Imine from ketones

For the preparation of enamines or imines from ketones, see Section 356 (Amine-Alkene). 0 1. CFsSOsSiMes, MeCN S... 

Methods for the preparation of hydrazones and oximes differ little from those used for the synthesis of imines from ketones and aldehydes in that the appropriate nitrogen species and the ketone are mixed. However, the equilibrium for the majority of reactions of ketones and aldehydes with hydrazines and hy-droxylamine favor the product hydr nes and oximes and removal of the water formed by the condensation is not required. 8(> Acid catalysis is complicated by the basicity of the reagent and, for example, the maximum rate of oxime formation is at approximately pH 4. Complicating reactions can occur such as the 1 2 combination of hydrazine with two ketones or aldehydes to form azines but this is not a problem with the substituted hydrazines that are used for asymmetric induction. 

This section contains alkylations of ketones and protected ketones, ketone transpositions and annulations, ring expansions and ring openings, and dimerizations. Conjugate reductions and Michael alkylations of enone are listed in Section 74 (Alkyls, Methylenes, and Aryls from Alkenes). For the preparation of enamines or imines from ketones, see Section 356 (Amine-Alkene). 

Imines from ketones with retention of halogen... 

Aldehydes and ketones serve as useful precursors to amino acids when they are converted to a Schiff base (from aldehydes) or an imine (from ketones). Reduction of the imino C=N moiety, usually in situ, generates the amine. When 1.83 (m = 1, 2) was treated with ammonia, for example, the resulting iminium salt (1,84) was hydrogenated to give either 8-aminooctanoic acid (7.[Pg.18]

Enamines derived from ketones are allylated[79]. The intramolecular asymmetric allylation (chirality transfer) of cyclohexanone via its 5-proline ally ester enamine 120 proceeds to give o-allylcyclohexanone (121) with 98% ee[80,8l]. Low ee was observed in intermolecular allylation. Similarly, the asymmetric allylation of imines and hydrazones of aldehydes and ketones has been carried out[82]. 

The pyrrolo[3, 4 2,3]azepino[4,5,6-cd] indole-8,10-dione system can be accessed by reaction, under conditions used for the Pictet-Spengler reaction, of the imines from condensation of 3-amino-4-(3-indolyl) pyrrolin-2,5-diones with aldehydes or ketones. Cyclisation to the pyrrolo-P-carbolines did not occur under the conditions <00JHC1177>. 

Preparation of enantiomerically pare secondary amines by catalytic asymmetric hydrogenation or hydrosilylation of imines is as important as the preparation of alcohols from ketones. However, asymmetric hydrogenation of prochiral ON double bonds has received relatively less attention despite the obvious preparative potential of this process.98... 

Asymmetric catalytic reduction reactions represent one of the most efficient and convenient methods to prepare a wide range of enantiomerically pure compounds (i.e. a-amino acids can be prepared from a-enamides, alcohols from ketones and amines from oximes or imines). The chirality transfer can be accomplished by different types of chiral catalysts metallic catalysts are very efficient for the hydrogenation of olefins, some ketones and oximes, while nonmetallic catalysts provide a complementary method for ketone and oxime hydrogenation. 

Imines derived from ketones with an a-methylene group can react via their enamine tautomers, and mixtures of triazoles are also isolated from these systems. The triazoline adducts of the enamine tautomers are aromatized by treating with acid, and in these conditions the triazoline appears to undergo a Dimroth rearrangement before elimination of the amine, because two triazoles are obtained, one of which has... 

Catalytic asymmetric reduction of unsaturated compounds is one of the most reliable methods used to synthsize the corresponding chiral saturated products. Chiral transition metal complexes repeatedly activate an organic or inorganic hydride source, and transfer the hydride to olefins, ketones, or imines from one... 

In the presence of excess monoalkylamine, carbonyl compounds in aqueous solution are in equilibrium with the corresponding imine. In most cases these imines cannot be isolated but they are reduced at a less negative potential than the carbonyl compound. Selective reduction of such equilibrium mixtures is a useful route to alkylamines from ketones in yields of 70-90%. The process fails with hindered ketones such as camphor and with bulky amines such as fert.-butyl amine. Overall the reaction has advantages of lower costs and simpler work-up compared to the use of cyanoborohydride reducing agents. In the electrochemical reaction, protonation of carbanion intermediates occurs from the more hindered side and where two isomeric products are fomied, the least hindered amine predominates [193]. 

However, the syn and anti isomers of imines are easily thermally equilibrated. They cannot be prepared as single stereoisomers directly from ketones and amines so this method cannot be used to control regiochemistry of deprotonation. By allowing lithiated ketimines to come to room temperature, the thermodynamic composition is established. The most stable structures are those shown below, which in each case represent the less substituted isomer. 

In contrast to the chemical properties of enolates, azaenolates of imines exhibit a marked thermodynamic preference for the syn configuration at the C-N partial double bond (syn effect)2 due to the repulsion between the lone pair density at nitrogen and the 7t-electron density at the carbon. Thus, lithiation of imines derived from ketones occurs with strong regioselectiv-ity at the least substituted carbon, followed by a regioselective reaction with electrophiles exclusively at the carbon of the ambident azaalkyl moiety. 

The potential substrates for the Strecker reaction fall into two categories ald-imines (derived from aldehydes, for which cyanide addition results in formation of a tertiary stereocenter) and ketoimines (derived from ketones, for which addition results in a quaternary stereocenter). As in the case of carbonyl cyanation, significant differences are observed between the substrate subclasses. To date, while a few catalyst systems have been found to display broad substrate scope with respect to aldimine substrates, successful Strecker reactions of ketoimines have been reported in only two cases. As is the case for all asymmetric catalytic methodologies, the breadth of the substrate scope constitutes a crucial criterion for the application of the Strecker reaction to a previously unexplored substrate. 

Another class of problematic amines are a-amino nitriles, which are readily accessible from ketones, amines, and cyanide. Like a-amino acids, these amines are electronically deactivated and less basic and nucleophilic than purely aliphatic amines, and are therefore difficult to acylate. Some a-amino nitriles or the corresponding acylated derivatives can, furthermore, decompose into imines and cyanide if reaction temperatures are too high or if the bases used are too strong (Scheme 7.11). 

The phenols need to be protected as their methyl ethers 67 and functionalisation by SeC>2, as described earlier in this chapter, gives the keto-aldehyde 68. To get 65 we should have to reduce the ketone in the presence of the aldehyde but the workers at Boehringer discovered a shortcut reductive amination using hydrogenation reduced both the imine (from i-PrNH2 and the aldehyde) and the ketone to give 69 and hence, by deprotection, metaproterenol 64. Notice that the aldehyde in 68 is more electrophilic than the conjugated ketone so it forms the imine needed for reductive amination. 

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