of the commonest reactions encountered in the template synthesis of macrocycles is the formation of imine C=N bonds from amines and carbonyl compounds. We have seen in the preceding chapters that co-ordination to a metal ion may be used to control the reactivity of the amine, the carbonyl or the imine. If we now consider that the metal ion may also play a conformational role in arranging the reactants in the correct orientation for cyclisation, it is clear that a limitless range of ligands can be prepared by metal-directed reactions of dicarbonyls with diamines. The Tt-acceptor imine functionality is also attractive to the co-ordination chemist as it gives rise to strong-field ligands which may have novel properties. All of the above renders imine formation a particularly useful tool in the arsenal of preparative co-ordination chemists. Some typical examples of the templated formation of imine macrocycles are presented in Fig. 6-12. 

Pyrazines are formed from transamination reactions, in addition to carbon dioxide and formaldehyde. A requirement is that the carbonyl compound contains a dione and the amino group is alpha to the carboxyl group (16). If the hydrogen on the ct-carbon oI the amino acid is substituted, a ketone is produced. Newell (17) initially proposed a pyrazine formation mechanism between sugar and amino acid precursors. (See Figure 3). The Schiff base cation is formed by addition of the amino acid to the anomeric portion of the aldo-hexose, with subsequent losses of vater and a hydroxyl ion. Decarboxylation forms an imine which can hydrolyze to an aldehyde and a dienamine. Enolization yields a ketoamine, vhich dissociates to amino acetone and glyceraldehyde. 2,5-Dimethylpyrazine is formed by the condensation of the tvo molecules of amino acetone. 

Reactions proceeding more than once in the transformation of a substrate can be more effective than a single process If the reaction in question is a condensation of an N nucleophile with a carbonyl compound, the combination of the of two such reactions—allows for the synthesis of heterocycles like, the two depicted in Figure 9.27. The synthesis of quinoxaline (B) from glyoxal dihydrate (A) and orfho-phenylene diamine consists of two imine formations. Somewhat more complicated is the synthesis of dimethylpyrrole D from acetonyl acetone (C) and ammonia. After the formation of the first imine, an imine enamine isomerization occurs. A condensation followed by another imine — enamine isomerization leads to the product. 

The mechanism involves the preliminary formation of an imine salt from the amine and formaldehyde. The amine is nucleophilic and attacks the more electrophilic of the two carbonyl compounds available. That is, of course, formaldehyde. No acid is needed for this addition step, but acid-catalysed dehydration of the addition product gives the imine salt. In the normal Mannich reaction, this is just an intermediate but it is quite stable and the corresponding iodide is sold as Eschenmoser s salt for use in Mannich reactions. 

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