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Amines hydrogenolysis

Single-bond cleavage with molecular hydrogen is termed hydrogenolysis. Palladium is the best catalyst for this purpose, platinum is not useful. Desulfurizations are most efficiently per-formed with Raney nickel (with or without hydrogen G.R. Pettit, 1962 A or with alkali metals in liquid ammonia or amines. The scheme below summarizes some classes of compounds most susceptible to hydrogenolysis. [Pg.113]

In addition to the preparation of l-alkenes, the hydrogenolysis of allylic compounds with formate is used for the protection and deprotection of carboxylic acids, alcohols, and amines as allyl derivatives (see Section 2.9). [Pg.368]

Allylic amines can be cleaved. Hydrogenolysis of allylic amines of different stereochemistry with NaBH CN was applied to the preparation of both dia-stereoisomers 655 and 657 of cyclopentenylglycine from the cyclic amines 654 and 656 of different stereochemistry[405]. [Pg.379]

Amines of the formula n 2n+ be prepared by the lithium aluminum hydride reduction of the corresponding amide, hydrogenolysis... [Pg.311]

Unusual reducing properties can be obtained with borohydride derivatives formed in situ. A variety of reductions have been reported, including hydrogenolysis of carbonyls and alkylation of amines with sodium borohydride in carboxyHc acids such as acetic and trifluoroacetic (38), in which the acyloxyborohydride is the reducing agent. [Pg.304]

The hydrogenolysis of hydroxamic acids (22) and hydra2ides (23) has also been used to synthesi2e amides. One of the earliest methods for the preparation of amides consists of treating acid chlorides with dry ammonia or an amine (24). [Pg.183]

Alkali moderation of supported precious metal catalysts reduces secondary amine formation and generation of ammonia (18). Ammonia in the reaction medium inhibits Rh, but not Ru precious metal catalyst. More secondary amine results from use of more polar protic solvents, CH OH > C2H5OH > Lithium hydroxide is the most effective alkah promoter (19), reducing secondary amine formation and hydrogenolysis. The general order of catalyst procUvity toward secondary amine formation is Pt > Pd Ru > Rh (20). Rhodium s catalyst support contribution to secondary amine formation decreases ia the order carbon > alumina > barium carbonate > barium sulfate > calcium carbonate. [Pg.209]

Amino Acids. Chloroformates play a most important role for the protection of the amino group of amino acids (qv) during peptide synthesis (32). The protective carbamate formed by the reaction of benzyl chloroformate and amino acid (33) can be cleaved by hydrogenolysis to free the amine after the carboxyl group has reacted further. The selectivity of the amino groups toward chloroformates results in amino-protected amino acids with the other reactive groups unprotected (34,35). Methods for the preparation of protected amino acids on an industrial scale have been developed (36,37). A wide variety of chloroformates have been used that give various carbamates that are stable or cleaved under different conditions. [Pg.39]

Purines, N-alkyl-N-phenyl-synthesis, 5, 576 Purines, alkylthio-hydrolysis, 5, 560 Mannich reaction, 5, 536 Michael addition reactions, 5, 536 Purines, S-alkylthio-hydrolysis, 5, 560 Purines, amino-alkylation, 5, 530, 551 IR spectra, 5, 518 reactions, 5, 551-553 with diazonium ions, 5, 538 reduction, 5, 541 UV spectra, 5, 517 Purines, N-amino-synthesis, 5, 595 Purines, aminohydroxy-hydrogenation, 5, 555 reactions, 5, 555 Purines, aminooxo-reactions, 5, 557 thiation, 5, 557 Purines, bromo-synthesis, 5, 557 Purines, chloro-synthesis, 5, 573 Purines, cyano-reactions, 5, 550 Purines, dialkoxy-rearrangement, 5, 558 Purines, diazoreactions, 5, 96 Purines, dioxo-alkylation, 5, 532 Purines, N-glycosyl-, 5, 536 Purines, halo-N-alkylation, 5, 529 hydrogenolysis, 5, 562 reactions, 5, 561-562, 564 with alkoxides, 5, 563 synthesis, 5, 556 Purines, hydrazino-reactions, 5, 553 Purines, hydroxyamino-reactions, 5, 556 Purines, 8-lithiotrimethylsilyl-nucleosides alkylation, 5, 537 Purines, N-methyl-magnetic circular dichroism, 5, 523 Purines, methylthio-bromination, 5, 559 Purines, nitro-reactions, 5, 550, 551 Purines, oxo-alkylation, 5, 532 amination, 5, 557 dipole moments, 5, 522 H NMR, 5, 512 pJfa, 5, 524 reactions, 5, 556-557 with diazonium ions, 5, 538 reduction, 5, 541 thiation, 5, 557 Purines, oxohydro-IR spectra, 5, 518 Purines, selenoxo-synthesis, 5, 597 Purines, thio-acylation, 5, 559 alkylation, 5, 559 Purines, thioxo-acetylation, 5, 559... [Pg.761]

The first, and still widely used, polymer-supported ester is formed from an amino acid and a chloromethylated copolymer of styrene-divinylbenzene. Originally it was cleaved by basic hydrolysis (2 N NaOH, FtOH, 25°, 1 h). Subsequently, it has been cleaved by hydrogenolysis (H2/Pd-C, DMF, 40°, 60 psi, 24 h, 71% yield), and by HF, which concurrently removes many amine protective groups. Monoesterification of a symmetrical dicarboxylic acid chloride can be effected by reaction with a hydroxymethyl copolymer of styrene-divinylbenzene to give an ester a mono salt of a diacid was converted into a dibenzyl polymer. ... [Pg.260]

Aryl esters, prepared from the phenol and an acid chloride or anhydride in the presence of base, are readily cleaved by saponification. In general, they are more readily cleaved than the related esters of alcohols, thus allowing selective removal of phenolic esters. 9-Fluorenecarboxylates and 9-xanthenecarboxylates are also cleaved by photolysis. To permit selective removal, a number of carbonate esters have been investigated aryl benzyl carbonates can be cleaved by hydrogenolysis aryl 2,2,2-trichloroethyl carbonates by Zn/THF-H20. Esters of electron-deficient phenols are good acylating agents for alcohols and amines. [Pg.276]

H2/Pd-C. If hydrogenation is carried out in the presence of (B0C)20, the released amine is directly converted to the BOC derivative. The formation of A-methylated lysines during the hydrogenolysis of a Z group has been observed with MeOH/DMF as the solvent. Formaldehyde derived oxidatively from methanol is the source of the methyl carbon. ... [Pg.532]

H2, Pd black, EtOH, 45°, 92% yield.If the hydrogenolysis is performed in the presence of (B0C)20 or Fmoc-OSu, the released amine is converted to the BOC and Fmoc derivatives in situ ... [Pg.584]

Heating a primary amine with dibenzylformamide-dimethyl acetal in CH3CN gives the formamidine in 49-99% yield. It is cleaved by hydrogenolysis (Pd(OH)2, MeOH, H2O, H2, 52-99% yield). ... [Pg.588]

Condensation of normeperidine (81) with 3-chloropropan-l-ol affords the compound possessing the alcohol side chain (88). The hydroxyl is then converted to chlorine by means of thionyl chloride (89) displacement of the halogen by aniline yields pimino-dine (90). ° Condensation of the secondary amine, 81, with styrene oxide affords the alcohol, 91 removal of the benzyllic hydroxyl group by hydrogenolysis leads to pheneridlne (92). ... [Pg.301]

The synthesis of a benzamide with a somewhat more complex side chain starts by condensation of acid 144 with racemic cis-aminopiperidine 152. Removal of the benzyl group of 153 by hydrogenolysis gives the secondary amine 154. Alkylation on nitrogen with the halide 155 gives finally the dopamine antagonist, cisapride (156) [38,39]. [Pg.42]

The above equation adequately accounts for the action of ammonia, but it may function in other ways as well, for a variety of bases, such as tertiary amines, carbonates (46), and hydroxides 20,32), also suppress formation of coupled products. Greenfield (28) suggested that bases may function by suppressing the hydrogenolysis reaction leading to secondary and tertiary amines. [Pg.96]

Nickel in the presence of ammonia is often used for reduction of nitriles to primary amines. The reaction is done at elevated temperatures and pressures ( 100 C, 1000 psig) unless massive amounts of nickel are used. Cobalt is used similarly but mainly under even more vigorous conditions. Nitriles containing a benzylamine can be reduced over Raney nickel to an amine without hydrogenolysis of the benzyl group (7). A solution of butoxycarbonyl)-3-aminopropyl]-N-<3-cyanopropyl)benzylamine (13.6 g) in 100 ml of ethanol containing 4 g. NaOH was reduced over 3.0 g Raney nickel at 40 psig for 28 h. The yield of A/ -benzyl-Air -(f-butoxycarbonyl)s >ermidine was 95% (7). [Pg.97]

Tertiary amines are effective promoters in hydrogenolysis of hindered benzyl esters that otherwise may undergo cleavage only with difficulty (187). [Pg.159]

Inhibition of O-benzyl hydrogenolysis was shown to be due to the presence of an amine, a finding with synthetic utility. [Pg.165]


See other pages where Amines hydrogenolysis is mentioned: [Pg.246]    [Pg.113]    [Pg.246]    [Pg.113]    [Pg.163]    [Pg.57]    [Pg.393]    [Pg.395]    [Pg.82]    [Pg.243]    [Pg.81]    [Pg.92]    [Pg.133]    [Pg.153]    [Pg.170]    [Pg.49]    [Pg.164]    [Pg.164]    [Pg.79]    [Pg.510]    [Pg.82]    [Pg.69]    [Pg.420]    [Pg.20]    [Pg.178]    [Pg.11]    [Pg.61]    [Pg.82]    [Pg.94]    [Pg.123]    [Pg.125]    [Pg.168]   
See also in sourсe #XX -- [ Pg.92 , Pg.188 ]

See also in sourсe #XX -- [ Pg.826 ]




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