Amides reduction with

Amide reduction with lithium aluminum hydride, 39, 19 Amine oxide formation, 39, 40 Amine oxide pyrolysis, 39, 41, 42 -Aminoacetanilide, 39, 1 Amino adds, synthesis of, 30, 7 2-Amino-4-anilino-6-(chloro-METHYl) -S-TRIAZINE, 38, 1 -Aminobenzaldehyde, 31, 6 hydrazone, 31, 7 oxime, 31, 7 phenylhydrazone, 31, 7 > -Aminobenzoic add, 36, 95 2-Aminobenzophenone, 32, 8 c-Aminocaproic acid, 32, 13 6-Aminocaproic acid hydrochloride,... 

Specifically, the tetrahedral intermediates B and D are formed in amide reductions with LiAlH4 and DIBAL, respectively. Their decomposition in principle could affect the C—O bond (—> —> —> amine) or the C—N bond (—> —> —> alcohol). There are two factors that provide an advantage for the C—O bond cleavage ... 

Reduction with zinc dust in glacial acetic acid yields deoxymycelia-namide, C22H28O3N2, ferric chloride negative, with infra red spectrum reminiscent of unstrained cyclic amides. Reduction with sodium and methanol in liquid ammonia gives an unsaturated hydrocarbon side chain ("mycelene ) characterized as a 2,6-dimethylocta-2,6-diene. Mycelianamide believed to consist of a cyclic bis-acylhydroxylamino nucleus substituted by the hydrocarbon side chain (12, 13). 

The monomers are prepared by the homologation of N-protected amino acid aldehydes. Boc-protected amino aldehyde was synthesized in solution via Weinreb amide reduction with LiAlH4.Then, using a Wittig reaction, it was transformed into an olefin bearing an ethyl ester group, which was subsequently saponified. 

The synthesis of meconin has been referred to already (p. 201). Cotarnine has been synthesised by Salway from myristicin (I) as a starting-point. This was transformed into jS-3-methoxy-4 5-methylenedioxy-phenylpropionic acid (II), the amide of which was converted by Hofmann s reaction into )S-3-methoxy-4 5-methylenedioxyphenylethylamine, and the phenylacetyl derivative (HI) of this condensed, by heating it in xylene solution with phosphoric oxide, giving rise to the two possible dihydroiso-quinoline derivatives. The first of these substances, 8-methoxy-6 7-methylenedipxy-1-benzyl-3 4-dihydroiioquinoline (IV), on conversion into the methochloride and reduction with tin and hydrochloric acid, gave... 

Grignard and alkyl lithium reagents were found to add to the carbonyl group of a tricyclic vinylogous amide. However, the same compound underwent the usual vinylogous reduction with lithium aluminum hydride (712). Grignard additions to di- and trichloroenamines gave a-chloro- and dichloroketones (713). 

Vinylogous amides undergo reduction with lithium aluminum hydride, by Michael addition of hydride and formation of an enolate, which can resist further reduction. Thus -aminoketones are usually produced (309, 563,564). However, the alternative selective reduction of the carbonyl group has also been claimed (555). 

Lipoic acid exists as a mixture of two structures a closed-ring disulfide form and an open-chain reduced form (Figure 18.33). Oxidation-reduction cycles interconvert these two species. As is the case for biotin, lipoic acid does not often occur free in nature, but rather is covalently attached in amide linkage with lysine residues on enzymes. The enzyme that catalyzes the formation of the lipoamide nk.2Lg c requires ATP and produces lipoamide-enzyme conjugates, AMP, and pyrophosphate as products of the reaction. 

An interesting synthesis of quinolizidines was achieved using a vinylogous variation of the Bischler-Napieralski reaction. Angelastro and coworkers reported that treatment of amide 26 with PPSE (polyphosphoric acid trimethylsilyl ester) followed by reductive... 

Acylation of norephedrine (56) with the acid chloride from benzoylglycolic acid leads to the amide (57), Reduction with lithium aluminum hydride serves both to reduce the amide to the amine and to remove the protecting group by reduction (58), Cyclization by means of sulfuric acid (probably via the benzylic carbonium ion) affords phenmetrazine (59), In a related process, alkylation of ephedrine itself (60) with ethylene oxide gives the diol, 61, (The secondary nature of the amine in 60 eliminates the complication of dialkylation and thus the need to go through the amide.) Cyclization as above affords phendimetra-zine (62), - Both these agents show activity related to the parent acyclic molecule that is, the agents are CNS stimulants... 

Preparation of the aldehyde required for the synthesis of cyclothiazide (182) starts by carbonation of the Grignard reagent obtained from the Diels-Alder adduct (186) from allyl bromide and cyclopentadiene.The resulting acid (187) is then converted to the aldehyde (189) by reduction of the corresponding diethyl amide (188) with a metal hydride. 

The complex thioamide lolrestat (8) is an inhibitor of aldose reductase. This enzyme catalyzes the reduction of glucose to sorbitol. The enzyme is not very active, but in diabetic individuals where blood glucose levels can. spike to quite high levels in tissues where insulin is not required for glucose uptake (nerve, kidney, retina and lens) sorbitol is formed by the action of aldose reductase and contributes to diabetic complications very prominent among which are eye problems (diabetic retinopathy). Tolrestat is intended for oral administration to prevent this. One of its syntheses proceeds by conversion of 6-methoxy-5-(trifluoroniethyl)naphthalene-l-carboxyl-ic acid (6) to its acid chloride followed by carboxamide formation (7) with methyl N-methyl sarcosinate. Reaction of amide 7 with phosphorous pentasulfide produces the methyl ester thioamide which, on treatment with KOH, hydrolyzes to tolrestat (8) 2[. 

Anhydrides are reduced with relative ease. McAlees and McCrindle 20) established the following increasing order of difficulty for various carbonyls acid chlorides > aldehydes, ketones > anhydrides > esters > carboxylic acids > amides. Reduction may proceed by 1,2-addilion of hydrogen or by cleavage of an oxygen-carbonyl bond. If 1,2-addition to the carbonyl occurs, as in the presence of strong protic acids over palladium, 1,1-diesters are formed by acylation 26). 

Conversion of Amides into Amines Reduction Like other carboxylic acid derivatives, amides can be reduced by LiAlH.4. The product of the reduction, however, is an amine rather than an alcohol. The net effect of an amide reduction reaction is thus the conversion of the amide carbonyl group into a methylene group (C=0 —> CTbV This kind of reaction is specific for amides and does not occur with other carboxylic acid derivatives. 

We ve already seen in Sections 20.7 and 21.7 how amines can be prepared by reduction of nitriles and amides with LiAlH4. The two-step sequence of 5 2 displacement with C followed by reduction thus converts an alkyl halide into a primary alkylamine having one more carbon atom. Amide reduction converts carboxylic acids and their derivatives into amines with the same number of carbon atoms. 

In general, reduction of amides to alcohols is difficult. More commonly the amide is reduced to an amine. An exception uses LiH2NBH3 to give the alcohol. Reduction with sodium metal in propanol also gives the alcohol.Acyl imidazoles are also reduced to the corresponding alcohol with NaBH4 in aqueous HC1. °... 

The bisphosphonate - upon reduction with lithiumaluminum hydride in ether at 0°C - produced the amide functionalized primary bisphosphine (1) in good yields [45]. This reaction proceeded to reduce the amide group in 1 to produce the amine functionaUzed primary bisphosphine (2) in <5% yields. The amido bisprimary phosphine 1 is an air stable crystalline solid whereas the amine compound 2 is an oxidatively stable liquid. Separation of 1 and 2 in pure forms was achieved using coliunn chromatography. The amidic bisprimary phosphine 1 was crystallized from chloroform and exhibits remarkable stability not only in the solid state but also in solution as well. The crystal structure of the air stable primary his-phosphine 1 as shown in Fig. 1 is unprecedented to date. 

Amides can also be deacylated by partial reduction. If the reduction proceeds only to the carbinolamine stage, hydrolysis can liberate the deprotected amine. Trichloroac-etamides are readily cleaved by sodium borohydride in alcohols by this mechanism.237 Benzamides, and probably other simple amides, can be removed by careful partial reduction with diisobutylaluminum hydride (see Section 5.3.1.1).238... 

Modifications at the carboxyl group include reduction (with dibor-ane260 or borohydride, after activation with soluble carbodiimide261,262), esterification (with diazomethane,101,223,283,264 or acyl or aryl chlorides224,264), and formation of amide esters.263,265... 

In this series, too, replacement of the N-methyl by a group such as cyclopropylmethyl leads to a compound with reduced abuse potential by virtue of mixed agonist-antagonist action. To accomplish this, reduction of 24 followed by reaction with tertiary butylmagnesium chloride gives the tertiary carbinol 27. The N-methyl group is then removed by the classic von Braun procedure. Thus, reaction with cyanogen bromide leads to the N-cyano derivative (28) hydrolysis affords the secondary amine 29. (One of the more efficient demethylation procedures, such as reaction with ethyl chloroformate would presumably be used today.) Acylation with cyclopropylcarbonyl chloride then leads to the amide 30. Reduction with lithium aluminum hydride (31) followed by demethylation of the phenolic ether affords buprenorphine (32).9... 

Treatment of the amide 210 with diisobutylaluminium hydride (DIBAL-H) produces not only the expected reduction product 211 but also gives a mixture of the pyrrolonaphthyridine 212 and the indoloquinoline 213. Treatment of 212 with 50% acetic acid results in rearrangement to 213 (Equation 54) <1996JOC7882>. 

The pyrroloquinolizine 456 has been prepared by the treatment of amide 455 with POCl3 followed by NaBH4. Quaternization of the quinolizine nitrogen with methyl iodide followed by reduction with sodium in liquid ammonia gives the pyrroloazecine 457 (Scheme 101) <2001AP241>. 

Reduction of amides 159 with LiAlH4 provides tetrahydropyrazines 160 <2004ARK286>. Further reduction of protected 160 (R1 = Cl, Rz = Me, R3 = BOC, X = C, Y = N) with NaCNBH3 furnishes compound 161 as a mixture of isomers in an 8 1 ratio (Scheme 2) <2006BML1207>. 

---