Heterocycles tetrazole

In the series of stable five-membered nitrogen-containing heterocycles, tetrazole possesses extreme characteristics that are inferior only to those of pentazole (cf. Section 6.07.4.3). Attention should be paid to the obvious fact that, in contrast to the hypothetical pentazole, tetrazole is a thermodynamically stable compound. This heterocycle surpasses the simple azide and hydrazoic acid by a number of key tests. However, tetrazoles are thermodynamically stable in the condensed phase, relatively weakly sensitive to impact and friction, and not very toxic, unlike HN3 which is notorious for its high sensitivity to impact, friction, thermal and electric impulses, and toxicity <1999THS(3)467>. 

FIGURE 8.8 Molecular structure of BTA and heterocyclic tetrazole compounds (ATA, PTA, and PTT). 

With the first nucleoside in place, we are ready to attach to it the second. For this purpose, the point of attachment, the 5 -OH, is deprotected with acid. Subsequent addition of a 3 -OH activated nucleoside effects coupling. The activating group is an unusual phosphoramidite [containing P(III)], which, as we shall see shortly, also serves as a masked phosphate [P(V)] for the final dinucleotide and is subject to nucleophilic substitution, not unlike PBrs (recall Sections 9-4 and 19-8). The displacement reaction is catalyzed and furnishes a phosphite derivative the catalyst is the, again unusual, aromatic heterocycle tetrazole, a tetrazacyclopentadiene related to pyrrole (Section 25-3) and imidazole (Section 26-1). Finally, the phosphorus is oxidized with iodine to the phosphate oxidation state. 

Substituted tetrazoles readily exchange the 5-hydrogen for deuterium in aqueous solution. A major rate-enhancing effect is observed with copper(II) or zinc ions due to complexation with the heterocycle. The rate of base-induced proton-deuterium exchange of 1-methyltetrazole is 10 times faster than 2-methyltetrazole (77AHC(2l)323). 

The classical age of preparative organic chemistry saw the exploration of the extensive field of five-membered heterocyclic aromatic systems. The stability of these systems, in contrast to saturated systems, is not necessarily affected by the accumulation of neighboring heteroatoms. In the series pyrrole, pyrazole, triazole, and tetrazole an increasing stability is observed in the presence of electrophiles and oxidants, and a natural next step was to attempt the synthesis of pentazole (1). However, pentazole has eluded the manifold and continual efforts to synthesize and isolate it. 

The 4-unsaturated-5-oxazolones provide convenient starting materials for the synthesis of other nitrogen-containing heterocyclic systems. The preparation of tetrazoles and isoquinolines is discussed in Sections II,B, 1 and II,B,2,b. 

Valence tautomerism of heterocyclic systems containing tetrazole rings has received much attention [76AHC(S1), p. 498 84CHEC-I(5)791 96CHEC-1I(4)621], The latest contributions to this area are considered in Section IV,C, which is concerned with the topic of azido-tetrazole tautomerism. 

Azide-tetrazole isomerism, or valence tautomerism, was not discussed for [5.6]bicyclic systems in the previous survey (76AHCS1). During recent years, this type of ring-chain tautomerism has been extensively studied for both six- and hve-membered heterocyclic azides. Tire tautomerism of [5.5]bicyclic tetrazole systems is covered in Section II,C. We discuss the tautomerism of the six-membered heterocyclic azides in this section. 

The diazotization of heteroaromatic amines is basically analogous to that of aromatic amines. Among the five-membered systems the amino-azoles (pyrroles, diazoles, triazoles, tetrazoles, oxazoles, isooxazoles, thia-, selena-, and dithiazoles) have all been diazotized. In general, diazotization in dilute mineral acid is possible, but diazotization in concentrated sulfuric acid (nitrosylsulfuric acid, see Sec. 2.2) or in organic solvents using an ester of nitrous acid (ethyl or isopentyl nitrite) is often preferable. Amino derivatives of aromatic heterocycles without ring nitrogen (furan and thiophene) can also be diazotized. 

Tetrazoles are a very interesting family of aromatic five-membered heterocycles for their abiUty to be a mimetic of the carboxy group with metabolic... 

In the modified procedure one of several heteroaromatic sulfones is used. The crucial role of the heterocyclic ring is to provide a nonreductive mechanism for the elimination step, which occurs by an addition-elimination mechanism that results in fragmentation to the alkene. The original example used a benzothiazole ring,279 but more recently tetrazoles have been developed for this purpose.280... 

Fused ring tetrazoles such as 96 are obtained from the reaction of nitrous acid with heterocyclic hydrazines (95) (Eq. 19).159 160 This method is also suitable for the preparation of fused ring ditetrazoles such as... 

In general, tetrazolium salts are stable in mineral acids. This stability has allowed a number of synthetic transformations such as ester and amide hydrolysis and demethylation of ethers etc.209-212 This is not the case with tetrazolium salts containing a heterocyclic substituent in the 3-position. They tend to decompose in mineral acid to the corresponding tetrazoles.230 Tetrazolyl-substituted tetrazoliums (146) and mesoionic tetrazoles, e.g., 145, are unaffected by acids.228,232... 

The compounds referred to as azolides are heterocyclic amides in which the amide nitrogen is part of an azole ring, such as imidazole, pyrazole, triazole, tetrazole, benzimidazole, benzotriazole, and their substituted derivatives. In contrast to normal amides, most of which show particularly low reactivities in such nucleophilic reactions as hydrolysis, alcoholysis, aminolysis, etc., the azolides are characterized by high reactivities in reactions with nucleophiles within the carbonyl group placing these compounds at about the same reactivity level as the corresponding acid chlorides or anhydrides. 11... 

The UV-spectra of azolides have already been discussed in the context of hydrolysis kinetics in Chapter 1. Specific infrared absorptions of azolides were mentioned there as well increased reactivity of azolides in nucleophilic reactions involving the carbonyl group is paralleled by a marked shift in the infrared absorption of the corresponding carbonyl bond toward shorter wavelength. For example, for the highly reactive N-acetyl-tetrazole this absorption is found in a frequency range (1780 cm-1) that is very unusual for amides obviously the effect is due to electron attraction by the heterocyclic sys-tem.[40] As mentioned previously in the context of hydrolysis kinetics of both imidazo-... 

More complex heterocycles have been produced by the use of tetrazoles, 121 (Equations 27 and 28) and 123 (Table 8) <2004KGS29,1999KGS343>. 

The synthesis of nitriles from halides is valuable in medicinal chemistry because nitriles are flexible building blocks readily converted into carboxylic acids, amides, amines, or a variety of heterocycles, e. g. thiazoles, oxazolidones, triazoles, and tetrazoles. The importance of the tetrazole group in medicinal chemistry is easily understood if we consider that it is the most commonly used bioisostere of the carboxyl group. 

Major advancements in the chemistry of pyrazoles, imidazoles, triazoles, tetrazoles, and related fused heterocyclic derivatives continued in 2000. Solid-phase combinatorial chemistry of pyrazoles and benzimidazoles has been particularly active. Synthetic routes to all areas continue to be pursued vigorously with improvements and applications. Notably, metal-promoted and cross-coupling reactions of all classes seemed to be a dominant theme in 2000. Applications of pyrazole-, imidazole-, and 1,2,3-benzotriazole-containing reagents to a wide array of synthetic applications remained active. 

Abstract In this chapter, selected results obtained so far on Fe(II) spin crossover compounds of 1,2,4-triazole, isoxazole and tetrazole derivatives are summarized and analysed. These materials include the only compounds known to have Fe(II)N6 spin crossover chromophores consisting of six chemically identical heterocyclic ligands. Particular attention is paid to the coordination modes for substituted 1,2,4-triazole derivatives towards Fe(II) resulting in polynuclear and mononuclear compounds exhibiting Fe(II) spin transitions. Furthermore, the physical properties of mononuclear Fe(II) isoxazole and 1-alkyl-tetrazole compounds are discussed in relation to their structures. It will also be shown that the use of a,p- and a,C0-bis(tetrazol-l-yl)alkane type ligands allowed a novel strategy towards obtaining polynuclear Fe(II) spin crossover materials. 

Only for 4-R-substituted 1,2,4-triazoles, isoxazoles and 1-alkyl-tetrazoles (Fig. 1), has the Fe(II)N6 spin crossover chromophore been found to consist of six chemically identical heterocyclic ligands. These spin transition materials are of particular interest. Since only a single N-donor ligand is involved in the synthetic procedure, the formation of mixed ligand species is avoided, and hence rather high yields are usually obtained. In addition, the choice of such relatively small heterocyclic ligands favours almost regular Oh symmetry about the Fe(II) ion. This is especially so for low-spin Fe(II). 

An intramolecular cyclization of a tetrazole-containing nucleoside 64 has been observed by Chu and co-workers <1997JOC7267> (cf. other properties of this compound in Table 3). These authors reported that the 3-OH group on the arabinofuranose ring participates in an addition reaction at position 7 of the tetrazolo[l,5-c]pyrimidine ring to form 65 which is a dihydro derivative of the parent heterocycle. The final structure elucidation has been carried out with the help of the tricyclic tandem mass spectrometry (MS/MS) fragment 66. 

Generalized valence bond interaction energies were computed for mono/poly-nitrogenous five- and six-membered heterocycles.203 Results that diverged from those obtained by other methods were obtained only for poly-nitrogenous systems such as pyridazine, benzotriazole, and tetrazole, which may confirm Bird s earlier finding123 204 that electron delocalization is not a stand-alone and direct measure of aromaticity for nitrogenous heterocyclic compounds. 

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