4- benzonitrile synthesis

Aryl, heteroaryl, and alkenyl cyanides are prepared by the reaction of halides[656-658] or triflates[659,660] with KCN or LiCN in DMF, HMPA, and THF. Addition of crown ethers[661] and alumina[662] promotes efficient aryl and alkenyl cyanation. lodobenzene is converted into benzonitrile (794) by the reaction of trimethylsiiyl cyanide in EtiN as a solvent. No reaction takes place with aryl bromides and chlorides[663]. The reaction was employed in an estradiol synthesis. The 3-hydroxy group in 796 was derived from the iodide 795 by converting it into a cyano group[664]. 

An unusual final example of a synthesis from pyridines involves the 4-lithiotetra-chloropyridine (128), which with two moles of benzonitrile gave the trichlorodiphenyl-pyrido[3,4- f]pyrimidine (130) via the intermediate (129) (72JCS(P1)2190). The 2-lithio analogue gave the corresponding [3,2-c] derivative. 

Because of resonance stabilization of the anion, a tet-nazolyl moiety is often employed successfully as a bioisosteric replacement for a carboxy group. An example in this subclass is provided by azosemide (27). Benzonitrile analogue is prepared by phosphorus oxychloride dehydration of the corresponding benzamide. Next, a nucleophilic aromatic displacement reaction of the fluorine atom leads to The synthesis concludes with the 1,3-dipolar addition of azide to the nitrile liinction to produce the diuretic azosemi de (27). ... 

The reaction between benzylidenetriphenylphosphorane and benzonitrile has been reinvestigated and the primary product (82) isolated. Stable ylides react similarly with activated nitriles, e.g. cyanogen and trifluoro-acetonitrile, but cyanomethylenetriphenylphosphorane with methyl cyano-formate gave largely the vinyl ether (83), the product of a normal olefin synthesis on the carbonyl of the ester group. 

The ITIES with an adsorbed monolayer of surfactant has been studied as a model system of the interface between microphases in a bicontinuous microemulsion [39]. This latter system has important applications in electrochemical synthesis and catalysis [88-92]. Quantitative measurements of the kinetics of electrochemical processes in microemulsions are difficult to perform directly, due to uncertainties in the area over which the organic and aqueous reactants contact. The SECM feedback mode allowed the rate of catalytic reduction of tra 5-l,2-dibromocyclohexane in benzonitrile by the Co(I) form of vitamin B12, generated electrochemically in an aqueous phase to be measured as a function of interfacial potential drop and adsorbed surfactants [39]. It was found that the reaction at the ITIES could not be interpreted as a simple second-order process. In the absence of surfactant at the ITIES the overall rate of the interfacial reaction was virtually independent of the potential drop across the interface and a similar rate constant was obtained when a cationic surfactant (didodecyldimethylammonium bromide) was adsorbed at the ITIES. In contrast a threefold decrease in the rate constant was observed when an anionic surfactant (dihexadecyl phosphate) was used. 

In considering an appropriate starting material for the synthesis of taranabant the commercial availability of a number of 3-substituted benzonitriles was evaluated, however, with the exception of the previously employed 3-bromobenzonitrile, cost effective options from recognized large-scale suppliers were limited (Figure 9.2). 

N-donor ligand. The reaction appears to proceed via an acyclic iminoplatinum(II) intermediate that undergoes a subsequent intramolecular cyclization. Some mechanistic aspects of this versatile reaction have been elucidated.225,226 A4-l,2,4-oxadiazolines have been prepared by the [2+3] cycloaddition of various nitrones to coordinated benzonitrile in m-[PtCl2( D M SO)(PhCN)] precursors.227,228 Racemic and chiral [PtCl2(PhMeSO)(PhCN)] complexes have also been used in order to introduce a degree of stereoselectivity into the reaction, resulting in the first enantioselective synthesis of A4-l,2,4-oxadiazolines, which can be liberated from the complexes by the addition of excess ethane-1,2-diamine. 

The synthesis of phthalimidines by dicobalt octacarbonyl-catalyzed carbonylation of Schiff bases was first described by Pritchard78 and the scope of the reaction was evaluated by Murahashi et a/.79 Later Rosenthal et al.80-83 subjected a variety of related compounds to carbonylation, and also achieved a phthalimidine synthesis directly from benzonitrile under the conditions of the oxo process.84 An example illustrating the formation of a phthalimidine is shown in Scheme 49 a comprehensive review of the scope and mechanism of reactions of this type is available.85... 

Hynninen and coworkers <99JCS(PT1)2403> used a similar approach to prepare phytochlorin-C6o diad 38 (Scheme 11). The protocol employed the pyrolysis of the natural chlorophyll a molecule 35, followed by transesterification and demetallation to furnish derivative 36. Subsequent oxidation of 36 with OsCU and NaI04 has allowed the synthesis of the formyl derivative 37, which was further used as precursor of the azomethinic ylide intermediate in the 1,3-DC reaction with Cm leading to the formation of diad 38. Photochemical studies revealed that this diad underwent a fast intramolecular photoinduced electron transfer in polar solvents such a benzonitrile <99JACS9378>. 

Two unique type Had syntheses of pyrroles that were reported both involved cyclopropane fragmentations. The first allowed for a synthesis of 2-arylpyrroles <06SL2339>. In the event, treatment of stannylcyclopropane 25 with -BuLi followed by benzonitrile produced 2-phenylpyrrole 26 via tin-lithium exchange, addition to the nitrile, ring fragmentation of ketimine intermediate, intramolecular condensation, and loss of dibenzylamine. 

Kobayashi and co-workers have also reported an alternate synthesis of 1,4-disubstituted isoquinolines and a new synthesis of 1,3,4-dihydroisoquinoline derivatives <06BCJ 1126 06S2934>. The 1,4-disubstituted isoquinolines 121 are synthesized in good yields by reacting a variety of organolithiums 122 with different benzonitriles 123. In addition, a variety of lithium dialkylamides 124 were also reacted with different benzonitriles 123 to form 1 -amino-4-substituted isoquinolines 121 in moderate yields. 

A process research investigation on p38 MAP kinase inhibitors examined the synthesis (on 7 mol scale) of a group of closely related pyrimidinones such as 37, by condensation of a number of arylacetic esters with 4-cyanopyridine and methyl isothiocyanate. Other nitriles were also examined but were much less successful than 4-cyanopyridine 3-cyanopyridine gave a much lower yield and both benzonitrile and 2-cyanopyridine failed completely <06T11714>. 

For more than a century, stoichiometric methods were presumed in the preparation of benzonitriles in laboratory and industry. These particularly include the Rosenmund-von Braun reaction of aryl halides, the diazotization of anilines and subsequent Sandmeyer reaction, and the ammoxidation. Because of (over)stoichiometric amounts of metal waste, lack of functional group tolerance, and harsh reaction conditions, these methods do not meet the criteria of modern sustainable synthesis. 

The Pd-catalyzed reaction of simple arenes and nitriles provides a useful synthesis of aromatic ketones.120 The reaction of toluene and benzonitrile in the presence of Pd(OAc)2 as a catalyst in DMSO and TFA gives diarylketones (Equation (92)). The presence of DMSO is essential in this reaction. 

Synthesis of the oxadiazolopyrimidone 358 was accomplished by reaction of the amide 357 with phosphorus pentoxide and methylsulfonic acid in low yield <1994PHA880>. Also, its benzologue 360 could only be obtained in very modest yield <2004TL8741> in the case, reaction of the benzonitrile derivative 359 with acetylhydrazine resulted in formation of the bicyclic product 360. 

N-Sulfinylaniline, the procedure for the preparation of which is described in Part A, is a versatile intermediate in the synthesis of heterocyclic compounds. Benzohydroxamoyl chloride, the method for the preparation of which is given in Part B, is the precursor of the highly reactive benzonitrile oxide, the diverse dipolar addition reactions of which have been thoroughly investigated. A wide array of heterocyclic compounds can be prepared starting with benzonitrile oxide. ... 

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