Indazole, structure

On the other hand, theoretical methods allow an insight into the structure of non-existent molecules like 2//-indazole (37) or the anion of indazole (38). INDO calculations have been performed by Palmer et al. on the anion of indazole (38) (75JCS(P1)1695). The optimized geometry obtained by them is shown in Figure 7. The N—N bond distance is longer in the... 

The indazole molecular structure (Figure 11) shows the tautomeric proton bonded to N-1 (1//-indazole. Section 4.04.1.5.1). A linear correlation between the bond lengths and the bond orders calculated by the CNDO/2 method was observed (74T2903). 

Figure 11 Bond lengths and bond angles of indazole X-ray structure...

The coupling constants are very rich in structural information. For the sake of comparison, indazole and isoindazole have been numbered like pyrazoles (Figure 16). 

From UV studies of 4-phenyl-, 4-nitro- and 4-nitroso-pyrazoles, Habraken et al. (67RTC1249,72JHC939) conclude that the 4-pyrazolyl group acts as an electron-donating group. UV spectra of pairs of 1-aryl- and 2-aryl-indazoles and their utility in the determination of isomeric structures are discussed in (67BSF2619) many other UV data on indazole derivatives can be found in (71PMH(3)67). 

Substituted indazolones exist in the OH form (143b) and 2-substituted indazolones exist in the NH form (144a), whereas the structure of AC-unsubstituted indazolones varies with the physical state. This difference of behaviour, depending on the position of the A -R substituent, corresponds to the aromatic structure of the indazole derivatives compared with the quinonoid structure of isoindazoles. 

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). 

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). 

Finally, a new class of antispermatogenic agents containing the same fundamental structure cited above has been described (76JMC778). 1-Halobenzyl-l J/-indazole-3-carboxylic acids are potentially useful for birth control, and because they act after a single administration they are of interest for the physiological study of the male reproductive system. 

In the search for new structures with antiinflammatory activities some 1-substituted 3-dimethylaminoalkoxy-lJ/-indazoles (704) have been synthesized and pharmacologically tested (66JMC38). Doses of 20-40 mg g i.p. produced sedation, muscle relaxation and motor incoordination, whereas doses of 80-100 mg kg produced depression. Toxicity was fairly constant in all series, varying from 120 to 150 mg kg i.p., with the exception of compounds possessing a nitro group or an amino group in the indazole nucleus, which provoked cyanosis. 

Support for this suggestion comes from many quarters. Reduction of the jS-carboline anhydro-bases with sodium and alcohol or with tin and hydrochloric acid gives the 1,2,3,4-tetrahydro derivatives, as does catalytic reduction over platinum oxide in an alkaline medium. On the other hand, catalytic reduction with platinum oxide in acetic acid results in the formation of the 5,6,7,8-tetrahydro-j3-carbolinium derivatives (see Section III,A,2,a). It should be noted, however, that reduction of pyrido[l,2-6]indazole, in which the dipolar structure 211 is the main contributor to the resonance hybrid, could not be effected with hydrogen in the presence of Adams catalyst. 

Infrared spectral evidence indicates that indazol 3-one probably exists in the oxo form (cf. 77). 4-Monosubstituted-l,3-diphenylpyrazol-5-ones have been assigned an oxo structure (cf. 78) on the basis of infrared (presence of a v C=N band) and ultraviolet spectral data. The structure of certain iV-acylated pyrazolones has been discussed on the basis of their infrared spectra, but in these cases the possibility of acyl migration is a complicating factor. 

As reported by Steel et al. three structural isomers of bis(camphor-pyrazol-l-yl)methane (21a, 21b and 21c) are formed by coupling of camphorpyrazole 10 [i.e., (4S,7i )-7,8,8-trimethyl-4,5,6,7-tetrahydro-4,7-methano-l(2)H-indazole] with CH2CI2 (121). Isomer 21c can be separated from the other two structural isomers by crystallization or column chomatography. Deprotonation at the bridging carbon atom, subsequent reaction with carbon dioxide and acidic workup yields the enantiopure bis(camphorpyrazol-l-yl)acetic acid Hbpa (8) (Scheme 17, Fig. 19) (116). Due to missing substituents at the p5rrazolyl carbon C5 and a hence likely ortho metallation, isomers 21a and 21b are not suited for his reaction (72). 

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