Barbituric acid, reaction with

The treatment of 5-phenyl-5-(3 -bromopropyl)barbituric acid (145) with ammonium hydroxide yields 3-phenyl-3-allophanyl-2-piperidon. The reaction begins with the ammonolysis of 145 and then the resultant primary amino function attaches to the C-6 or C-4 carbonyl group of the ring with ring opening to yield 146, which then hydrolyzes to 147.400 5-Phenyl- and 5-allyl-5-(2 -hydroxypropyl)barbituric acids undergo similar intramolecular isomerization and a-phenyl-a-allophany,l-y-valerolactones are formed, respectively.359,401-403... 

Reaction of strong CH-acidic such as Meldrum s acid or barbituric acid derivatives, with aldehydes and urea was studied by Shaabani et al. this led to an efficient sol-vent-free synthesis of spiro-fused heterocycles by use of microwave irradiation [158]. 

Similar reactions of other barbituric acid derivatives with alkenes gave the corresponding 5,5-bis(2-hydroperoxyethyl)barbituric acids in quantitative yields (Scheme 23). Using thiobarbituric acid also afforded a similar bis(hydroperoxide) in good yield. 

Section 21 8 Alkylation of diethyl malonate followed by reaction with urea gives derivatives of barbituric acid called barbiturates, which are useful sleep promoting drugs... 

More conveniently, compound (13) was directly condensed with barbituric acid (14) in acetic acid (28) or in the presence of an acid catalyst in an organic solvent (29). The same a2o dye intermediate (13) and alloxantin give riboflavin in the presence of palladium on charcoal in alcohoHc hydrochloric acid under nitrogen. This reaction may involve the reduction of the a2o group to the (9-phenylenediamine by the alloxantin, which is dehydrogenated to alloxan (see Urea) (30). 

Cyanide compounds are classified as either simple or complex. It is usually necessary to decompose complex cyanides by an acid reflux. The cyanide is then distilled into sodium hydroxide to remove compounds that would interfere in analysis. Extreme care should be taken during the distillation as toxic hydrogen cyanide is generated. The cyanide in the alkaline distillate can then be measured potentiometricaHy with an ion-selective electrode. Alternatively, the cyanide can be determined colorimetricaHy. It is converted to cyanogen chloride by reaction with chloramine-T at pH <8. The CNCl then reacts with a pyridine barbituric acid reagent to form a red-blue dye. 

Beryllium, calcium, boron, and aluminum act in a similar manner. Malonic acid is made from monochloroacetic acid by reaction with potassium cyanide followed by hydrolysis. The acid and the intermediate cyanoacetic acid are used for the synthesis of polymethine dyes, synthetic caffeine, and for the manufacture of diethyl malonate, which is used in the synthesis of barbiturates. Most metals dissolve in aqueous potassium cyanide solutions in the presence of oxygen to form complex cyanides (see Coordination compounds). 

The direct formation of dipyrimidin-5-yl sulfides occurs on treatment of appropriate 5-unsubstituted pyrimidine substrates with sulfur mono- or di-chloride. Thus, reaction of uracil (83 R = H) with sulfur monochloride in boiling formic acid gives diuracil-5-yl sulfide in good yield sulfur dichloride gives a poor yield. Simple derivatives of uracil and barbituric acid undergo similar reactions but not cytosine, isocytosine, 2,4-bismethylthiopyrimidine or pyrimidine-4,6-dione (59). The mechanism is unknown (72AJC2275). 

Early investigators adduced various kinds of chemical evidence in support of a monohydroxy-dioxo structure for barbituric acid (112) (a) reaction with diazomethane afforded a mono-O-methyl deriva- iye,i59,i6o barbituric acid and its 5-alkyl derivatives are much stronger acids than the 5,5-dialkyl derivatives, and (c) the 5-bromo and 5,5-dibromo derivatives have different chemical properties. - The early physical evidence also appeared to substantiate the monoenol structure, this formulation having been suggested for barbituric acid in 1926 on the basis of its ultraviolet spectrum and again in 1934, In the 1940 s, ultraviolet spectroscopic studies led to the suggestion of other monohydroxy and dihydroxy structures for barbituric acid, whereas its monoanion was assigned structure 113 (a clear distinction between ionization and tautomerism was not made in these papers). 

It is, however, more likely that the discrepancies observed in the periodate oxidation of malonaldehyde concern mainly the hydroxylation step. In the mechanism proposed (5) for this reaction, it is the enol form of malonaldehyde which is hydroxylated. However, titrations of a solution of malonaldehyde, prepared by hydrolysis of an aqueous solution (33) of carefully distilled 1, 3, 3-tri-ethoxypropene (46, 47), both with strong base and with iodine, indicate that only about 80% of the enol form is present in the equilibrium solution. On the other hand, the thio-barbituric acid test (58, 59) gave consistently higher values for the malonaldehyde content of the solution. The fact that only about 80% of the enol form is present in the equilibrium solution is all the more important as it can be shown (56) by titration with strong base that the enolization is slow, and moreover does not seem to go to completion. 

In a 2-1. round-bottomed flask fitted with a reflux condenser protected by a calcium chloride tube 11.5 g. (0.5 gram atom) of finely cut sodium is dissolved in 250 cc. of absolute alcohol. To this solution is added 80 g. (0.50 mole) of ethyl malonate followed by 30 g. (0.50 mole) of dry urea dissolved in 250 cc. of hot (70°) absolute alcohol. After being well shaken the mixture is refluxed for seven hours on an oil bath heated to 1 io°. A white solid separates rapidly. After the reaction is completed, 500 cc. of hot (50°) water is added and then enough hydrochloric acid (sp. gr. 1.18) to make the solution acidic (about 45 cc.). The resulting dear solution is filtered and cooled in an ice bath overnight. The white product is collected on a Buchner funnel, washed with 50 cc. of cold water, and then dried in an oven at 105-1 io° for three to four hours. The yield of barbituric acid is 46-50 g. (72-78 per cent of the theoretical amount). 

Barbituric acid can be considered as a cyclized malonic acid diamide (malonyl-urea). It is therefore a cyclic diketone that may be classified, in the sense of the compounds discussed in Section 12.6, as a coupling component with a methylene group activated by two carbonyl groups in the a- and a -positions. The reaction with arenediazonium salts was studied by Nesynov and Besprozvannaya (1971). These authors obtained coupling products (in good yield) that they considered to be arylhydrazones. Coupling with 4-(phenylazo)benzenediazonium chloride was studied by Chandra and Thosh (1991). The lH NMR spectra of these compounds are consistent with the arylhydrazone structure 12.68. 

In the Diels-Alder reaction with inverse electron demand, the overlap of the LUMO of the 1-oxa-l,3-butadiene with the HOMO of the dienophile is dominant. Since the electron-withdrawing group at the oxabutadiene at the 3-position lowers its LUMO dramatically, the cycloaddition as well as the condensation usually take place at room or slightly elevated temperature. There is actually no restriction for the aldehydes. Thus, aromatic, heteroaromatic, saturated aliphatic and unsaturated aliphatic aldehydes may be used. For example, a-oxocarbocylic esters or 1,2-dike-tones for instance have been employed as ketones. Furthermore, 1,3-dicarbonyl compounds cyclic and acyclic substances such as Meldmm s acid, barbituric acid and derivates, coumarins, any type of cycloalkane-1,3-dione, (1-ketoesters, and 1,3-diones as well as their phosphorus, nitrogen and sulfur analogues, can also be ap-... 

A reaction known as diazo group transfer produces diazo barbituric acid from barbituric acid and p-toluene sulfonyl azide. Additional barbituric acid affords azo barbituric acid [7]. Subsequent complexation with a nickel (II) salt yields a greenish yellow pigment. 

Likewise, suitable starting materials are iminoisoindolines, especially diimino-isoindoline (l-amino-3-iminoisoindolenine), which reacts with a cyanoacetamide NCCH2CONHR5 to afford a mono-condensation product 49. Further reaction with a compound containing an activated methylene group (such as cyanoacetamide derivatives, barbituric acid) yields the desired pigment 47 ... 

Tosylation of 1146 gave 1147, which was converted to the iodo derivative, whose reaction with the sodium salt of guanine, followed by acetylation to aid its purification and then deprotection, gave 1148 (86JMC1384). The hydroxymethyl groups on C-5 of barbituric acid were introduced starting with malonic ester and then reaction with urea (93MI12). 

Barbituric acid, a 2,4,5-tiihydrox3q)yrimidine, which exists in the triketo form, is also able to readt with CFgSCl. Owing to the strong acidity of the methylene group, the reaction can take place in this case without... 

The Knoevenagel reaction consists in the condensation of aldehydes or ketones with active methylene compounds usually performed in the presence of a weakly basic amine (Scheme 29) [116], It is well-known that aldehydes are much more reactive than ketones, and active methylene substrates employed are essentially those bearing two electron-withdrawing groups. Among them, 1,3-dicarbonyl derivatives are particularly common substrates, and substances such as malonates, acetoacetates, acyclic and cyclic 1,3-diketones, Meldrum s acid, barbituric acids, quinines, or 4-hydroxycoumarins are frequently involved. If Z and Z groups are different, the Knoevenagel adduct can be obtained as a mixture of isomers, but the reaction is thermodynamically controlled and the major product is usually the more stable one. 

Interestingly enough, a closely related protocol was successfully proposed for the synthesis of spirooxindoles-containing tetrahydrochromene skeletons when aromatic aldehydes were switched for isatin derivatives. This high-yielded reaction was performed with dimedone, 4-hydroxycoumarin, or barbituric acids in water using triethylbenzylammonium chloride (TEBA) as catalyst (Scheme 36) [125]. A Knoevenagel condensation occurred first between isatin and malonitrile derivative, followed by Michael addition of 1,3-dicarbonyl substrates and cyclization to the cyano moiety. 

The preparation of barbiturates illustrates many of the synthetic methods covered in this chapter. The preparation employs the reaction of urea (C0(NH2)2) with malonic ester to form barbituric acid. The general reaction is presented in Figure 15-30. The stable pyrimidine and other resonance forms help drive the reaction. By alternating the substituent at carbon number five (C5), various pharmacologically active substances can be formed. Barbital, a sedative, and phenobarbital, a sleeping aid, are shown in Figure 15-31. 

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