Formamide 2-amino

The cyclization pathway proposed (81UK1252) involves nucleophilic substitution of the hetero group (XR) by the formamide amino group to form either enyne formamide 157 or imine 158. 

A structurally well-defined and water-soluble PVAm is available by acid or base catalyzed hydrolysis of PVFA (Scheme 2) [58, 59] because form-amide groups are readily hydrolyzed to amino groups. The degree of hydrolysis of PVFA can be used to produce adaptable copolymers, poly(vinyl form-amide-co-vinyl amine) (PVFA-co-PVAm) with different formamide/amino group ratios. Hence, the degree of hydrolysis of the formamide groups is an excellent tool to control the desired charge density of the polyelectrolyte. 

Amino-pyridazines and -pyridazinones react with monomethyl- or iV,A-dimethyl-formamide and other aliphatic amides in the presence of phosphorus trichloride, thionyl chloride, phosgene or benzenesuUonyl chloride to give mono- or di-alkylaminomethyl-eneamino derivatives. The same compounds can be prepared conveniently with A,iV-dimethylformamide dimethyl acetal in high yield (Scheme 50). 

Finally, some results obtained from indazoles substituted in the carbocycle are of interest, even though in these cases the reaction does not involve the heterocyclic moiety (Section 4.04.2.3.2(ii)). For example, pyrazolo[3,4-/]- (566) and pyrazolo[4,3-/]-quinolines (567) have been obtained from aminoindazoles by the Skraup synthesis (76JHC899). Diethylethoxy-methylenemalonate can also be used to give (566 R = C02Et, R = OH) (77JHC1175). Pyrazolo-[4,3-/]- and -[4,3-g]-quinazolones (568) and (569) have been obtained from the reaction of formamide with 5-amino-4-methoxycarbonyl- and 6-amino-5-carboxyindazole, respectively (81CB1624). 

Triazole has been prepared by the oxidation of substituted 1,2,4-triazoles, by the treatment of urazole with phosphorus pentasulfide, by heating equimolar quantities of formyl-hydrazine and formamide, by removal of the amino function of 4-amino-l,2,4-triazole, by oxidation of l,2,4-triazole-3(5)-thiol with hydrogen peroxide, by decarboxylation of 1,2,4-triazole-3(5)-carboxylic acid, by heating hydrazine salts with form-amide,by rapidly distilling hydrazine hydrate mixed with two molar equivalents of formamide, i by heating N,N -diformyl-hydrazine with excess ammonia in an autoclave at 200° for 24 hours, and by the reaction of 1,3,5-triazine and hydrazine monohydrochloride. ... 

Greater stereoselectivity for the formation of equatorial amines has been found in the reduction of enamines with formic acid or formamides (553-559). The selective formation of 3-a-amino-5- -steroids by this method and of 3- 3-amino-5- 3-steroids by catalytic reduction (5<50) of the corresponding enamines is of interest. 

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). 

Acid chlorides, acetic anhydride,and formamide have also been used to synthesize pyrido[2,3-d]pyrimidines from 2-ammo-nicotinamides, although in the last case high temperatures were necessary. It is suspected that all the foregoing eyclizations proceed via initial acylation of the 2-amino group to yield an intermediate 2 - amidonicotinamide. 

Good yields of pyrido[2,3-d]pyrimidiries (37) were also oblaiiied by the action of formamide on o-amino nitriles (36). Reduction of 2-amino-4,6-dimethylnicotinitrilc yields the 3-aminomcthyl compound (38). Acylation to the 3-aoylaminomethyl derivative (39), followed by cyolization, by means of heat or phosphoryl chloride, yielded the dihydropyrido[2,3-d]pyrimidines (40). ... 

Alkylpyrimidines were obtained in 59-70% yield from higher 1-dimethyl-amino- and l-methoxyalk-l-en-3-ynes (R = Me, Et, -Pr) by their reaction with formamide (70ZOR2374). The exception was l-methoxy-5,5-dimethylhex-l-en-3-yne, from which the pyrimidine was obtained in 45% yield only, which is related to steiic hindrance for the attack at the acetylene bond. 

In the authors opinion (81UK1252), the evidence for such a scheme is the isolation of formamide transamination products, dialkylformamides (in case of l-dialkylaminoalk-l-en-3-ynes). Examples of formamide transamination, e.g., by /3-amino-substituted carbonyl compounds, are known [58CB2832 60CB1402 60HC( 14)272],... 

Condensation of hydrazine with ethoxymethylenemalononitrile (22) gives 3-amino-4-cyanopyrazole (23). Hydrolysis with sulfuric acid leads to the amide, 24 heating with formamide inserts... 

Chemical Name N-[(4-Amino-2-methyl-5-pyrimidinyl)methyl] -N -[4-hydroxy-1-methyl-2-[(tetrahydrofurfuryl)dithio] -1 -butenyi] formamide... 

Chemical Name N,N -[dithiobis[2-(2-hydroxyethyl)-1-methylvinylene] ] bis[N-[(4-amino-2-methyl-5-pyrimidinyl)methyl] formamide]... 

Although a number of reagents can be used to reduce an isoxazole ring, molybdenum hexacarbonyl31 was selected for use in this synthesis. The action of this reagent on 24 reduces the weak N-0 bond of the isoxazole ring and produces a //-amino-a,//-unsaturated aldehyde (i.e. a vinylogous formamide) (see Scheme 19). Intermediate 87 forms smoothly upon deprotection of the terminal acetylene carbon with basic methanol-THF. 

With optically active formamide-derived aminocarbene complexes high enantioselectivity was observed in most cases (Table 5). This chemistry was used in the synthesis of 1-carbacephalathin and 3-ANA precursors (Eq. 9) [48], as well as the synthesis of a,a -disubstituted amino acids (Scheme 1) [49]. 

CN (J , P )-( )-A-[2-hydroxy-5-[l-hydroxy-2-[[2-(4-methoxyphenyl)-l-methylethyl]amino]ethyl]phenyl]formamide... 

CN yV-l(4-amino-2-methyl-5-pyrimidinyl)methyl]-N-[4-hydroxy-l-methyl-2-[[(tetrahydro-2-furanyl)methyl]dilhio]-l-butenyl]formamide... 

The Jacobsen group has also shown that the recycling of the resin-bounded catalyst can be successfully performed [152,154]. Moreover, they have developed an efficient method for the hydrolysis of the aminonitrile into the corresponding amino acid. This method was apphed for the commercial production of optically active K-amino acids at Rhodia ChiRex (e.g. tert-leucine) the catalyst was immobihsed on a resin support (4 mol %, 10 cycles) and the intermediate hydrocyanation adduct was trapped by simply replacing TFAA with HCOOH/AC2O, for example. Highly crystalhne formamide derivatives were thus obtained in excellent yields (97-98% per cycle) with very high enantioselectivities (92-93% per cycle) [158]. 

AEC stock solution 0.4 g of 3-amino 9-ethyl carbazole dissolved in 100 ml of N,N dimethyl formamide... 

The amino-substituted five-membered heterocycles are unstable compounds, but their acetyl and formyl derivatives can be isolated. N-(Selenienyl-3)formamide can be obtained via the reaction route shown in Scheme ll.134 An ortho, electron-attracting substituent, such as formyl or nitro, renders amino compounds stable. However, the yield of 2-nitro-3-aminoselenophene is quite low. 

In 2001, Sarko and coworkers disclosed the synthesis of an 800-membered solution-phase library of substituted prolines based on multicomponent chemistry (Scheme 6.187) [349]. The process involved microwave irradiation of an a-amino ester with 1.1 equivalents of an aldehyde in 1,2-dichloroethane or N,N-dimethyl-formamide at 180 °C for 2 min. After cooling, 0.8 equivalents of a maleimide dipo-larophile was added to the solution of the imine, and the mixture was subjected to microwave irradiation at 180 °C for a further 5 min. This produced the desired products in good yields and purities, as determined by HPLC, after scavenging excess aldehyde with polymer-supported sulfonylhydrazide resin. Analysis of each compound by LC-MS verified its purity and identity, thus indicating that a high quality library had been produced. 

The hydrochloride salt of 4-amino-1-benzylimidazole (83 R = H) was acetylated readily by acetic anhydride to give the acetamide derivative (83 R = COCHj) (55%) (74JMC1168). Treatment with acetic-formic anhydride gave the corresponding formamide (83 R = CHO). 

Treatment of 2-benzoylpyridine 81 with p-toluene-sulfonamide gave 1-amino-2-benzoylpyridinium tosylate 82 (X = OTs), which was cyclized with formamide in the presence of triethylamine hydrobromide to give 83 (82FRP2486942). The reaction of the perchlorate 82 (X = C104) with urea in polyphosphoric acid afforded 3-hydroxy-l-phenylpyrido[2,l-/][l,2,4]triazinium perchlorate 84. Treatment of this salt with base led to the zwitterionic l-phenylpyrido[2,l-/][l,2,4]triazin-5-ium-3-olate 85 (86JHC375). Pharmaceutical compositions contain 83 (82FRP2486942). 

The protected 5-amino-l-ribofuranosyl-4-(5-methyl-l,2,4-oxadiazol-3-yl)imidazole 58 (Equation 4) undergoes MHR to afford the 3-acetamidoimidazopyrazole 59 in dimethyl formamide (DMF) or DMSO as solvent at... 

This procedure represents the most convenient synthesis of 3(5)-aminopyrazole. It employs readily available starting materials and gives excellent yields in all steps.5,6 />-Toluene-sulfonyl chloride can be replaced by other arenesulfonyl chlorides. 3-Imino-l-arylsulfonylpyrazolidines can be alkylated with dimethyl sulfate or with alkyl 7>-toluenesulfonates in dimethyl-formamide to give salts of l-alkyl-2-arylsulfonyl-5-amino-4-... 

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