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Pyrazole preparation

Lithiated pyrazoles prepared from CtH or preferably from C-Br pyrazoles (B-76MI40402) can be transformed into carboxylic acids. In this way pyrazole-4-carboxylic acids (504 ... [Pg.267]

The synthesis and relative stability of 3,5-diacyl-4,5-dihydro-l//-pyrazoles prepared by dipolar cycloaddition of enones and a-diazoketones has been published <2004JOC9085>. 3-Acyl-4-aryl-2-pyrazolines have been synthesized by the reaction of a,/3-unsaturated ketones with diazomethane <1996IJB1091>. Ethyl diazoacetate added to 1,3-diarylpropenones in a regioselective fashion to give the intermediate 4,5-dihydto-3//-pyrazole derivative 1,3-hydride shift in the latter led to the formation of the isomeric ethyl 4-aryl-5-aroyl-4,5-dihydro-l//-pyrazole-3-carboxylate and ethyl 4-aryl-3-aroyl-4,5-dihydro-l/7-pyrazole-5-carboxylate in a ratio of 5 1 <2001RJ01517>. 1,3-Dipolar cycloaddition of 2-diazopropane with diarylideneacetones afforded diastereomeric bis-A -pyrazolines <1999T449>. [Pg.97]

Turchi and Cullen described the first examples of pyrazoles prepared from oxazoles (Scheme 1.231). Treatment of 5-ethoxy-p-oxo-2-phenyl-4-oxazolepropa-noic acid ethyl ester 857 with hydrazine did not afford the expected pyrazolone 858. Instead, the authors isolated ethyl-4-(benzoylamino)-5-ethoxy-l//-pyrazole-3-acet-ate 860 (R = H) in good yield. Similarly, reaction of 857 with methyUiydrazine produced 860 (R = CH3) in comparable yield. [Pg.185]

If 7 Rg, a mixture of the two isomeric pyrazoles is obtained. An excellent method to prepare pyrazole [288-13-1] consists in treating 1,1,3,3-tetramethoxypropane (masked malondialdehyde) with hydrazine (eq. 2). [Pg.313]

Fig. 2. Pyrazole-derived pharmaceuticals (a) butaglyon [2603-23-8] an antidiabetic (b) dazopride [70181 -03-2] an antiemetic (c) feclobuzo [23111-34 ] an antiinflammatory (d) kebuzone [833-34-9], an antirheumatic (e) muzolimin [55294-15-0], a diuretic (f) phenazobz [20610-63-3], an antiasthmatic (g) selenofob [39102-63-1], an antibiotic (h) sulfamazo [65761-24-2], an antiseptic and (i) sulfinpyrazone [57-96-5], an antigout preparation (50). Fig. 2. Pyrazole-derived pharmaceuticals (a) butaglyon [2603-23-8] an antidiabetic (b) dazopride [70181 -03-2] an antiemetic (c) feclobuzo [23111-34 ] an antiinflammatory (d) kebuzone [833-34-9], an antirheumatic (e) muzolimin [55294-15-0], a diuretic (f) phenazobz [20610-63-3], an antiasthmatic (g) selenofob [39102-63-1], an antibiotic (h) sulfamazo [65761-24-2], an antiseptic and (i) sulfinpyrazone [57-96-5], an antigout preparation (50).
Pyrazoles and imidazoles carrying a substituent on nitrogen, as well as oxazoles, thiazoles, etc., are converted by alkyl halides into quaternary salts. This is Illustrated by the preparation of thiamine (89) from components (87) and (88). [Pg.51]

Azoles containing a free NH group react comparatively readily with acyl halides. N-Acyl-pyrazoles, -imidazoles, etc. can be prepared by reaction sequences of either type (66) -> (67) or type (70)->(71) or (72). Such reactions have been carried out with benzoyl halides, sulfonyl halides, isocyanates, isothiocyanates and chloroformates. Reactions occur under Schotten-Baumann conditions or in inert solvents. When two isomeric products could result, only the thermodynamically stable one is usually obtained because the acylation reactions are reversible and the products interconvert readily. Thus benzotriazole forms 1-acyl derivatives (99) which preserve the Kekule resonance of the benzene ring and are therefore more stable than the isomeric 2-acyl derivatives. Acylation of pyrazoles also usually gives the more stable isomer as the sole product (66AHCi6)347). The imidazole-catalyzed hydrolysis of esters can be classified as an electrophilic attack on the multiply bonded imidazole nitrogen. [Pg.54]

Scheme 4 shows in a general manner cyclocondensations considered to involve reaction mechanisms in which nucleophilic heteroatoms condense with electrophilic carbonyl groups in a 1,3-relationship to each other. The standard method of preparation of pyrazoles involves such condensations (see Chapter 4.04). With hydrazine itself the question of regiospecificity in the condensation does not occur. However, with a monosubstituted hydrazine such as methylhydrazine and 4,4-dimethoxybutan-2-one (105) two products were obtained the 1,3-dimethylpyrazole (106) and the 1,5-dimethylpyrazole (107). Although Scheme 4 represents this type of reaction as a relatively straightforward process, it is considerably more complex and an appreciable effort has been expended on its study (77BSF1163). Details of these reactions and the possible variations of the procedure may be found in Chapter 4.04. [Pg.121]

Pyrazole and indazole anions, in a manner similar to other azole anions, show the expected inversion of reactivity when compared with the cations. They are more reactive towards electrophiles, both at the nitrogen and carbon atoms, and less reactive towards nucleophiles than the corresponding neutral molecules. For practical purposes most of the N -alkylated pyrazoles and indazoles are prepared from the corresponding anions. [Pg.218]

Phase transfer catalysis has been used with success to prepare N- substituted pyrazoles (78MI40403, 79MI40408, 70JHC1237, 80JOC3172) and this procedure can be considered the simplest and most efficient way to obtain these compounds. Experimental design methodology has been used to study the influence of the factors on the reaction between pyrazole and -butyl bromide under phase transfer conditions (79MI40408). [Pg.230]

The fact that the isomeric structure of azolides is thermodynamically controlled has been used by Olofson and Kendall to prepare 1-alkylazoles regioselectively (70JOC2246). An asymmetric pyrazole yields two alkylated derivatives (Scheme 21 see Section 4.04.2.1.3 (viii)), but the alkylation with a powerful alkylating agent of the acetylated derivative leads to the less abundant isomer via the salt (249), which is too unstable to be isolated. [Pg.232]

With an activated C—C triple bond two successive additions can occur if the intermediate alkene is reactive enough. DMAD and 3,5-dimethylpyrazole give an initiaj fumarate (255) which reacts further at the other end to form regioselectively the succinates (256). On the other hand, methyl ethynyl ketone reacts twice at the same carbon atom with pyrazole to form 1,1-pyrazolylbutanone (258) (68ZC458). The probable intermediate, a pyrazolide vinylogue (257), can be prepared from methyl chlorovinyl ketone and pyrazole, in a reaction which is similar to acetylation (Section 4.04.2.1.3(x)). [Pg.233]

Analogously, pyrazolyl-aluminate and -indate ligands have been prepared <75JCS(D)749) and their chelating properties evaluated with cobalt, nickel, copper and zinc. Gallyl derivatives of pyrazoles and indazoles have been extensively studied by Storr and Trotter e.g. 75CJC2944) who determined several X-ray structures of these compounds. These derivatives exist in the solid state as dimers, such as (212) and (288). A NMR study in acetone solution showed the existence of a slow equilibrium between the dimer (212) and two identical tautomers (289) and (290) (Section 4.04.1.5.1) (81JOM(215)157). [Pg.236]

Phosphorus derivatives of different structures have been prepared including pyrazol-1-ylphosphines PPzs, PhPPz2 and Ph2PPz (Pz for pyrazolate anion (72CRV497,80MI40402)). By transamination with tris(dimethylamino)phosphine, pyrazoles and indazole are converted into (291) and (292), respectively (67CR(C)(265)1507). 3,5-Dimethylpyrazole reacts with amidodichlorophosphates to yield triamides (293) whereas 1-substituted pyrazolones yield amidophosphates (294) (71LA(750)39). [Pg.236]

Halogenation is one of the most studied electrophilic substitutions in the pyrazole series (67HC(22)1, B-76MI40402). The results concern chlorination, bromination and iodination since there is no report on direct fiuorination of pyrazoles (fiuoropyrazoles are prepared by other... [Pg.239]

Pyrazolecarbinols can be dehydrated to vinylpyrazoles, (438) — (446) (72JHC1373), or transformed into chloromethyl derivatives (81T987). Compound (440 R = CH2C1) thus prepared is the starting material for the synthesis of the macrocycles (226)-(228) (Section 4.04.2.1.2(vi)). Vinyl- and ethynyl-pyrazoles have been extensively studied (B-76MI40402) and many vinylpyrazoles are polymerized by free radical initiators. [Pg.261]

In different seetions of this ehapter, pyrazoles and indazoles C-linked to a metal or a metalloid have been deseribed or they will be deseribed in the preparative seetions, ineluding lithio derivatives (Seetion 4.04.2.1.7), pyrazolylmagnesium reagents (Seetion 4.04.2.3.7(iii)), ehloromereury derivatives (Seetion 4.04.2.1.4(vii)) and silylpyrazoles (Section 4.04.3.1.2(ii)). All these compounds are useful intermediates and some of their most characteristic reactions will be dijcussed here. [Pg.267]

Sodium and silver pyrazole salts (Section 4.04.2.1.3(vl)) are often used Instead of neutral pyrazoles to facilitate electrophilic attack on the ring nitrogen atoms. For example, pyrazolyl-methanes (234)-(236) have been prepared from pyrazole anions (Section 4.04.2.1.3(vlll)). Unstable 2-acetyllndazoles are obtained from the reactive silver salts of indazoles (Section 4.04.2.1.3 (x)). Electrophilic attack on the ring carbon atoms also occurs more readily in... [Pg.270]

See other pages where Pyrazole preparation is mentioned: [Pg.90]    [Pg.115]    [Pg.31]    [Pg.154]    [Pg.93]    [Pg.77]    [Pg.90]    [Pg.115]    [Pg.31]    [Pg.154]    [Pg.93]    [Pg.77]    [Pg.308]    [Pg.122]    [Pg.106]    [Pg.197]    [Pg.225]    [Pg.230]    [Pg.231]    [Pg.232]    [Pg.233]    [Pg.234]    [Pg.235]    [Pg.245]    [Pg.246]    [Pg.258]    [Pg.260]    [Pg.262]    [Pg.263]    [Pg.266]   
See also in sourсe #XX -- [ Pg.33 , Pg.184 ]



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3- pyrazoles, preparation

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