Amides nitrogen bases

Many protective groups have been developed for the amino group, including carbamates (>NCO,R), used for the protection of ammo acids in peptide and protein syntheses, and amides (>NCOR). used more widely in syntheses of alkaloids and for the protection of the nitrogen bases adenine, cytosine, and guanine in nucleo-... 

The hydrogeh atom bound to the amide nitrogen in 15 is rather acidic and it can be easily removed as a proton in the presence of some competent base. Naturally, such an event would afford a delocalized anion, a nucleophilic species, which could attack the proximal epoxide at position 16 in an intramolecular fashion to give the desired azabicyclo[3.2.1]octanol framework. In the event, when a solution of 15 in benzene is treated with sodium hydride at 100 °C, the processes just outlined do in fact take place and intermediate 14 is obtained after hydrolytic cleavage of the trifluoroacetyl group with potassium hydroxide. The formation of azabi-cyclo[3.2.1]octanol 14 in an overall yield of 43% from enone 16 underscores the efficiency of Overman s route to this heavily functionalized bicycle. 

Amines are ammonia derivatives in which one or more hydrogen atoms have been replaced by an organic radical. Amines are sometimes called nitrogen bases. Basic chemistries include fatty amines (as primary, secondary, tertiary, and polyamines), amine salts, quaternary ammonium compounds, amine oxides, and amides. 

A deviant reaction was observed when the AT-Boc-aziridinecarboxamide 44b was treated with LDA in THF as the base. Under these kinetically controlled conditions an intramolecular reaction of the amide nitrogen with the Boc group takes place leading to the bicyclic product 46 in which the aziridine ring is retained (Scheme 36) [45]. 

N-hydroxylation is not restricted to primary and secondary amines. For example, nitrogen-based functional groups such as amides, amidino, guanidino, hydrazino, etc. that have at least one nitrogen-hydrogen bond are susceptible to N-hydroxylation. 

While anodic amide oxidations have found the most synthetic use to date, the oxidation of nitrogen-containing molecules is not limited to amide substrates. A variety of amine oxidations have been studied, and the Kolbe electrolysis of carboxylic acids has been used to generate nitrogen-based reactive intermediates. Many of these reactions also offer unique synthetic advantages (Sects. 10.2 and 10.3). 

Choquette et al. investigated the possibilities of using a series of substituted sulfamides as possible electrolyte solvents (Table 12). These compounds are polar but viscous liquids at ambient temperature, with viscosities and dielectric constants ranging between 3 and 5 mPa s and 30 and 60, respectively, depending on the alkyl substituents on amide nitrogens. The ion conductivities that could be achieved from the neat solutions of Lilm in these sulfamides are similar to that for BEG, that is, in the vicinity of 10 S cm Like BEG, it should be suitable as a polar cosolvent used in a mixed solvent system, though the less-than-satisfactory anodic stability of the sulfamide family might become a drawback that prevents their application as electrolyte solvents, because usually the polar components in an electrolyte system are responsible for the stabilization of the cathode material surface. As measured on a GC electrode, the oxidative decomposition of these compounds occurs around 4.3—4.6 V when 100 fik cm was used as the cutoff criterion, far below that for cyclic carbonate-based solvents. 

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