Aldehyde derivatives, reduction

Aldehydes and ketones of furazans and furoxans have many properties resembling those of the aryl derivatives. Reduction of the carbonyl compounds with... 

Iridium-catalyzed transfer hydrogenation of aldehyde 73 in the presence of 1,1-dimethylallene promotes tert-prenylation [64] to form the secondary neopentyl alcohol 74. In this process, isopropanol serves as the hydrogen donor, and the isolated iridium complex prepared from [Ir(cod)Cl]2, allyl acetate, m-nitrobenzoic acid, and (S)-SEGPHOS is used as catalyst. Complete levels of catalyst-directed diastereoselectivity are observed. Exposure of neopentyl alcohol 74 to acetic anhydride followed by ozonolysis provides p-acetoxy aldehyde 75. Reductive coupling of aldehyde 75 with allyl acetate under transfer hydrogenation conditions results in the formation of homoallylic alcohol 76. As the stereochemistry of this addition is irrelevant, an achiral iridium complex derived from [Ir(cod)Cl]2, allyl acetate, m-nitrobenzoic acid, and BIPHEP was employed as catalyst (Scheme 5.9). 

Figure 15.15 An aldehyde derivative of pyrene can be used to couple a hydrophilic amino-PEG-carboxylate spacer by reductive amination. The resultant derivative then can be used to coat a carbon nanotube through pyrene ring adsorption and result in a water-soluble derivative containing terminal carboxylates for coupling amine-containing ligands.

In contrast to oxidative dechlorination, the hydrolytic dechlorination of chloramphenicol replaces a Cl-atom with a OH group to yield a (monochlo-ro)hydroxyacetamido intermediate. The latter, like the dichloro analogue, also eliminates HC1, but the product is an aldehyde that is far less reactive than the oxamoyl chloride intermediate. Chloramphenicol-aldehyde undergoes the usual biotransformation of aldehydes, namely reduction to the primary alcohol 11.41 and dehydrogenation to the oxamic acid derivative 11.40 (Fig. 11.7). 

Several derivatives of carboxylic acids yield aldehydes on reduction and are frequently prepared just for this purpose. 

Reduction of alkylated aldehyde-derived SAMP-hydrazones, followed by reductive N —N cleavage of the resulting hydrazines with Raney nickel, furnishes /(-substituted primary amines in good chemical yields and without racemization in 94-99% ee (see Table 5)31. 

Table 3 Preparation of N -Protected Amino Aldehydes by Reduction of Ester and Amide Derivatives n o...

Scheme 7 Preparation of an a-Amino Aldehyde by Reduction of the Corresponding 3,5-Dimethylpyrazole Derivatives 251...

Preparation of a N -Protected a-Amino Aldehyde via Reduction of the Corresponding N -Protected a-Amino Add 3,5-Dimethylpyrazole Derivative General Procedure 25 ... 

Perhaps the most useful part of the reported synthesis is the facile preparation of (—)-pyrimidoblamic acid (12 Scheme 3). A key to this synthesis is the preparation of the fully substituted pyrimidine 8. This was done by a one-pot inverse electron demand Diels-Alder reaction between the symmetrical triazine 7 and prop-1-ene-1,1-diamine hydrochloride, followed by loss of ammonia, tautomerization, and loss of ethyl cyanoformate through a retro-Diels-Alder reaction. Selective low-temperature reduction of the more electrophilic C2 ester using sodium borohydride afforded 9, the aldehyde derivative of which was condensed with 7V -Boc-protected (3-aminoalaninamide to give the imine 10. Addition of the optically active A-acyloxazolidinone as its stannous Z-enolate provided almost exclusively the desired anti-addition product 11, which was converted into (—)-pyrimidoblamic acid (12). Importantly, this synthesis confirmed Umezawa s assignment of absolute configuration at the benzylic center. 

Aldehyde groups can be converted into terminal amines by a reductive amination process with ammonia or a diamine compound. The reaction proceeds by initial formation of a Schiff base interaction—a dehydration step yielding an imine derivative. Reduction of the Schiff base with sodium cyanoborohydride or sodium bor-ohydride produces the primary amine (in the case of ammonia) or a secondary amine derivative terminating in a primary amine (for a diamine compound) (Fig. 88). 

Quinazolines are of great interest in the pharmaceutical industry as protein tyrosine kinase inhibitors. Dener et al 8 described a synthesis starting from 2-methoxybenzaldehyde, Wang, or Rink resins. With the aldehyde resin reductive aminations were undertaken to yield polymer-bound secondary amines (Fig. 7). The latter were subjected to 2,4-dichloro-6,7-dimethoxyquinazoline to give the 4-amino-substituted derivatives. These were then allowed to react with primary or secondary amines at 135-140° in the presence of DBU in DMA. As a result of a detailed scope and limitation study, Dener et al,28 note that some bifunctional amines, such as piperazine, give to some extent dimeric derivatives. 

J. S. Cha, Recent Developments in the Synthesis of Aldehydes by Reduction of Carboxylic Acids and their Derivatives with Metal Hydrides, Org. Prep. Proced. Int. 1989, 21, 451- 477. 

Acid chlorides are more reactive than other acid derivatives, and they are reduced to aldehydes by mild reducing agents such as lithium tri-ferf-butoxyaluminum hydride. Diisobutylaluminum hydride (DIBAL-H) reduces esters to aldehydes at low temperatures, and it also reduces nitriles to aldehydes. These reductions were covered in Sections 18-9,18-10, and 20-13. 

For the asymmetric reduction of ketone and aldehyde derivates, two electrochemical reduction systems using ADH as catalyst were examined (Fig. 22) [108]. In system A, the reduced coenzymes are regenerated using either FNR for NADPH or DP for NADH. Methyl viologen serves as electron mediator between the electrode and FNR/DP. System B contains ADH as sole enzyme, which catalyzes both reduction of substrates and regeneration of cofactors. Phenylethanol is oxidized by ADH accompanied by reduction of NADP+ to NADPH and its oxidation product acetophenone is reduced electrochemically at a glassy carbon cathode. 

This modification resulted in a yield improvement for the pentacyclization process from 47 % to 66 %. Treatment of the amino ether 192 with diisobutylaluminum hydride in refluxing toluene accomplished Eschenmoser-Grob fragmentation and reduction of the initially formed immonium ion, to give the unsaturated amino alcohol 193 in 86% yield. It was gratifying to find that 193 was the only product formed in this reaction. In the tetrahydropyran derivative, reduction of 192 to 193 is accompanied by about 15 % simple elimination. Displacement of the tosyl group in 196 gives sulfide 197, which is oxidized to sulfone 198. This material is metallated and coupled with enantiomerically pure aldehyde to secure the codaphniphylline skelton [74]. 

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