Aryl compounds cycloaddition reactions

A large number of pyridazines are synthetically available from [44-2] cycloaddition reactions. In one general method, azo or diazo compounds are used as dienophiles, and a second approach is based on the reaction between 1,2,4,5-tetrazines and various unsaturated compounds. The most useful azo dienophile is a dialkyl azodicarboxylate which reacts with appropriate dienes to give reduced pyridazines and cinnolines (Scheme 89). With highly substituted dienes the normal cycloaddition reaction is prevented, and, if the ethylenic group in styrenes is substituted with aryl groups, indoles are formed preferentially. The cycloadduct with 2,3-pentadienal acetal is a tetrahydropyridazine derivative which has been used for the preparation of 2,5-diamino-2,5-dideoxyribose (80LA1307). 

The cycloaddition reaction of compound 6 with N-aryl- and N-aralkylazides 23 was also investigated (967(52)7183). Thiadiazabicyclo[3.1.0]hexene derivatives 25 were obtained from the labile triazoline intermediate 24 through nitrogen elimination. This bicyclic system underwent thermal transformation, producing thiadiazine dioxides 26 as the main product together with thiazete dioxides 27 and pyrazoles 28. 

Aryl- and alkenylcarbene complexes are known to react with alkynes through a [3C+2S+1C0] cycloaddition reaction to produce benzannulated compounds. This reaction, known as the Dotz reaction , is widely reviewed in Chap. Chromium-Templated Benzannulation Reactions , p. 123 of this book. However, simple alkyl-substituted carbene complexes react with excess of an alkyne (or with diynes) to produce a different benzannulated product which incorporates in its structure two molecules of the alkyne, a carbon monoxide ligand and the carbene carbon [128]. As referred to before, this [2S+2SH-1C+1C0] cycloaddition reaction can be carried out with diyne derivatives, showing these reactions give better yields than the corresponding intermolecular version (Scheme 80). 

It has been shown that cross-coupling reactions constitute a very mild method to introduce different alkyl and aryl groups to the most active C-3 position of the pyrazinone ring [26]. The broadly functionahzed 2-azadiene system of the title compounds was studied in cycloaddition reactions with various electron-reach and electron-poor dienophiles to provide highly substituted heterocycles [24]. 

The 3-oxo-2-pyrazolidinium ylides 315, easily available by reaction of the corresponding pyrazolidin-3-one with aromatic aldehydes, function as 1,3-dipoles in cycloaddition reactions with suitable alkenes and alkynes to provide the corresponding products. When unsymmetrical alkynes are used, mixtures of both possible products 316 and 317 are usually obtained (Equation 45). The regioselectivity of cycloadditions of the reaction with methyl propiolate is influenced by the substituents on the aryl residue using several 2,6-di- and 2,4,6-trisubstituted phenyl derivatives only compound 316 is formed <2001HCA146>. Analogous reactions of 3-thioxo-l,2-pyrazolidinium ylides have also been described <1994H(38)2171>. 

A cycloreversion mechanism is suggested for the transformation of the nonisolable cycloadduct 90 to the aldehyde 91 and isothiocyanate 92 <1996BCJ719> and for the spiro-1,4,2-oxathiazole intermediates 94 to the dioxothiazoline 95 and the aryl isothiocyanate 92 <2001MOL510>. Both cycloadducts are obtained by cycloaddition reactions of nitrile oxides 88 to thiocarbonyl compounds (Scheme 12). 

The extremely sterically hindered 1,2,4-diazaphospholes 139-142 were prepared via [2+3] cycloaddition reaction of 2-(2,4,6-tri-/,< +-butylphenyl)-l-phosphaethyne 138 with trimethylsilyldiazomethane derivatives (Scheme 11). Structures of 1,2,4-diazaphospholes 140 and 142 were investigated by NMR spectroscopy and X-ray diffraction. The experimental structural studies as well as theoretical calculations confirmed aromatic character of these 1,2,4-diazaphospholes. The crystal structure of compounds 140 and 142 showed remarkable hydrogen bonding character in relation to molecular aggregation due to the presence of the bulky aryl groups <2007EJI3491>. 

Diazo compounds have also been used as precursors in the preparation of pyrazoles and indazoles. The copper-promoted cycloaddition reaction of lithium acetylides 18 with diazocarbonyl compounds 19 provided a direct and efficient approach to the synthesis of pyrazoles 20 <07AG(I)3242>. A facile, efficient, and general method for the synthesis of 1-arylated indazoles 22 and A-unsubstituted indazoles 23 by the 1,3-dipolar cycloaddition of benzynes, generated from 21, with diazomethane derivatives has been reported <07AG(I)3323>. Reaction of diazo(trimethylsilyl)methylmagnesium bromide with aldehydes or ketones gave 2-diazo-2-(trimethylsilyl)ethanols, which were applied to the synthesis of di- and trisubstituted pyrazoles via [3+2] cycloaddition reaction with ethyl propiolate or dimethyl acetylenedicarboxylate <07S3371>. 

Indene can participate as the cne component in [4 + 2] and [2 + 2] cycloaddition reactions with diazene dicarboxylates and triazolediones. Aryl-substituted alkenes, however, can participate as the diene components in cycloaddition reactions with the same diazene compounds, although the reaction can follow different pathways depending on the nature of the substituents on the vinyl and phenyl groups. 

The previous cycloaddition reaction discussed is believed to proceed through an aldimine anion (19). Such delocalized anions can also be generated by treatment of suitable aldimines with a strong base. Subsequent cyclocondensation with a nitrile produces imidazoles [25-28]. The 2-azaallyl lithium compounds (19) are made by treatment of an azomethine with lithium diiso-propylamide in THF-hexane ( 5 1) (Scheme 4.2.9) [29. To stirred solutions of (19) one adds an equimolar amount of a nitrile in THF at —60°C. Products are obtained after hydrolysis with water (see also Section 2.3). If the original Schiff base is disubstituted on carbon, the product can only be a 3-imidazoline, but anions (19) eliminate lithium hydride to give aromatic products (20) in 37-52% yields (Scheme 4.2.9). It is, however, not possible to make delocalized anions (19) with R = alkyl, and aliphatic nitriles react only veiy reluctantly. Examples of (20) (Ar, R, R, yield listed) include Ph, Ph, Ph, 52% Ph, Ph, m-MeCeUi, 50% Ph, Ph, p-MeCeUi, 52% Ph, Ph, 3-pyridyl, 47% Ph, Ph, nPr, 1% [25]. Closely related is the synthesis of tetrasubstituted imidazoles (22) by regioselective deprotonation of (21) and subsequent reaction with an aryl nitrile. Even belter yields and reactivity are observed when one equivalent of potassium t-butoxide is added to the preformed monolithio anion of (21) (Scheme 4.2.9) [30]. 

The course of the intramolecular photoreaction of carbonyl compounds with electron-rich alkenyl- or aryl-substituents in the side-chain is dictated essentially by the thermodynamics of the electron-transfer step. This relationship has been intensively studied for phthalimides. When AG°et is positive, [n 2 + 2] cycloaddition reactions were observed with alkenyl substituents and classical Norrish II chemistry for aryl-substituted substrates. When AG°et was negative, electron transfer prod-... 

Reaction of the Cp-amidinato imido titanium complexes Cp Ti[MeC(NPr1)2](NR) (R = But, 2,6-C6H3Me2) with C02 proceed via initial cycloaddition reactions to give N-O-carbamato complexes. The Buc derivative does not react with an excess of C02 and it undergoes a retrocyclization process with the formation of BuNCO and the binuclear fi-oxo compound Cp Ti[MeC(NPr1)2] 2(/i-0). The aryl derivatives exhibit a double CO2 insertion process to give Cp Ti[MeC(NPri)2][0(C0)N(Ar)(C0)0] (Scheme 248).661... 

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