Lactams, preparation from imides

Samarium(II) iodide also allows the reductive coupling of sulfur-substituted aromatic lactams such as 7-166 with carbonyl compounds to afford a-hydroxyalkylated lactams 7-167 with a high anti-selectivity [74]. The substituted lactams can easily be prepared from imides 7-165. The reaction is initiated by a reductive desulfuration with samarium(ll) iodide to give a radical, which can be intercepted by the added aldehyde to give the desired products 7-167. Ketones can be used as the carbonyl moiety instead of aldehydes, with good - albeit slightly lower - yields. 

As in 10-55 hydrazides and hydroxamic acids can be prepared from carboxylic esters, with hydrazine and hydroxylamine, respectively. Both hydrazine and hydroxylamine react more rapidly than ammonia or primary amines (the alpha effect, p. 445). Imidates, RC(=NH)OR, give amidines, RC(=NH)NH2. Lactones, when treated with ammonia or primary amines, give lactams. Lactams are also produced from y- and 5-amino esters in an internal example of this reaction. 

A series of N-substituted narceine amides (Section III,D,1) was prepared from 101 under the action of primary amines (100). Acid-catalyzed dehydration transformed these amides to corresponding imides (ene lactams) of the ( )-narceine imide (117) type (100). Similar transformations were performed in the hydrastine series (101). JV-Methylhydrastine (98) when treated with dilute ammonium hydroxide gave hydroxy lactam 127, which was dehydrated to (Z)-fumaridine (113) (5). Sodium borohydride was able to reduce the stilbene double bond in 98 to produce saturated lactone 132 (5). 

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... 

In 1995, Boeckman et al. disclosed a highly diastereoselective aldol reaction using the ligand 79 derived from chiral bicyclic lactam28 (Scheme 2.1z). The imide 80, readily prepared from bicyclic lactam 79 and propionyl chloride, was converted to the boron Z-enolate, which was then treated with a representative series of aldehydes at -40° C for 48 hours. The levels of diastereoselectivity observed in reactions of boron enolate derived from 80 are comparable to those... 

For the synthesis of (69), the enol ether (71) from the indanone (70) was carboxylated with COa-n-butyl-Iithium in THF at —70 C to yield (72). The methyl ester (73) was converted into (75) via the maleic anhydride adduct (74), essentially as described in earlier work. Lithium aluminium hydride reduction followed by oxidation with dicyclohexylcarbodi-imide afforded the aldehyde (76). This was condensed with excess (77) to yield a mixture of the diastereomers (78). Oxidation with chromium trioxide-pyridine in methylene dichloride gave (79), which could be converted into the diketone (80) by treatment with excess benzenesulphonylazide. The diketo-lactam (81) was prepared from (80) as described for the synthesis of the analogous intermediate used in the synthesis of napelline. Reduction of (81) with lithium tri-t butoxyaluminohydride gave the desired dihydroxy-lactam (82). Methylation of (82) with methyl iodide-sodium hydride gave (83). Reduction of this lactam to the amine (84) with lithium aluminium hydride, followed by oxidation with potassium permanganate in acetic acid, gave (69). 

Just as a lactam can be opened to give an amino acid, an imide gives a similar reaction. A simple example is the hydrolysis of glutarimide, in this case prepared from furfural in four steps, to 5-amino-4-oxo-pentanoic acid (5-aminolevulinic acid, 2.81). This latter compound showed relatively high herbicidal activity. ... 

Oximes, Amides, Amidoximes, Lactams, Hydroxamic Chlorides, Imide Chlorides, and Dichloroketcmes. The preparation of 1,5-penta-methylenetetrazole from cyclohexanoneoxime and sodium azide in the... 

The exchange reaction of the acid component of vinyl esters with other acids is catalyzed by PdCl2 (eq 43). Thus various vinyl esters are prepared from easily available Vinyl Acetate. As an example, vinyl itaconate is prepared by the reaction of vinyl acetate with itaconic monomethyl ester (eq 44). iV-Vinyllactams and cyclic imides are prepared by the exchange reaction of lactams and imides with vinyl acetate (eq 45). ... 

Pd(OAc)2] in the presence of PPh3 was used as catalyst. The use of vinyl bromides in lactam formation has also been reported.498 Imides were obtained from aryl bromides. The method has further been applied to the synthesis of diazepam and 1,4-benzodiazepines499 and to a-methylene lactams and lactones.S00 501 In connection with the synthesis of natural products, the reaction has been employed in the preparation of hexadehydrohimbane,502 anthramycin503 and berbine derivatives.504 The catalyst was prepared in situ from [Pd(OAc)2] (106) and PPh3 in all cases. The mechanism of lactam formation is analogous to that for amides (Scheme 42). 

Alternatively, diltiazem (30) has been prepared using the Evans auxiliary derivative 31 derived from L-valine (Scheme 23.7).55 After dehydration of the adduct from the condensation of 31 with anisaldehyde through the mesylate, the enol ether was formed with a Z E ratio of 4 1. This imide was then treated with 2-aminothiophenol in the presence of 0.1 equiv. 2-aminothiophenoxide with no change in the isomer ratio. The auxiliary was removed with trimethylaluminum, with concomitant formation of the lactam. After separation by crystallization, the correct diastereoisomer was converted to diltiazem in >99%ee. 

Thionyl chloride is a versatile reagent for transforming secondary amides - and lactams to imidoyl chlorides, e.g. (207 Scheme 28) because only gaseous byinxxlucts are formed. Thionyl chloride can be used in excess. Even from the Ni complexes of N-benzoylthioureas and SCXTb imide chlorides (208) could be prepared. ... 

Spectroscopic evidence of the seven-membered rings has been found in the preparation of polyimides from pyromellitic dianhydride and methylenediphenyl-diisocyanate (MDI) [105]. The reaction is conducted in solution of aprotic solvents, with reagents addition at low temperature and a maximum reaction temperature of about 130 °C. On the other hand, polyimides of very high molecular weight have not been reported by this method. The mechanism is different when the reaction is accelerated by the action of catalysts. Catalytic quantities of water or alcohols facilitate imide formation, and intermediate ureas and carbamates seem to be formed, which then react with anhydrides to yield polyimides [106]. Water as catalyst has been used to exemplify the mechanism of reaction of phthalic anhydride and phenyl isocyanates, with the conclusion that the addition of water, until a molecular equivalent, markedly increases the formation of phthalimide [107] (Scheme 13). The first step is actually the hydrolysis of the isocyanates, and it has been claimed that ureas are present in high concentration during the intermediate steps of the reaction [107]. Other conventional catalysts have been widely used to accelerate this reaction. Thus, tertiary amines, alkali metal alcoholates, metal lactames, and even mercury organic salts have been attempted [108]. 

Quite recently,the anionic homopolymerization of a few substituted p-lactams and the copolymerization of some of the above pairs have been smdied in order to prepare polyamide 3-derived polypeptides displaying biological properties. The solution polymerization or copolymerization, initiated by li amide disubstituted with trrmethylsilyl groups and activated with 4-tert-butylbenzoyl chloride, does not have living character. From that study, some insights emerged into the reactivity of the above p-lactams in terms of their acidities, as well as electrophUidty of the imide end groups. 

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