Amidines, hydrolysis

Therefore, the conclusion from these studies was that p glucosides hydrolyze by a syn elimination mechanism [67] which is supported by the conclusion reached by Perrin and Nunez in their study of amidine hydrolysis [68]. This conclusion also conforms to Sinnott s principle of least nuclear motion theory [69]. 

As a class of compounds, nitriles have broad commercial utility that includes their use as solvents, feedstocks, pharmaceuticals, catalysts, and pesticides. The versatile reactivity of organonitnles arises both from the reactivity of the C=N bond, and from the abiHty of the cyano substituent to activate adjacent bonds, especially C—H bonds. Nitriles can be used to prepare amines, amides, amidines, carboxyHc acids and esters, aldehydes, ketones, large-ring cycHc ketones, imines, heterocycles, orthoesters, and other compounds. Some of the more common transformations involve hydrolysis or alcoholysis to produce amides, acids and esters, and hydrogenation to produce amines, which are intermediates for the production of polyurethanes and polyamides. An extensive review on hydrogenation of nitriles has been recendy pubHshed (10). 

Cyanopyridazines add ammonia, primary and secondary amines and hydroxylamine to give amidines or amidoximes. Substituted amides, thioamides and carboximidates can be also prepared. With hydrazine, 3-pyridazinylcarbohydrazide imide is formed and addition of methylmagnesium iodide with subsequent hydrolysis of the imine affords the corresponding pyridazinyl methyl ketone. 

The reactivity of the amino groups at the pteridine nucleus depends very much upon their position. All amino groups form part of amidine or guanidine systems and therefore do not behave like benzenoid amino functions which can usually be diazotized. The 4-, 6-and 7-amino groups are in general subject to hydrolysis by acid and alkali, whereas the 2-amino group is more stable under these conditions but is often more susceptible to removal by nitrous acid. 

Several related derivatives have also been utilized in this type of synthesis. Imino-chloromethanesulfenyl chlorides (184), prepared by the controlled addition of chlorine to isothiocyanates, react with amidines (161) to give 1,2,4-thiadiazolines (185) (71T4117). Chlorocarbonylsulfenyl chloride (186), prepared by the hydrolysis of trichloromethanesulfenyl chloride with sulfuric acid, reacted with ureas, thioureas and guanidines to give 1,2,4-thiadiazolidine derivatives (187) <70AG(E)54, 73CB3391). 

The third step is hydrolysis of the N-phosphorylated amidines which is carried out by either acid or alkali depending on the substrate. 

The propionitrile (94) also yielded a pyrido[2,3-d]pyTimidine (96) when treated with ammonia or methylamine, the intermediate amidine (95) undergoing hydrolysis during the reaction.Amination was shown to be the rate-determining stage. 

Copper complexes, 5,533-750 acetylacetone hydrolysis, 2,379 photoreduction, 2.384 amidines... 

The zinc complex formed with V,V -diphenylformamidinate is structurally analogous to the basic zinc acetate structure, as [Zn4(/i4-0)L6], and the basic beryllium acetate structure. It is prepared by hydrolysis of zinc bis(diphenylformamidinate).184 Mixed metal zinc lithium species were assembled from dimethyl zinc, t-butyl lithium, V.iV -diphenylbenzamidine and molecular oxygen. The amidinate compounds formed are dependent on the solvent and conditions. Zn2Li2 and... 

Because of their ease of crystallization, alkylzinc alkoxides are often isolated as decomposition products in reactions involving organozinc compounds. The methylzinc lithium tert- butoxide heterocubes [ (THF)LiOBut 2-(MeZnOBu1 ]182 (Figure 58, 123) and [(LiOBu MeZnOBu1 ]183 124 were isolated as hydrolysis products from reactions involving amines, amidines, /< //-butyllithium, and dimethylzinc. 

The amidine bond formed is quite stable at acid pH however, it is susceptible to hydrolysis and cleavage at high pH. A typical reaction condition for using imidate crosslinkers is a buffer system consisting of 0.2 M triethanolamine in 0.1 M sodium borate, pH 8.2. After conjugating two proteins with a bifunctional imidoester crosslinker, excess imidoester functional groups may be blocked with ethanolamine. 

Hydrolysis of amino-alkylamino-l,2,5-thiadiazole 1-oxides 55 with concentrated aqueous HC1 gave the amidines 56 (Equation 4) <2001JME1231>. The hydrolysis reactions of 2-alkyl-4-amino-2,3-dihydro-l, 2,5-thiadiazol-3-one 1,1-dioxides 57 in the range 24-73 °C in buffered aqueous solutions gave the corresponding 2-amino-2-[(iV-alkyl-substituted-sulfamoyl)imino]acetic acid salts 58 (Equation 5) <1998JP0489>. 

Fluoroethyl fluoroacetate is a compound of considerable toxicity. Its l.c. 50 for rabbits (inhalation) is 0-05 mg./l., i.e. about half as great as for M.F.A. It is therefore placed in class A. Other factors apart from hydrolysis to fluoroethanol and fluoroacetic acid appear to be operative, and it seems that the molecule is toxic per se. The related fluoroacetylimino-2-fluoro-ethyl ether hydrochloride, [CH2F C( NH2) O CH2 CH2F]+CT, is also placed in class A. This is understandable as it is readily hydrolysed by water to 2-fluoroethyl fluoroacetate. Other fluoroacetylimino ether hydrochlorides containing, however, only one fluorine atom fall into class B, as does also fluoroacet-amidine hydrochloride itself. 

Ethanolysis of isopropylidene bis(cyclohexylamino)methylenemalonate (1731) afforded 2-oxo ester (1732) in boiling ethanol in the presence of sulfuric acid, and the hydrolysis of 1731 in dioxan in the presence of concentrated hydrochloric acid gave amidine (1733) (88ZC436). 

Amidines such as the ones presented here appear to have a number of advantages, displaying good water solubility, and not producing formaldehyde during breakdown. Varying the dialkylamino group can modulate the lipo-philicity and the rate of nonenzymatic hydrolysis, and the stability of amidines under the acidic conditions that prevail in the stomach is compatible with oral administration. Future studies will certainly reveal the potential medicinal value of amidines. 

There is one report of reductive cleavage of the imidazole ring. Treatment of 122 with sodium dithionate in aqueous ammonia yielded amidine 123, which on hydrolysis with acid gave 124. Compound 124 was obtained directly on reduction with sodium dithionate in aqueous ethanolic sodium bicarbonate (83JHC1003). 

Reduced pyrimidines are much less stable toward hydrolysis than the fully conjugated analogs, and this is often used synthetically to produce amino acids and diamines. The BH3 reduction of cyclic amidines (1,4,5,6-tetrahydropyr-imidines) to hexahydropyrimidines, and their subsequent hydrolysis was mentioned above <1999JFIC105>, but there are many more examples. For instance, m-cyclobutane /5-amino acids 544 can be prepared from the cyclobutane derivatives 542 formed by the [2-F2] photocycloaddition reaction between uracil and ethylene <2002TL6177, 2004TL7095, 2006SL1394>. 

Kolb and Barth 229) synthesized oc-substituted optically active amines or amino acids (223). Again the authors employed a derivative of naturally occurring (S)-proline, namely (—)-(S)-l-dimethoxymethyl-2-methoxymethyl-pyrrolidine (221) as chiral auxiliary agent. The metalation of the amidines (160) leads to azaallyl anions homologous with (222). After alkylation and hydrolysis, the desired a-substituted amines and amino acids, respectively, are obtained with some stereoselectivity. 

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). 

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