Lithium aluminum hydride reduction, alcohols amines from

The first report in this regard described a method for direct formation of the desired optically active (S)-alcohol 32a, via enantioselective reduction with a chiral amine complex of lithium aluminum hydride (Scheme 14.9). Therefore, the necessary chiral hydride complex 38 was preformed in toluene at low temperature from chiral amino alcohol 37. The resulting hydride solution was then immediately combined with ketone 31 to afford the desired (S)-alcohol 32a in excellent yield and enantiomeric excess. In addition to providing a more efficient route to the desired drug molecule, this work also led to the establishment of the absolute configuration of duloxetine (3) as S). 

The diversity of the products obtained by the three-component domino-Knoevenagel-hetero-Diels-Alder reaction can be further increased by a different work-up of the formed cycloadduct 141. Thus, hydrogenolytic removal of the Cbz-group in 141 led to 151 with a lactam and an aldehyde moiety by reaction of the formed secondary amine with the lactone moiety followed by elimination of benzyl alcohol. Reduction of 151 with lithium aluminum hydride gave benzoquinolizidine 152 (Scheme 5.30). Alkaloids of this type have so far not been found in nature, but it can be assumed that they might exist, since they could easily be formed from deacetylisopecoside 153, which is an intermediate in the biosynthesis of emetine 111. 

Unsymmetrical secondary amines are readily prepared in good yields by the catalytic reduction of Schiff bases at moderate temperatures in high-or low-pressure equipment. Many examples have been cited. The intermediate imines are prepared from primary amines and aldehydes—very seldom from ketones—and may be used without isolation (cf. method 431). For the preparation of aliphatic amines, e.g., ethyl-w-propylamine and n-butylisoamylamine, a prereduced platinum oxide catalyst is preferred with alcohol as the solvent. Schiff bases from the condensation of aromatic aldehydes with either aromatic or aliphatic amines are more readily prepared and are reduced over a nickel catalyst. In this manner, a large number of N-alkylbenzylamines having halo, hydroxyl, or methoxyl groups on the nucleus have been made. Reductions by means of sodium and alcohol and lithium aluminum hydride have also been described,... 

Chiral Ligand of L1A1H4 for the Enantioselective Reduction of Alkyl Phenyl Ketones. Optically active alcohols are important synthetic intermediates. There are two major chemical methods for synthesizing optically active alcohols from carbonyl compounds. One is asymmetric (enantioselective) reduction of ketones. The other is asymmetric (enantioselective) alkylation of aldehydes. Extensive attempts have been reported to modify Lithium Aluminum Hydride with chiral ligands in order to achieve enantioselective reduction of ketones. However, most of the chiral ligands used for the modification of LiAlHq are unidentate or bidentate, such as alcohol, phenol, amino alcohol, or amine derivatives. 

Reduction of the ketolactam 390 (having the newly assigned A/B trans stereochemistry) with sodium borohydride followed by reduction of the amide with lithium aluminum hydride gave an amino alcohol. Oxidation of this amino alcohol with chromic acid followed by rereduction with lithium aluminum hydride gave an amino alcohol different from that obtained previously. In the oxidation to the ketone 373, therefore, epimerization at C-9a must have occurred, and the two amine alcohols must have the configurations 391 and 392. Since in both compounds Bohlmann bonds were observed in the IR spectrum, the A/ ring juncture is trans. 

Alkylation of Azide Ion and Reduction A much better method for preparing a primary amine from an alkyl halide is first to convert the alkyl halide to an alkyl azide (R—N3) by a nucleophilic substitution reaction, then reduce the azide to a primary amine with sodium and alcohol or with lithium aluminum hydride. 

Nitriles have been reduced with hydrogen and various catalysts [24] and by chemical means. Among the chemical reducing agents, sodium and alcohol have been used [23]. Deuterated amines have been produced from nitriles by reduction with lithium aluminum deuteride [25]. The prepration of cyclopropylmethylamine with lithium aluminum hydride is a related example of this reduction [26]. 

An asymmetric synthesis has used the reduction of imonium salts to optically active tertiary amines with lithium aluminum alkoxy hydrides derived from optically active alcohols (538,539). 

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