Imides, alkylation amides

Treatment with sodium hypochlorite or hypobromite converts primary amines into N-halo- or N,N-dihaloamines. Secondary amines can be converted to N-halo secondary amines. Similar reactions can be carried out on unsubstituted and N-substituted amides and on sulfonamides. With unsubstituted amides the N-halo-gen product is seldom isolated but usually rearranges (see 18-13) however, N-halo-N-alkyl amides and N-halo imides are quite stable. The important reagent NBS is made in this manner. N-Halogenation has also been accomplished with other reagents, (e.g., sodium bromite NaBr02) benzyltrimethylammonium tribromide (PhCH2NMe3 Br3"), and NCS. The mechanisms of these reactions involve attack by a positive halogen and are probably similar to those of 12-47 and 12-49.N-Fluorination can be accomplished by direct treatment of amines °° or... 

N-Alkyl amides or imides can also be prepared starting from alcohols by treatment of the latter with equimolar amounts of the amide or imide, Ph3P, and diethyl azodicarboxylate (EtOOCN=NCOOEt) at room temperature (the Mitsunobu reaction, see p. 396).925... 

The addition of phenyldimethylsilane to the double bond of enamides (or vinyl ureas) in the presence of catalytic amounts of rhodium acetate, leads to Ma-silyl)alkyl amides (or ureas). Rhodium catalyst are known to move double bonds, and indeed the same type of RSMA are obtained from an /V-ally I urea, albeit in low yield. On the other hand, hydrosilylation of A-allyl imides takes place at the terminal carbon atom in high yields.211... 

In order to attempt to address the issues of oral bioavailability and compound stability a number of synthetic analogues of the natural products were generated. It was found that long chain alkyl amides of the 5 5 bicycle system possessed comparable activity to their natural imide analogues. (Table 3, Activity of synthetic analogues). Whilst these compounds were more stable to pH extremes than the natural compounds, however, their solubility was lower, and they showed no oral bioavailability. 

The photolytic cleavage of alkyl aryl sulfoxides has been shown to occur via initial C—S bond homolysis, in accordance with the common mechanistic assumption. Secondary and tertiary alkyl groups show high chemoselectivity for alkyl C—S cleavage. Uniquely, alkene products have been isolated, formed by disproportionation of the initial alkyl radical, with the formation of benzaldehyde and racemization of primary alkyl compounds. An investigation into the photochemical conversion of N-propylsulfobenzoic imides into amides in various solvents revealed a solvent dependence of the observed mechanism. In ethanol, sulfur dioxide extension forms a biradical which abstracts a hydrogen atom from the solvent, whereas in aromatic solvents biradical formation by a single electron transfer is implicated. The photolysis and thermolysis of l,9-bis(alkylthio)dibenzothiophenes and /7-aminophenyl disulfide have been studied. 

RUO4 in oxidative cleavage of phenols or alkenes, oxidation of aromatics to quinones, oxidation of alkyl amides to imides or of ethers to esters (see 1st edition). 

Turner29 has recorded the absorption spectra of cyclic imides and amides in the 175-200 m/x region. The effect of progressive Ca-alkyl substitution on the intensity has been studied. The shift of the absorption band to a longer wavelength in glutarimide has been ascribed to steric strain. 

This reaction was first reported by Wheeler and Johnson in 1899 and was explored extensively by Lander starting in 1900. It is a thermal conversion of alkyl imidates (also known as imino ethers ) into A -alkyl amides in the presence of an alkylting agent. Therefore, it is generally referred to as the Lander rearrangement." ... 

A polyamide-imide (PAI) features alternating imide and amide substructure sequences, an example being a pyromellitimide and amide, with a general structure as indicated below, where A1 is an alkyl group. The IR spectrum of a polyamide-imide is similar to that of a polyimide, except that amide grouping provides an additional carbonyl stretching vibration at around 1670 cm ... 

Tetrahydropyranylation of Amides. Aromatic amides, alkyl amides, ureas, sulfonamides, and imides undergo reaction with dihydropyran-f/ydrogen Chloride (benzene, reflux, 2 h, 22-73%), yielding the expected adducts. ... 

The reaction is applicable to the preparation of amines from amides of aliphatic aromatic, aryl-aliphatic and heterocyclic acids. A further example is given in Section IV,170 in connexion with the preparation of anthranilic acid from phthal-imide. It may be mentioned that for aliphatic monoamides containing more than eight carbon atoms aqueous alkaline hypohalite gives poor yields of the amines. Good results are obtained by treatment of the amide (C > 8) in methanol with sodium methoxide and bromine, followed by hydrolysis of the resulting N-alkyl methyl carbamate ... 

Another variation of the Madelung synthesis involves use of an O-alkyl or O-silyl imidate as the C2 electrophile. The mechanistic advantage of this modification stems from avoiding competing N-deprotonation, which presumably reduces the electrophilicity of the amide group under the classical conditions. Examples of this approach to date appear to have been limited to reactants with a EW substituent at the o-alkyl group[15,16]. 

The imide proton N-3—H is more acidic than N-1—H and hence this position is more reactive toward electrophiles in a basic medium. Thus hydantoins can be selectively monoalkylated at N-3 by treatment with alkyl haUdes in the presence of alkoxides (2,4). The mono-A/-substituted derivatives (5) can be alkylated at N-1 under harsher conditions, involving the use of sodium hydride in dimethylform amide (35) to yield derivatives (6). Preparation of N-1 monoalkylated derivatives requires previous protection of the imide nitrogen as an aminomethyl derivative (36). Hydantoins with an increased acidity at N-1—H, such as 5-arylmethylene derivatives, can be easily monoalkylated at N-3, but dialkylation is also possible under mild conditions. 

Another alternative for preparing a primary amine from an alkyl halide is the Gabriel amine synthesis, which uses a phthalimide alkylation. An imide (—CONHCO—) is similar to a /3-keto ester in that the acidic N-H hydrogen is flanked by two carbonyl groups. Thus, imides are deprotonated by such bases as KOH, and the resultant anions are readily alkylated in a reaction similar to the acetoacetic ester synthesis (Section 22.7). Basic hydrolysis of the N-alkylated imide then yields a primary amine product. The imide hydrolysis step is analogous to the hydrolysis of an amide (Section 21.7). 

While there is clear evidence for complex formation between certain electron donor and electron acceptor monomers, the evidence for participation of such complexes in copolymerization is often less compelling. One of the most studied systems is S-.V1 Al I copolymerization/8 75 However, the models have been applied to many copolymerizations of donor-acceptor pairs. Acceptor monomers have substituents such as carboxy, anhydride, ester, amide, imide or nitrile on the double bond. Donor monomers have substituents such as alkyl, vinyl, aryl, ether, sulfide and silane. A partial list of donor and acceptor monomers is provided in Table 7.6.65.-... 

C for 6 h afforded the alkylated imides in 60-84% yields. The last approach was extended to unsaturated carboxylic amides. The diene 0,N-acetal 86 was prepared from the amide 85 in high yields and subsequently treated with azoinitiator V-70 to afford the desired products (Scheme 13). ... 

A useful method to synthesize ten and fourteen-membered ring imides 346 involved an initial condensation of macrocyclic -ketoestes 343 with alkyl or aryl isocyanates and carbodiimides, respectively, in the presence of a base [68]. After a nucleophilic attack of the enolate on the isocyanate C, the resultant amide N anion 344 induced a ring closure by addition to the keto group. Then, the intermediately formed four-membered ring 345 underwent a fragmentation... 

Conventional conversion of amide, lactam, imide, and urea carbonyl groups into enaminones, enamino esters, or enamino nitriles requires prior activation of the carbonyl groups either by alkylation to imino ethers, followed by reaction with activated methylene groups, or by thiation, e.g. with P2S5, to thiocarbonyl groups followed by alkylation (and possibly also oxidation), and, again, subsequent reac-... 

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... 

Some of the N-alkylated narceine amides and imides were tested for antibacterial effectiveness and showed activity of medium potency against Mycobacterium tuberculosis H37 Rv. Their antimycotic activity was also of medium strength. Coccidiostatic screening showed some effectiveness (100). 

---