Amidines oxidative

Gold(I) ylides are oxidized in 0.1 M [Bu4N]BF4/THFat low potentials of +0.11 and + 0.23 V vs. Ag/AgCl (quasi-reversible). The dinuclear amidinate oxidizes under the same conditions at + 1.24 V vs. Ag/AgCl (reversible). These large differences in chemical character of the dinuclear gold(I) complexes appear to explain the widely different behavior of these compounds and especially toward the reaction with mercury cyanide. 

In another cyclization procedure for the 1,5-benzodiazodne system, the nitriles (296) are converted to the aminodihydrodiazocines (297) (79CPB2589). Attack of nucleophiles on (297) occurs at the N-5—C-6 bond to give the 3,4,5,6-tetrahydrodiazodnes (298) with NaBH4 and the jS-aminoethylquinazolines (301) on hydrolysis. The diazocines (297) behave as typical amidines. Oxidation leads to the amidoximes (300) which on hydrolysis are converted to 2,1-benzisoxazoles (302), and reaction with diketene leads to the fused pyrimidinones (299 and l-methyl-3-one isomer) (79CPB2927). 

Trifluoroethanimidamines (amidines) undergo a two-electron electrochemical oxidation leading either to 2-trifluoromethyl benzimidazoles via intramolecular nucleophilic substitution or to p-benzoquinone imine derivatives by external nucleophilic addition depending on the reaction conditions [Eq. (21)] [137]. Another study of the indirect electrochemical amidine oxidation has been published by Lessard [138]. 

Another approach uses the reaction of 6-chloro-5-nitropyrimidines with a-phenyl-substituted amidines followed by base-catalyzed cyclization to pteridine 5-oxides, which can be reduced further by sodium dithionite to the heteroaromatic analogues (equation 97) (79JOC1700). Acylation of 6-amino-5-nitropyrimidines with cyanoacetyl chloride yields 6-(2-cyanoacetamino)-5-nitropyrimidines (276), which can be cyclized by base to 5-hydroxypteridine-6,7-diones (27S) or 6-cyano-7-oxo-7,8-dihydropteridine 5-oxides (277), precursors of pteridine-6,7-diones (278 equation 98) (75CC819). 

Numerous examples of N—S bond formation using oxidative conditions have been described in the literature. A convenient synthesis of isothiazoles involves the direct oxidation of -y-iminothiols and numerous variations have been studied (see Chapter 4.17), The oxidation of the amidine (248) to give the 3-aminoisothiazole (249) illustrates the reaction scheme (65AHC(4)107, 72AHC(14)1), which has been extended to the synthetically useful 5-amino-4-cyano-3-methylisothiazole (251) obtained by oxidation of (250) with hydrogen peroxide (75JHC883). 

One of the best methods of synthesis of isothiazoles is by direct oxidation of y- iminothiols (169) or their tautomers. The reaction is capable of many ramifications and is represented by the general equation shown in Scheme 27. The substituents represent a wide range of groups. Thus, iminothioamides (169 R = NH2) are oxidized to give 3-alkyl-5-aminoisothiazoles (170 = NH2), amidines (169 R = NH2) produce 3-amino compounds,... 

A combination of the preceding type of synthesis and of cyclization of 4-amino-5-arylazopyrimidine can be seen in the novel procedure of Richter and Taylor. Proceeding from phenylazomalonamide-amidine hydrochloride (180), they actually close both rings in this synthesis. The pyrimidine ring (183) is closed by formamide, the triazole (181) one by oxidative cyclization in the presence of cupric sulfate. Both possible sequences of cyclization were used. The synthetic possibilities of this procedure follow from the combination of the two parts. The synthesis was used for 7-substituted 2-phenyl-l,2,3-triazolo[4,5-d]-pyrimidines (184, 185). An analogous procedure was employed to prepare the 7-amino derivatives (188) from phenylazomalondiamidine (186). 

Catalytic hydrogenation of 2-cyano-l-(2-nitrophenyl)piperidines over Pearlman s catalyst in a low-pressure hydrogenator under 1 atm of hydrogen in dioxane gave cyclic amidine A -oxides 352 (01EJOC987). 

Neither the oxide nor the amidine function are in fact required for activity. Treatment of the oxime, 7, with chloro-acetyl chloride in the presence of sodium hydroxide proceeds directly to the benzodiazepine ring system (14)(the hydroxyl ion presumably fulfills a role analogous to methylamine in the above rearrangement). Reduction of the N-oxide function of 14 leads to diazepam (15). ... 

In the oxidative Eschenmoser sulfide contraction (Scheme 11), thioamide 59 is oxidized by benzoyl peroxide to give either a symmetrical disulfide or the O-benzoate of the thiolactam-S-oxide. In any event, the once-nucleophilic thioamide sulfur atom is now forced to adopt the role of electrophile a reactivity umpolung has, in effect, been achieved.13 The nucleophilic enamide 65 attacks the sulfur atom leading to the formation of sulfur-bridged intermediate 66. The action of a phosphine or a phosphite thiophile on the putative episulfide then gives vinylogous amidine 67. 

Complete reduction of the azepine ring to hexahydroazepine has been effected with hydrogen and palladium,40 or platinum,135 239 catalysts. For example, ethyl 1 f/-azepine-l-carboxylate is reduced quantitatively at room temperature to ethyl hexahydroazepine-l-carboxylate (92% bp 118 —120 3C).134 136 TV-Phenyl-S/Z-azepin -amine (1), however, with platinum(IV) oxide and hydrogen in methanol yields the hexahydroazepine 2 in which the amidine unit is preserved in the final product.34 The same result is obtained using 5% palladium/barium carbonate, or 2 % palladium/Raney nickel, as catalyst. 

Interestingly, it appears that thiirene oxides also react with amidines (e.g. DBU) in a similar way2. 

The entrapment of lithium oxide and lithium halides by the lithium amidinate Li[Bu"C(NBu02] has been studied in detail by X-ray crystallography Interesting polycylic molecular structures have been obtained, as exemplified by the unusual sandwich complex of lithium oxide made from Li[Bu C(NBu )2l in toluene... 

A bis(chelate) structure was found for the closely related germylene [MeC(NPr )2]2Ge, which was also made from GeCl2(dioxane) and 2 equivalents of the lithium amidinate (colorless crystals, 81%). The same synthetic approach was used to make bis(amidinato) metal dichlorides of silicon and germanium in high yields (83-95%). Rapid oxidative addition of chalcogen atom sources (styrene sulfide and elemental Se) to the germylene derivatives resulted in a series... 

Oxidative addition of diphenyldichalcogenides, PhEEPh (E = S, Se) to Ge(II) bis(amidinate) complexes was found to occur rapidly, resulting in formation of the corresponding Ge(IV) bis(phenylchalcogenolato) derivatives as shown in Scheme 45. Diphenylditelluride did not react even at elevated temperatures. 

Tin amidinates display a rich coordination chemistry with the metal in both the di- and tetravalent oxidation states. The first results in this area were mainly obtained with N-silylated benzamidinate ligands. Typical reactions are summarized in Scheme 48. A stannylene containing unsymmetrically substituted amidinate ligands, [o-MeC6H4C(NSiMe3)(NPh)]2Sn, has been prepared accordingly and isolated in the form of colorless crystals in 75% yield. ... 

A sterically hindered homoleptic samarium(lll) tris(amidinate), Sm[HC (NC6H3Pr2-2,6)2]3, was obtained by oxidation of the corresponding Sm(II) precursor (cf. Scheme 54). Magnetic data and the results of low temperature absorption, luminescence, and magnetic circular dichrosim spectra have been... 

The role of steric influences on the formation of various vanadium amidinate complexes in the oxidation states +2 and +3 has been studied in detail. The reaction of VCl2(TMEDA)2 and of VCl3(THF)3 with 2 equivalents of formamidinate salts afforded dimeric V2[HC(NCy)2l4 (cf. Section IV.E) with a very short V-V multiple bond and [ [HC(NCy)2 V(/i-Cl)l2 which is also dimeric (Scheme 107). The formation of V2[HC(NCy)2l4 was shown to proceed through the intermediate monomeric [HC(NCy)2l2V(TMEDA), which was isolated and fully characterized. The dinuclear structure was reversibly cleaved by treatment with pyridine forming the monomeric [HC(NCy)2l2V(py)2. ... 

Chlorination of the Cp Ru(amidinate) complexes is readily achieved by treatment with CHCI3, while oxidative addition of allylic halides results in formation of cationic Ti-allyl ruthenium(IV) species (Scheme 243). °... 

Reaction of Li[Fc(NCy)2l with 0.5 equivalents of [Rh(CO)2(/t-Cl)]2 formed orange [FcC(NCy)2]Rh(CO)2 in good yield. Chemical oxidation of [FcC(NCy)2]Rh(CO)2 with AgBF4 generated the amidine-containing product [ FcCfNCylNHCylRhfCOlJlBFJ (Scheme 150). ... 

Gold in the oxidation state +1 also tends to form dinuclear complexes with bridging amidinate ligands. A typical example is Au2[HC(NC6H3Me2-2,6)2]2 (cf. Section Oxidative addition of iodomethane to the dinuclear gold(I)... 

Substituted pyrimidine N-oxides such as 891 are converted analogously into their corresponding 4-substituted 2-cyano pyrimidines 892 and 4-substituted 6-cya-no pyrimidines 893 [18]. Likewise 2,4-substituted pyrimidine N-oxides 894 afford the 2,4-substituted 6-cyano pyrimidines 895 whereas the 2,6-dimethylpyrimidine-N-oxide 896 gives the 2,6-dimethyl-4-cyanopyrimidine 897 [18, 19] (Scheme 7.6). The 4,5-disubstituted pyridine N-oxides 898 are converted into 2-cyano-4,5-disubsti-tuted pyrimidines 899 and 4,5-disubstituted-6-cyano pyrimidines 900 [19] (Scheme 7.6). Whereas with most of the 4,5-substituents in 898 the 6-cyano pyrimidines 900 are formed nearly exclusively, combination of a 4-methoxy substituent with a 5-methoxy, 5-phenyl, 5-methyl, or 5-halo substituent gives rise to the exclusive formation of the 2-cyanopyrimidines 899 [19] (Scheme 7.6). The chemistry of pyrimidine N-oxides has been reviewed [20]. In the pyrazine series, 3-aminopyrazine N-ox-ide 901 affords, with TCS 14, NaCN, and triethylamine in DMF, 3-amino-2-cyano-pyrazine 902 in 80% yield and 5% amidine 903 [21, 22] which is apparently formed by reaction of the amino group in 902 with DMF in the presence of TCS 14 [23] (Scheme 7.7) (cf. also Section 4.2.2). Other 3-substituted pyrazine N-oxides react with 18 under a variety of conditions, e.g. in the presence of ZnBr2 [22]. 

NO synthase catalyzes a five-electron oxidation of an amidine nitrogen of arginine. L-Hydroxyarginine is an intermediate that remains tighdy bound to the en-... 

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