Reduction imine protection

A short synthesis of (-f)-monomorine (1562) by Maruoka and coworkers used the chiral phase-transfer catalyst (R)-1672 to mediate an enantioselective conjugate addition between enone 1673 and the imine-protected glycine ester 1674 (Scheme 213). In a remarkable one-pot reaction, the intermediate adduct 1675 was then treated with Hantzsch ester (diethyl 2,6-dimethyl-l,4-dihydropyridine-3,5-dicarboxylate) in mildly acidic medium, which brought about deprotection of the acetal and imine as well as a double reductive amination in which the dihydropyridine acted as the hydrogen transfer agent. The resulting indolizidine ester (—)-1676 was... 

The synthesis of the E-ring intermediate 20 commences with the methyl ester of enantiomerically pure L-serine hydrochloride (22) (see Scheme 9). The primary amino group of 22 can be alkylated in a straightforward manner by treatment with acetaldehyde, followed by reduction of the intermediate imine with sodium borohydride (see 22 —> 51). The primary hydroxyl and secondary amino groups in 51 are affixed to adjacent carbon atoms. By virtue of this close spatial relationship, it seemed reasonable to expect that the simultaneous protection of these two functions in the form of an oxazolidi-none ring could be achieved. Indeed, treatment of 51 with l,l -car-bonyldiimidazole in refluxing acetonitrile, followed by partial reduction of the methoxycarbonyl function with one equivalent of Dibal-H provides oxazolidinone aldehyde 52. 

TV-aluminum imines are another example of masked inline derivatives of ammonia. They are easily synthesized by partial reduction of nitriles with diisobutylaluminum hydride (D1BAL-H)6. Addition of lithium organic reagents to /V-aluminum iniines 7 derived from O-protected cyanohydrins 6 provides a-amino alcohols 8a and 8b in moderate yields and low to good diastereo-selectivities n 12. 

The reductive amination of ketones can be carried out under hydrogen pressure in the presence of palladium catalysts. However, if enantiopure Q -aminoketones are used, partial racemization of the intermediate a-amino imine can occur, owing to the equilibration with the corresponding enam-ine [102]. Asymmetric hydrogenation of racemic 2-amidocyclohexanones 218 with Raney nickel in ethanol gave a mixture of cis and trans 1,2-diamino cyclohexane derivatives 219 in unequal amounts, presumably because the enamines are intermediates, but with excellent enantioselectivity. The two diastereomers were easily separated and converted to the mono-protected cis- and trans- 1,2-diaminocyclohexanes 220. The receptor 221 has been also synthesized by this route [103] (Scheme 33). 

Enantiopure 3-phenyl-2-cyanoazetidines (S)-238 and (K)-238, which are epimeric at C2, are prepared in high yields from (K)-phenylglycinol. A one-pot sequence, including addition of organohthium or allyhnagne-sium bromide to the cyano group and in situ reduction of the resulting imine with sodium borohydride, allowed for the preparation of 2-(l-aminoalkyl)azetidines, which were then protected as N-Boc derivatives (R,S)-239 and (S,it)-239 [112] (Scheme 36). Complete anti diastereoselectivity (dr more than 95 5 by NMR) was observed in both cases. The same sequence... 

The transformation of the cyano group could also introduce a new chiral center under diastereoselective control (Figure 5.13). Grignard-transimination-reduction sequences have been employed in a synthesis of heterocyclic analogues of ephedrine [81]. The preferential formation of erythro-/3-amino alcohols may be explained by preferential hydride attack on the less-hindered face of the intermediate imine [82], and hydrocyanation of the imine would also appear to proceed via the same type of transition state. In the case of a,/3-unsaturated systems, reduction- transimination-reduction may be followed by protection of the /3-amino alcohol to an oxazolidinone, ozonolysis with oxidative workup, and alkali hydrolysis to give a-hydroxy-/3-amino acids [83]. This method has been successfully employed in the synthesis L-threo-sphingosine [84]. 

The chiral cyanohydrins also lead directly to a-hydroxy acids by hydrolysis (sequence B) [69] and to protected a-hydroxy aldehydes by first hydroxyl group protection, followed by reduction of the nitrile and hydrolysis of the intermediate imine (not shown) (sequence C) [114]... 

It is synthesized by the reaction of 3,4-dimethoxyphenyl-2-amine and l-(4-methoxyphenyl)-3-butanone with a simultaneous reduction of formed imine, giving the product (11.1.30), the methoxyl-protecting groups of which are cleaved by hydrogen bromide, giving dobutamine (11.1.31) [32,33]. 

Trifluoroalanine has also been prepared by reducing trifluoropyruvate imines (ethyl trifluoropyruvate is available commercially it is prepared either from per-fluoropropene oxide or by trifluoromethylation of ethyl or f-butyl oxalate). These imines are obtained by dehydration of the corresponding aminals or by Staudinger reaction. They can also be obtained by palladium-catalyzed carbonylation of trifluoroacetamidoyl iodide, an easily accessible compound (cf. Chapter 3) (Figure 5.4). Reduction of the imines affords protected trifluoroalanines. When the imine is derived from a-phenyl ethyl amine, an intramolecular hydride transfer affords the regioisomer imine, which can further be hydrolyzed into trifluoroalanine. ... 

Difluoroserine is unstable, but some O- and A -protected derivatives of ethyl difluoro-serinate have been prepared. As for trifluoroalanine, a good precursor is ethyl trifluoro-pyruvate. Synthesis is based on the addition of an alcohol on gem-difluoroenamine, resulting from the reductive cleavage of a C—F bond of an imine of ethyl trifluoro-pyruvate (cf. Chapter 2) (Figure 5.10). ... 

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