Nitriles anions from

Fusion of an all cyclic ring onto the piperidine so as to form a perhydroisoquinoline is apparently consistent with analgesic activity. Synthesis of this agent, ciprefadol (68), starts with the Michael addition of the anion from cyclohexanone 56 onto acrylonitrile (57). Saponification of the nitrile to the corresponding acid ( ) followed by Curtius rearrangement leads to isocyanate Acid... 

Head-to-head [2+2]photocycloaddition of 1,2-diarylethanediones and 2-aminopropene nitriles (CH2 C(CN)NR2) occurs to yield oxetanes 10 in moderate to good yields. The formation of only one diastereoisomer in each of the cases investigated is rationalized in terms of the most easily accessible and stabilized 1,4-diradical intermediate <95RTC498>. 2,3,4-Trisubstituted oxetanes 11 are obtained in high yield by intramolecular nucleophilic attack of the anion from certain 2-(l-alkoxyethyl)-3-substituted oxiranes <96JOC4466>. 

A more highly substituted pyrrolidone, doxapram, shows activity as a respiratory stimulant. Preparation of this agent involves an interesting rearrangement, which in effect results in a ring exchange reaction. Alkylation of the anion from diphenylacetonitrile with the chloropyrrolidine 14 affords 15. Hydrolysis of the nitrile function leads to the... 

Since alkyllithium compounds and their carbanions have an isoelectronic structure with alkoxides, their reaction behavior with carbenes is expected to be similar to that of alkoxides, showing enhanced reactivity in both C-H insertion and hydride abstraction.35 In this reaction, the hydride abstraction cannot be followed by recombination and, therefore, can be differentiated from the insertion. Indeed, the reaction of alkyllithium compounds 70 or nitrile anions (see Section IV.B) with ethyl(phenylthio)carbenoid, which is generated by the reaction of 1-chloropropyl sulfide 69 with BuLi, takes place at the -position of 70 more or less in a similar manner giving both insertion product 71 and hydride abstraction products 72 and 73, respectively. This again supports a general rule C-H bonds at the vicinal position of a negatively charged atom are activated toward carbene insertion reactions (Scheme 22). 

An explanatory mechanism for the formation of vinyl sulfides is shown in Scheme 24. In route a, (phenylthio)carbene 77 generated from chlorosulfide 75 reacts with the nitrile anion to form (phenylthio)carbanion 79, which then undergoes elimination of cyanide ion to produce vinyl sulfide 76. In route b, 75 reacts first with the nitrile anion 74 to produce P-(phenylthio)nitrile 78 followed by base-catalyzed P-elimination. However, route b is unlikely because 79 cannot be generated from 68 due to a larger pKa value of its ot proton than that of the nitrile. In fact, the reaction of chlorosulfide 75a with lithionitrile 80 gave a different product 81 in 63% yield. 

Decarboxylation of 1,3-dimethylorotic acid in the presence of benzyl bromide yields 6-benzyl-1,3-dimethyluracil and presumably involves a C(6) centered nucleophilic intermediate which could nonetheless have either a carbene or ylide structure. Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometry has been used to explore the gas-phase reactions of methyl nitrate with anions from active methylene compounds anions of aliphatic ketones and nitriles react by the 5n2 mechanism and Fco reactions yielding N02 ions are also observed nitronate ions are formed on reaction with the carbanions derived from toluenes and methylpyridines. 

A disubstituted butyramide, disopyramide, distantly related to some acyclic narcotics interestingly shows good antiarrhythmic activity. Alkylation of the anion from phenylacetonitrile with 2-bromopyridine yields 99. Alkylation of the anion from the latter with N,N-diisopropyl-2-chloroethyl-amine leads to the amine 100. Hydration of the nitrile in sulfuric acid affords disopi/ramide (101). 

A remarkably simple fused indole devoid of the traditional side chains is described as an antidepressant agent. Michael addition of the anion from indole ester 119 to acrylonitrile affords the cyanide 120. Selective reduction of the nitrile leads to the ami noester 121. This is then cyclized to the lactam (122). Reduction of the... 

The presence of the propionamide fragment in the stmcture of the anti-inflammatory agent broperamole (125-1) is reminiscent of the heterocycle-based NSAID propionic acids. The activity of this agent may trace back to the acid that would result on hydrolysis of the amide. Tetrazoles are virtually always prepared by reaction of a nitrile with hydrazoic acid or, more commonly, sodium azide in the presence of acid in a reaction very analogous to a 1,3-dipolar cycloaddition. A more recent (and safer) version of the reaction noted later (see losartan, 77-4) uses tributyltin azide. In the case at hand, reaction of the anion of mefa-bromobenzonitrile (125-1) with sodium azide and an acid affords the tetrazole (125-2). Condensation of the anion from that intermediate with ethyl acrylate leads to the product from Michael addition saponiflcation gives the corresponding carboxylic acid (125-3). This is then converted to the acid chloride reaction with piperidine affords broperamole (125-4) [136]. 

The amide ions are powerful bases and may be used (i) to dehydrohalogenate halo-compounds to alkenes and alkynes, and (ii) to generate reactive anions from terminal acetylenes, and compounds having reactive a-hydrogens (e.g. carbonyl compounds, nitriles, 2-alkylpyridines, etc.) these anions may then be used in a variety of synthetic procedures, e.g. alkylations, reactions with carbonyl components, etc. A further use of the metal amides in liquid ammonia is the formation of other important bases such as sodium triphenylmethide (from sodamide and triphenylmethane). 

Carbanions from hydrocarbons, nitriles, ketones, esters, TV./V-dialkyl acetamides and thioamides, and mono and dianions from (3-dicarbonyl compounds are some of the most common nucleophiles through which a new C-C bond can be formed. This C-C bond formation is also achieved by reaction with aromatic alkoxides. Among the nitrogen nucleophiles known to react are amide ions to form anilines however, the anions from aromatic amines, pyrroles, diazoles and triazoles, react with aromatic substrates to afford C-arylation. 

THF at - 20°. All other anions should be prepared separately, and 2 should be added to 1 at - 20°. By these procedures mono- and disubstituted olefins, vinyl sulfides, vinyl ethers, and allylsilanes are available in 35-80% yield, usually as cis-trans mixtures. Trisubstituted olefins are best prepared by similar routes from a -branched nitrile anions. 

Three examples of nitrile-stabilized enolates have been described by Boche et al. Two of these structures incorporate the anion of phenylacetonitrile. Hie TMEDA-solvated dimer (178) crystallizes out of benzene solution however, the mixed nitrile anion LDA-(TMEDA)2 complex (179) is obtained when excess LDA is present. This latter complex has often been mistaken as a geminal d anion since it frequently gives products that appear to arise from a dianion. The crystal structure of the anion l-cyano-2,2-dimethylcyclopropyllithium (180) consists of an infinite polymer (181) that is solvated by THF. Interestingly, there are C— Li contacts in this structure and the carbanionic carbon remains tetrahedral. 

From a historical perspective, the a-(dialkylamino)nitrile anions were the first acyl anion equivalents to undergo systematic investigation. More recent studies indicate that anions of a-(dialkylamino)nitriles derived from aliphatic, aromatic or heteroaromatic aldehydes intercept an array of electrophiles including alkyl halides, alkyl sulfonates, epoxides, aldehydes, ketones, acyl chlorides, chloroformates, unsaturated ketones, unsaturated esters and unsaturated nitriles. Aminonitriles are readily prepared and their anions are formed with a variety of bases such as sodium methoxide, KOH in alcohol, NaH, LDA, PhLi, sodium amide, 70% NaOH and potassium amide. Regeneration of the carbonyl group can be achieved... 

A useful alternative to the carbonylation route to ketones and trialkylmethanols from alkylboranes is the cyanidation reaction. The nitrile anion [(-) C=N ] is isoelectronic with CO and also reacts with R3B. However, the cyanoborate salts are thermally stable and therefore require an electrophile such as benzoyl chloride or trifluoroacetic anhydride (TFAA) to induce 1,2-migration. 

Wiber found that the reaction between benzonitrile and hydrogen peroxide shows first-order dependence on the concentration of the nitrile, hydrogen peroxide, and hydroxide ion that benzonitrile oxide is not an intermediate that the oxygen introduced into the nitrile comes from hydrogen peroxide and not from water or hydroxide ion and that the effect of substituents on the reaction rate parallels that observed in known nucleophilic attacks on the nitrile carbon atom. These results suggested that the Initiating reaction Is an attack on the nitrile by hydroperoxide anion with formallon of the peroxycarboklmMte aeld (3). I his substance has not... 

The amino nitrile 9 fulfils all these hopes. It is easily made, it can be alkylated to give 10, and the anion from removal of its second proton gives a clean Michael reaction to form 11. Finally, the amino-nitrile functionality is easily hydrolysed at room temperature and neutral pH (unlike so many such compounds see chapter 14) with Cu(II) catalysis to give the ene-dione 4 and hence ds-jasmone 1 by thermodynamically controlled cyclisation in weak base.1 This process of adding a new five-membered ring, not necessarily to give a cyclopentenone, is often called cyclo-pentannelation and there are now many such methods.3... 

The anion from (70.5) attacks the nitrile group and a 4-aminopyridine ring is formed in this example, the product is related to the antibacterial agent nalidixic acid. 5-Phenyl esters are useful in regioselectively directing a Dieckmann condensation of the diesters (70.6) to carbacephems. Dieckmann reactions usually requite heating but the enaminic ester (70.7) undergoes cyclization without external heat. 

Formation of the 2-3 bond is also possible using the anion from an aryl-amino-nitrile adding intramo-lecularly to an unsaturated ketone or ester the nitrile serves to acidify the future C-2-hydrogen and also to bring about aromatisation via final loss of hydrogen cyanide." "... 

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