Lactams, alkylation amines

The usefulness of this reaction for the preparation of heterocycles under mild conditions became apparent in 1978, when chemists from Merck, Sharp Dohme reported the synthesis of bicyclic 3-lactams by intramolecular carbene N-H insertion [1179]. Intramolecular N-alkylation of P-lactams by carbene complexes is one of the best methods for preparation of this important class of antibiotic and many P-lactam derivatives have been prepared using this methodology [1180 -1186] (Table 4.11). Intramolecular N-H insertion can also be used to alkylate amines [1187-1189], y-lactams [1190], and carbamates [1191-1193] (Table 4.11). 

The limitations of this approach can be seen in the reaction of a saturated solution of ammonia in 90% ethanol with ethyl bromide in a 16 1 molar ratio, under which conditions the yield of primary amine was 34.2% (at a 1 1 ratio the yield was 11.3%). Alkyl amines can be one type of substrate that does give reasonable yields of primary amine (provided a large excess of NH3 is used) are a-halo acids, which are converted to amino acids. A-Chloromethyl lactams also react with amines to give good yields to the A-aminomethyl lactam. Primary amines can be prepared from alkyl halides by 10-43, followed by reduction of the azide (19-32), or by the Gabriel synthesis (10-41). 

In 2008, the same authors reported the synthesis of polyfunctionalized Al-alkyl-p-lactams with high stereoselectivity in an efficient manner performing the same reaction with allyl bromide and heteroarylidene Al-alkyl-amines. Interestingly, by modulating the type of alkyl group linked to the nitrogen atom, it is possible to influence the reaction stereoselectivity [164]. 

Fuming sulfuric acid containing 10-60% sulfur trioxide hydrolyzes perfluoro-Af-alkylcyelic amines to perfluoro-Al-alkyl lactams. Mercuric sulfate acts as a Catalyst [JO, 31] (equation 33). The lactams ate highly reactive and can be used to prepare polymenc films and surfactants... 

Lukes studied the reaction of N-methyl lactams with Grignard reagents. With the five- (39-42) and six-membered (43-47) rings, 2,2-dialkylated bases (16, = 1,2) are formed as by-products in addition to the l-methyl-2-alkyl pyrrolines (15, = 1) or l-methyl-2-alkyl piperideines (15, =2). Aromatic Grignard reagents afford only the unsaturated bases, probably because of steric factors (48,49). Separation of enamines and 2,2-dialkylated amines from each other can be easily achieved since the perchlorates of the enamines and the picrates of 2,2-dialkylated bases crystallize readily. Therefore enamines can be isolated as crystalline perchlorates and the 2,2-dialkylated bases as crystalline picrates. Some authors who repeated the reactions isolated only pyrrolines (50,57) or, by contrast, 2,2-dialkylated bases (52). This can be explained by use of unsuitable isolation techniques by the authors. 

Nucleophilic aromatic substitution of the anthranilic acid derivatives, 72, on ortho-bromonitrobenzene affords the diphenyl-amine, 73. The ester is then saponified and the nitro group reduced to the amine (74). Cyclization of the resulting amino acid by heat affords the lactam (75). Alkylation on the amide nitrogen with 2-dimethylaminoethyl chloride by means of sodium amide affords dibenzepine (76). ... 

In vielen Fallen erbringt jedoch die Reaktionsfolge ausgehend von einem Carbonsau-re-amid bzw. Lactam bessere Ausbeuten1 4 allerdings muB in diesem Fall das Acyl-amin bereits die gewiinschten N-Alkyl-Gruppen enthalten. 

Preparation of nefopam starts with the acylation of aminobenzhydrol 1 (obtainable by reduction of the corresponding benzoylbenzamide) with chloroacetyl chloride treatment of the chloroamide (2) with potassium tertiary butoxide results in internal alkylation to give the eight-membered ring (3). Reduction of the lactam function with lithium aluminum hydride gives the amine and, thus, nefopam (4). ... 

The hydroxy lactams are postulated to be intermediates in transformations of enol lactones to ene lactams. This hypothesis was proved by synthesis. For example, treatment of N-methylhydrastine (98) with dilute ammonium hydroxide resulted in hydroxy lactam 148, which by the action of hydrochloric acid underwent dehydration to produce fumaridine (113) (5). Similarily, fumschleicherine (120) in reaction with trifluoroacetic acid gave fumaramine (111) 121). Narceine amide (149) was prepared from (Z)-narceine enol lactone (101) in likewise fashion 100,122) and dehydrated to narceine imide (116). A large number of N-alkylated narceine amides was synthesized from (Z)-narceine enol lactone (101) and primary amines by Czech investigators for... 

Other conversions of hydroxyl-substituted compounds (or their lactam tautomers), their thio analogues, as well as amines are listed in Table 8. These reactions involve 0-, N-, or -alkylations or acylations, O-S exchange reactions, or other analoguous processes. 

Azetidones (p-lactams) are generally obtained in high yield from (3-halopropion-amides (Table 5.18) and the low yield from the reaction of N-phenyl (3-chloropropi-onamide can be reconciled with the isolation of A-phenyl acrylamide in 58% yield [34]. The unwanted elimination reaction can be obviated by conducting the cyclization in a soliddiquid system under high dilution [35, 36]. Azetidones are also formed by a predominant intramolecular cyclization of intermolecular dimerization to yield piperazine-2,5-diones, or intramolecular alkylation to yield aziridones. Aone-pot formation of azetidones in 45-58% yield from the amine and P-bromocarboxylic acid chloride has also been reported [38]. 

Sha et al. (45) reported an intramolecular cycloaddition of an alkyl azide with an enone in an approach to a cephalotaxine analogue (Scheme 9.45). Treatment of the bromide 205 with NaN3 in refluxing methanol enabled the isolation of compounds 213 and 214 in 24 and 63% yields, respectively. The azide intermediate 206 underwent 1,3-dipolar cycloaddition to produce the unstable triazoline 207. On thermolysis of 207 coupled with rearrangement and extrusion of nitrogen, compounds 213 and 214 were formed. The lactam 214 was subsequently converted to the tert-butoxycarbonyl (t-Boc)-protected sprrocyclic amine 215. The exocyclic double bond in compound 215 was cleaved by ozonolysis to give the spirocyclic ketone 216, which was used for the synthesis of the cephalotaxine analogue 217. 

The chiral, nonracemic bicyclic lactams, used as starting materials for stereoselective alkylation reactions, are usually prepared by treating a mixture of the enantiomerically pure vicinal amino alcohol 1 with a 3-acylpropanoic or 4-acylbutanoic acid 2 (R4 = H) under acid catalysis in toluene with azeotropic removal of the resulting water1-17. When formation of the bicyclic aminal is complete, it is isolated as a diastereomeric mixture which is usually easy to purify and provides the major diastereomer 3. An alternative method for preparation of the bicyclic lactam uses the same conditions with a 2-substituted acid (R4 =1= H). This leads to a roughly 50 50 mixture of diastereomers 3 and 4 which can be used directly for the next step2,5,12. 

Samuel Danishefsky of Columbia University has also described (J. Am. Chem. Soc. 2005, 127, 8298) a total synthesis of 1, starting from the pyroglutamate derivative 10. Conjugate addition followed by alkylation established the lactam framework. Intramolecular cyclization of 12 gave 13, establishing the aminated quaternary center. The oxygenated quaternary center was then constructed by phenylselenyl-mediatcd cyclization of 14. The end game of this synthesis used the already-established cyclohexenyl zinc addition, which worked as well with 16 as it had with 7. 

Increased retention of the analytes can also be achieved by addition of various ion-pair reagents in the mobile phase Tetrabutylammonium cations have typically been used as counter ions, at around pH 6.5, to increase retention and improve the selectivity in the analysis of monobasic penicillins (105, 123). Alkyl-sulfonic acids have been also used to improve the separation of -lactams bearing an amine function in their side chain or having a neutral side chain. Heptanesul-fonic acid (80, 103), decanesulfonic acid (87, 93, 106), dodecanesulfonic acid (77, 107-110), or mixtures of octanesulfonic and dodecanesulfonic acids (73, 75, 78, 79) constitute the principal alkylsulfonic acids used in -lactam analysis. In some applications, heptafluorobutyric acid (74, 76) or sodium thiosulfate (90, 112, 115, 116, 121, 122) has also been used as an ion-pairing reagent. 

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