Benzaldehyde reductive amination

Further substitution of benzoic acid leads to a drug with antiemetic activity. Alkylation of the sodium salt of p-hydroxy-benzaldehyde (8) with 2-dimethylaminoethyl chloride affords the so-called basic ether (9). Reductive amination of the aldehyde in the presence of ammonia gives diamine, 10. Acylation of that product with 3,4,5-trimethoxybenzoyl chloride affords trimetho-benzamide (11). ... 

One problem with reductive amination as a method of amine synthesis is that by-products are sometimes obtained. For example, reductive amination of benzaldehyde with methylamine leads to a mixture of iV-methylbenzylamine and i -methyldibenzylarnine. How do you suppose the tertiary amine byproduct is formed Propose a mechanism. 

A one-pot synthesis of thiohydantoins has been developed using microwave heating [72]. A small subset of p-substituted benzaldehydes, prepared in situ from p-bromobenzaldehyde by microwave-assisted Suzuki or Negishi reactions, was reacted in one pot by reductive amination followed by cyclization with a thioisocyanate catalyzed by polystyrene-bound dimethyl-aminopyridine (PS-DMAP) or triethylamine, all carried out under microwave irradiation, to give the thiohydantoin products in up to 68% isolated yield (Scheme 16). 

Formation of PAC from benzaldehyde and pyruvate catalysed by PDC and reductive amination of if-PAC to produce the chiral biopharmaceutical product ephedrine. 

Besides direct reduction, a one-pot reductive amination of aldehydes and ketones with a-picoline-borane in methanol, in water, and in neat conditions gives the corresponding amine products (Scheme 8.2).40 The synthesis of primary amines can be performed via the reductive amination of the corresponding carbonyl compounds with aqueous ammonia with soluble Rh-catalyst (Eq. 8.17).41 Up to an 86% yield and a 97% selectivity for benzylamines were obtained for the reaction of various benzaldehydes. The use of a bimetallic catalyst based on Rh/Ir is preferable for aliphatic aldehydes. 

The first example of this type of transformation was reported in 1974 [76]. Three catalysts were investigated, namely [Co2(CO)8], [Co(CO)g/PBu ], and [Rh6(CO)i6]. The [Co OJg/PBu ] catalyst showed activity for reductive animation using ammonia and aromatic amines. The [Rh6(CO)16] catalyst could be used for reductive animation using the more basic aliphatic amines that were found to poison the cobalt catalyst. This early report pointed out that the successful reductive animation of iso-butanal (Me2CCHO) with piperidine involves selective enamine hydrogenation, that reductive animation of cyclohexanone with isopropylamine probably involves imine hydrogenation, and that reductive amination of benzaldehyde with piperidine would presumably involve the reduction of a carbinolamine. 

The two main resin linkers developed so far are shown in Scheme 18, i.e. tris(alk-oxy)benzylamide- 412 and 4-alkoxybenzylamide-type linkers)341 the former being TFA labile and thus fully compatible with Fmoc/tBu and the latter strongly acid labile and correspondingly compatible with Boc/Bzl chemistry. As shown in the case of the tris(alk-oxy)benzaldehyde handle such handles may be introduced into the C-terminal amino acid ester by reductive amination, and after suitable N -protection coupled to amino-functionalized resins (see Scheme 18). Alternatively, the tris(alkoxy)benzaldehyde-functionalized resin, BAL resin, (see Scheme 14) is used to link the C-terminal amino acid ester by reductive amination. To overcome the difficult acylation of the V -arylamino acid ester derivative on resin (best results with 10 equivalent symmetrical anhydrides), synthesis in solution of the C-terminal dipeptide building block containing the amide handle followed by its attachment to the resin has been proposed)341 ... 

Reductive amination of benzaldehyde with (R)-81 provided the corresponding benzyl amine, which was reductively alkylated with formaldehyde to give 82 (Scheme H) " Compound 82 was debenzylated by hydrogenation in the presence of Pearlman s catalyst to afford frovatriptan ((/J)-6). Alternatively, monomethylation of amine (/ )-81 was affected by treatment with carbon disulfide and dicyclohexylcarbodiimide in pyridine to provide isothiocyanate 83, which was reduced with sodium borohydride to give (l )-6. 

As illustrated by the examples in Table 3.9, resin-bound 4-alkoxybenzylamides often require higher concentrations of TFA and longer reaction times than carboxylic acids esterified to Wang resin. For this reason, the more acid-sensitive di- or (trialkoxy-benzyl)amines [208] are generally preferred as backbone amide linkers. The required resin-bound, secondary benzylamines can readily be prepared by reductive amination of resin-bound benzaldehydes (Section 10.1.4 and Figure 3.17 [209]) or by A-alkyla-tion of primary amines with resin-bound benzyl halides or sulfonates (Section 10.1.1.1). Sufficiently acidic amides can also be A-alkylated by resin-bound benzyl alcohols under Mitsunobu conditions (see, e.g., [210] attachment to Sasrin of Fmoc cycloserine, an O-alkyl hydroxamic acid). 

Scheme 2 shows Rapoport s synthesis [15]. The cinnamic acid derivative 3 prepared from m-methoxy benzaldehyde [20] was ethylated by diethyl sulfate to give ethyl cinnamate derivative 4, followed by Michael addition with ethyl cyanoacetate to afford compound 5. Compound 5 was converted to lactam 6 by the reduction of the cyano group and subsequent cyclization. Selective reduction of the lactam moiety of 6 was achieved by treatment with trimethy-loxonium fluorob orate followed by sodium borohydride reduction. Amine 8 was obtained by the reductive methylation of amine 7. Amine 8 was converted to compound 9 by methylene lactam rearrangement [21], followed by selenium dioxide oxidation to provide compound 10. Allylic rearrangement of compound 10 and subsequent hydrolysis gave compound 12. The construction of the decahydroisoquinoline structure began with compound 12,... 

More recently, Bradley has demonstrated the chemoselective capture of primary amines over secondary amines using a polymeric methacrylate (AAEM) 13 as a purification method for an in-situ reductive amination procedure (Scheme 5) [13]. Reduction of the imines 17a-c (formed by addition of benzaldehyde 15 to an excess of the primary amines 16a-c) gave the required secondary amines 18a-c. The remaining unwanted primary amines 16a-c was chemoselectively removed by the addition of the scavenger resin, acetoacetoxy ethyl methacrylate (AAEM) 13 to give the enamines 19a-c. Simple filtration of the reaction mixture gave the required secondary amine in good yield and excellent purity. Previously, within this area benzaldehyde-based resins (like 14) have been used, but were problematic, as they were particularly air sensitive. 

Scheme 16 shows parallel syntheses of cyclic and acyclic amide compounds. Fluorous benzaldehydes were first subjected to reductive amination reactions. The resulting amines were then reacted with isocyanates to form substituted hydantoin rings 14 or with benzoyl chlorides to form amides 15. Purified F-sulfonates were used for palladium-catalyzed cross-coupling reactions to form corresponding biaryl 16 [31] and arylsulfide 17 [32] products, respectively. 

The synthesis of BENZYL ISOCYANIDE from benzaldehyde via reductive amination with 5-aminotetrazole followed by oxidation of the resultant amine with sodium hypobromite provides a general method for the synthesis of isocyanides. The preparation of BIS(2,2,2-TRICHLOROETHYL) AZODICARBOXYLATE makes available an alternative to dimethyl azodicarboxylate that is not only more reactive in Diels-Alder reactions but whose ester groups can be removed under neutral conditions. 

L-Phe can be prepared via the enantioselective hydrolysis of N-acetyl-D,L-Phe and microbial reductive amination of phenylpyruvate (see Fig. 8.14) [87]. The stoichiometric yields of these processes were high but the precursors required 3-4 synthetic steps from the basic starting materials in most cases. The phenyl-ammonia lyase route, in contrast [89], provided L-Phe in only two steps from the basic chemicals benzaldehyde and acetic anhydride [90]. The enzymatic step... 

Benzaldehyde first reacts with methylamine and NaBHsCN in the usual way to give the reductive amination product /V-methylbenzylamine. This product then reacts further with benzaldehyde in a second reductive amination to give Af-methyldibenzylamine. 

The procedure has been shown applicable to the reductive amination of cyclohepta-none, cyclooctanone, acetophenone, norhomanonc, and benzaldehyde. Amines used include ammonia, methylamine, dimethylamine, morpholine, aniline, and hydroxyl-... 

Lemmtyinen and coworkers <01JPP835> have devised a protocol, in which the phytochlorin 37 containing a formyl group was transformed into glycine derivative 50 via reductive amination (Scheme 15). In the final step, derivative 50 was reacted with benzaldehyde and C o, and gave rise to the phytochlorin-C6o diad 51. 

Now a difficulty emerged. They wanted to carry out the resolution on a large scale but enantio-merically pure 6 is expensive. The solution was to make it themselves from previously resolved cheap 2. The obvious route is reductive amination using benzaldehyde and the only danger is racemisation of the intermediate imine 7. They found that the imine 7 did not racemise as it was prepared in toluene but that some racemisation took place when NaB(CN)H3 was used for the reduction. The solution was to use catalytic hydrogenation and they prepared 53 kg batches of optically pure 7 in 98% yield by this method and used that to resolve the hydroxy acid 5. 

PROBLEM 22.12 Show how you could prepare each of the following amines from benzaldehyde by reductive amination ... 

Intermediate (5)-l is simply yV-benzyl-4-fluorophenylglycine that has been capped with an ethylene unit. The original synthesis in which 4-fluorophenylacetic acid was transformed to the corresponding chiral oxazolidinone 6 is depicted in Scheme 2. Masked a-azido acid 7 was formed diastereoselectively from this intermediate. Hydrolysis and azide reduction afforded enantiomerically pure (5)-4-fluorophenyl glycine (8). Reductive amination with benzaldehyde introduced the V-benzyl unit and subsequent A, 0-dialkylation with ethylene dibromide provided chiral oxazinone 1. 

This is a reductive amination reaction. First one equivalent of ammonia reacts with one equivalent of benzaldehyde to form an imine which in turn is reduced to a primary amine. The primary amine then reacts with another equivalent of benzaldehyde to form another imine. This imine is then reduced to a secondary amine. 

In order to test for catalytic activity, the reductive amination of benzaldehyde 13 by n-propylamine 12 was chosen as a model reaction [52]. 

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