Olefinic amines reduction

Cyclopropane compounds containing the olefin isostere replacement for the amide bond were prepared using Julia olefination chemistry. Aldehydes 39 and 40 were obtained by LAAIH4 reduction of the chiral w-butyl esters of 32 and 33, respectively, followed by swera oxidation of the corresponding alcohols (Figure 22). Condensation of the (S)-N-BOC-cyclohexylalanine sulfone 41 with aldehyde 39 gave after treatment with 2% Na(Hg) and deprotection, the trans and cis olefin-amines... 

Studies have been made on the influence of various groups on the rate of hydrogenation of the double bond. Reductions of olefinic alcohols (method 85), olefinic aldehydes (method 161), olefinic ketones (method 196), olefinic acids (method 267), olefinic esters (method 303), olefinic Cyanides (method 394), and olefinic amines (method 460) are treated separately. 

An array of three transformations comprised of a consecutive olefin nitration/reduction protocol generates a racemic primary amine. 

Imines were preferentially formed and the carbon-carbon bond was selectively formed at the C(2) position of the cyclic amine. With ethylene and propene, only imines were formed but with more bulky olefins and 7-membered cyclic amines, reduction to 2-alkyl cyclic amine took place, and N-alkylation was also observed from bicyclic amine. 

Finally, racemic a-sparteine (266) was obtained upon global reduction of all olefin, aminal and carbonyl functions. 

The less hindered f/ans-olefins may be obtained by reduction with lithium or sodium metal in liquid ammonia or amine solvents (Birch reduction). This reagent, however, attacks most polar functional groups (except for carboxylic acids R.E.A. Dear, 1963 J. Fried, 1968), and their protection is necessary (see section 2.6). 

A number of less hindered monoalkylboranes is available by indirect methods, eg, by treatment of a thexylborane—amine complex with an olefin (69), the reduction of monohalogenoboranes or esters of boronic acids with metal hydrides (70—72), the redistribution of dialkylboranes with borane (64) or the displacement of an alkene from a dialkylborane by the addition of a tertiary amine (73). To avoid redistribution, monoalkylboranes are best used /V situ or freshly prepared. However, they can be stored as monoalkylborohydrides or complexes with tertiary amines. The free monoalkylboranes can be hberated from these derivatives when required (69,74—76). Methylborane, a remarkably unhindered monoalkylborane, exhibits extraordinary hydroboration characteristics. It hydroborates hindered and even unhindered olefins to give sequentially alkylmethyl- and dialkylmethylboranes (77—80). 

Nitio olefins can be made in some cases by dehydration of the aromatic nitrohydroxy derivatives. Subsequent reduction yields the aromatic amine. The following three-step reaction yielding 2-amino-l-phenylbutane illustrates the synthesis of this class of valuable pharmaceutical compounds. 

In addition to the nitrile and alcohol routes for fatty amine preparation, processes have been described by Unocal and Pennwalt Corporation, using an olefin and secondary amine (14—16) by Texaco Inc., hydrogenation of nitroparaffins (17—20) by Onyx Corporation, reaction of an alkyl haUde with secondary amines (21,22) by Henkel Cie, GmbH, reduction of an ester in the presence of a secondary amine (23) by catalytic hydroammonolysis of carboxyhc acids (24) and by the Hofmann rearrangement (25). 

Iodine azide, on the other hand, forms pure adducts with A -, A - and A -steroids by a mechanism analogous to that proposed for iodine isocyanate additions. Reduction of such adducts can lead to aziridines. However, most reducing agents effect elimination of the elements of iodine azide from the /mwj -diaxial adducts of the A - and A -olefins rather than reduction of the azide function to the iodo amine. Thus, this sequence appears to be of little value for the synthesis of A-, B- or C-ring aziridines. It is worthy to note that based on experience with nonsteroidal systems the application of electrophilic reducing agents such as diborane or lithium aluminum hydride-aluminum chloride may yet prove effective for the desired reduction. Lithium aluminum hydride accomplishes aziridine formation from the A -adducts, Le., 16 -azido-17a-iodoandrostanes (97) in a one-step reaction. The scope of this addition has been considerably enhanced by the recent... 

Olefins are also the products of hydroboratlon of enamines, followed by treatment of the organoborane products with hot acid (543,544). The reduction of enamines with sodium borohydride and acetic acid (545) and the selective reduction of dienamines with sodium borohydride to give homo-allylic tertiary amines (138-140,225,546,547), has been applied to the synthesis of conessine (548) and other aminosteroid analogs (545,549-552). Further examples of the reduction of imonium salts by sodium borohydride can be found in the reduction of Bischler-Napieralski products, and other cyclic imonium salts (102). 

The stereochemical course of reduction of imonium salts by Grignard reagents was found to depend on the structure of the reagent 714). Hydro-boration of enamines and oxidation with hydrogen peroxide led to amino-alcohols (7/5). While aluminum hydrogen dichloride reacted with enamines to yield mostly saturated amines and some olefins on hydrolysis, aluminum hydride gave predominantly the unsaturated products 716). 

ATBN - amine terminated nitrile rubber X - Flory Huggins interaction parameter CPE - carboxylated polyethylene d - width at half height of the copolymer profile given by Kuhn statistical segment length DMAE - dimethyl amino ethanol r - interfacial tension reduction d - particle size reduction DSC - differential scanning calorimetry EMA - ethylene methyl acrylate copolymer ENR - epoxidized natural rubber EOR - ethylene olefin rubber EPDM - ethylene propylene diene monomer EPM - ethylene propylene monomer rubber EPR - ethylene propylene rubber EPR-g-SA - succinic anhydride grafted ethylene propylene rubber... 

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