Alkynes, reaction with pyrrole derivatives

Alkynes substituted with one or two trifluoromethyl groups are also highly reactive dienophiles [9] Indeed, hexafluoro-2-butyne is used increasingly as a definitive acetylenic dienophile in "difficult Diels-Alder reactions. It was used, for example, to prepare novel inside-outside bicycloalkanes via its reaction with cir,trnns -l,3-undecadiene [74] (equation 67) and to do a tandem Diels-Alder reaction with a l,l-bis(pyrrole)methane [75] (equation 68) Indeed, its reactions with pyrrole derivatives and furan have been used in the syntheses of 3,4-bis(tri-fluoromethyl)pyrrole [76, 77] (equation 69) and ],4-bis(trifluoromethyl)benzene-2,3-oxide [78] (equation 70), respectively. 

Secondary thioamides, precursors of N-protonated azomethine ylids, give A1-pyrrol ine derivatives (after elimination of thiol). When the dipolarophiles are dissymmetric alkenes, high regioselectivity is obtained. Reaction with alkynes leads to pyrrole derivatives in good to excellent yields and with ArCHO leads regioselectively to 2,5-disubstituted 2-oxazolidines in moderate yields.264... 

Pyrrole derivatives are prepared by the coupling and annulation of o-iodoa-nilines with internal alkynes[291]. The 4-amino-5-iodopyrimidine 428 reacts with the TMS-substituted propargyl alcohol 429 to form the heterocondensed pyrrole 430, and the TMS is removed[292]. Similarly, the tryptophane 434 is obtained by the reaction of o-iodoaniline (431) with the internal alkyne 432 and deprotection of the coupled product 433(293]. As an alternative method, the 2,3-disubstituted indole 436 is obtained directly by the coupling of the o-alky-nyltrifluoroacetanilide 435 with aryl and alkenyl halides or triflates(294]. 

Finally, the bimolecular cycloaddition of alkynes with 2-phenylazirines in the presence of molybdenum hexacarbonyl has been studied (79TL2983). The pyrrole derivatives (294) obtained appear to arise from an initial [2 + 2] cycloaddition followed by a ring opening reaction. 

The regioselectivity observed in these reactions can be correlated with the resonance structure shown in Fig. 2. The reaction with electron-rich or electron-poor alkynes leads to intermediates which are the expected on the basis of polarity matching. In Fig. 2 is represented the reaction with an ynone leading to a metalacycle intermediate (formal [4C+2S] cycloadduct) which produces the final products after a reductive elimination and subsequent isomerisation. Also, these reactions can proceed under photochemical conditions. Thus, Campos, Rodriguez et al. reported the cycloaddition reactions of iminocarbene complexes and alkynes [57,58], alkenes [57] and heteroatom-containing double bonds to give 2Ff-pyrrole, 1-pyrroline and triazoline derivatives, respectively [59]. 

As with the reaction of pyrroles, diazoles and triazoles react with propargyl bromide to yield TV-substituted products and, depending upon the base strength, either TV-prop-2-ynylazoles or allenic derivatives are formed [30]. Generally, with potassium carbonate under soliddiquid two-phase conditions at room temperature in the absence of a solvent, the prop-2-ynyl compounds are formed as sole products, whereas with solid potassium hydroxide at elevated temperatures the allenes are obtained as the major products. Benztriazole produces a mixture of the N1- and N2-prop-2-ynyl, and N2-allenic derivatives, whereas with potassium hydroxide only the N -allenic derivative is obtained. The alkynes readily isomerize to the allenes in the presence of base and the quaternary ammonium salt, or upon treatment with methanolic sodium hydroxide. A series of l-(alk-2-ynyl)imidazoles have been prepared, as intermediates in the synthesis of imidazopyridines [31 ] and the reaction of 3-hydroxymethylpyrazoles with propargyl bromide leads to pyrazolooxazines [32]. 

Huisgen and coworkers have also described the cycloaddition behavior of the munchnones , unstable mesoionic A2-oxazolium 5-oxides with azomethine ylide character.166 Their reactions closely parallel those of the related sydnones. These mesoionic dipoles are readily prepared by cyclodehydration of N-acyl amino acids (216) with reagents such as acetic anhydride. The reaction of munchnones with alkynic dipolarophiles constitutes a pyrrole synthesis of broad scope.158-160 1,3-Dipolar cycloaddition of alkynes to the A2-oxazolium 5-oxide (217), followed by cycloreversion of carbon dioxide from the initially formed adduct (218), gives pyrrole derivative (219 Scheme 51) in good yield. Cycloaddition studies of munchnones with other dipolarophiles have resulted in practical, unique syntheses of numerous functionalized monocyclic and ring-annulated heterocycles.167-169... 

This above result was only obtained with maleimide as the dipolarophile. With dimethyl fumarate and fumaronitrile, A2-pyrrolines are obtained, probably because of the acidity of the hydrogen atoms a- to ester and nitrile functionalities. Reaction with alkynes produces pyrrole derivatives in good to excellent yields and with aromatic aldehydes leads regioselectively to oxazolidines in moderate yields.263... 

Imines react with alkynes to give pyrroles (equation 29). " A related transformation of azides has been reported by the group of Toste to afford pyrroles by an acetylenic Schmidt reaction (equation 30). " In an intermolecular-related addition, gold triazolates are obtained. The intramolecnlar hydroamination of trichloroacetimidates derived from propar-gyl and homopropargyl alcohols also proceeds with cationic An(I) as catalysts. ... 

Oxazoles represent the most widely recognized heteroaromatic azadiene capable of [4 + 2] cycloaddition reactions. The course of the oxazole Diels-Alder reaction and the facility with which it proceeds are dependent upon the dienophile structure (alkene, alkyne), the oxazole and dienophile substitution, and the reaction conditions. Alkene dienophiles provide pyridine products derived from fragmentation of the [4 + 2] cycloadducts which subsequently aromatize through a variety of reaction pathways to provide the substituted pyridines (Scheme 14). In comparison, alkyne dienophiles provide substituted fiirans that arise from the retro Diels-Alder reaction with loss of R CN from the initial [4 + 2] cycloadduct (Scheme 15,206 Representative applications of the [4 + 2] cycloaddition reactions of oxazoles are summarized in Table 14. Selected examples of additional five-membered heteroaromatic azadienes participatiitg in [4 + 2] cycloaddition reactions have been detailed and include the Diels-Alder reactions of thiazoles, - 1,3,4-oxadiazoles, isoxazoles, pyrroles and imidazoles. ... 

BusSnH-mediated intramolecular arylations of various heteroarenes such as substituted pyrroles, indoles, pyridones and imidazoles have also been reported [51]. In addition, aryl bromides, chlorides and iodides have been used as substrates in electrochemically induced radical biaryl synthesis [52]. Curran introduced [4-1-1] annulations incorporating aromatic substitution reactions with vinyl radicals for the synthesis of the core structure of various camptothecin derivatives [53]. The vinyl radicals have been generated from alkynes by radical addition reactions [53, 54]. For example, aryl radical 27, generated from the corresponding iodide or bromide, was allowed to react with phenyl isonitrile to afford imidoyl radical 28, which further reacts in a 5-exo-dig process to vinyl radical 29 (Scheme 8) [53a,b]. The vinyl radical 29 then reacts in a 1,6-cyclization followed by oxidation to the tetracycle 30. There is some evidence [55] that the homolytic aromatic substitution can also occur via initial ipso attack to afford spiro radical 31, followed by opening of this cyclo-... 

Dalla Croce and La Rosa examined the 1,3-dipolar cycloaddition reactions of unsymmetrical munchnones with terminal alkynes to give pyrroles 156 and 157 (Table 4.8). The reaction is generally regioselective the major pyrrole isomer from the monosubstituted munchnones have adjacent hydrogens, irrespective of the munchnone substituent. With the disubstituted munchnones, the major regioisomer is derived from attachment of C-4 of the munchnone and the p-carbon of the alkyne, except for phenylacetylene, which shows the opposite regiochemistry. The authors interpreted this behavior as a consequence of the electron-rich nature of phenylacetylene as a dipolarophile with a larger LUMO coefficient on the a carbon. 

In contrast to facile reactions of aryl halides with alkenes and alkynes, reactions of aromatic compounds with aryl halides have received less attention. Only intramolecular arylation of benzene derivatives, except phenols, is known [1]. On the other hand, electron-rich heterocycles such as ffirans, thiophenes, pyrroles, oxa-zoles, imidazoles, and thiazoles undergo facile inter- and intramolecular arylation with aryl halides. These are called heteroaryl Heck reactions [2]. 

To date, many electrophilic reagents, such as alkyl halides, alkenes, alkynes, carbonyl compounds, epoxides, alcohols, and ethers, have been investigated in AFC alkylation reactions. On the other hand, the reactive 5-membered heteroaromatic compounds, such as indole, pyrrole, furan, and thiophene derivatives, and electron-rich benzene derivatives have been successfully applied in AFC alkylation reactions. Indole and pyrrole derivatives are most popular substrates due to their high reactivity and account for almost 80% of the published methodologies. A variety of chiral organometal-lic catalysts and organocatalysts are employed in the catalytic AFC alkylation reactions with high enantiomeric control. 

Toste has reported a gold(I)-catalyzed protocol for the intramolecular addition of an alkyl azide to an alkyne with loss of dinitrogen (acetylenic Schmidt reaction) to form pyrrole derivatives [19]. For example, treatment of homopropargyl azide 16 with a catalytic 1 2 mixture of (dppm)Au2Cl2 (dppm = l,2-bis(diphenylphosphino)meth-ane) and AgSbFfi in methylene chloride at 35 °C led to isolation of2,5-dibutylpyrrole in 82% yield (Eq. (11.13)). The method was also effective for the cyclization of a-unsubstituted homopropargyl azides and tolerated both alkyl and aryl substitution of the alkyne. 

Transmetallation of 1-6 or treatment of 1-6 with Lewis acid further broadens the scope of its reaction chemistry. In the presence of CuCl, the reaction of 1-6 with diazo dicarboxylate affords pyridazine derivatives [27]. In the presence of CuCl or nickel complexes, the reaction of 1-6 with alkynes leads to benzene derivatives [28, 29]. Transmetallation of 1-6 with Bids allows further reaction with 2-oxo malonate to give 2/7-pyran derivatives [27]. Transmetallation of 1-6 with CrCls followed by reaction with isocyanates affords pyridine derivatives [30]. Transmetallation of 1-6 with AICI3 followed by reaction with aldehydes affords pentasubstimted cyclo-pentadiene derivatives [31]. Under the similar condition, 1-6 reacts with nitroso compounds to form pyrrole derivatives [32]. Addition of n-butyl lithium activates 1-6 and allows further reaction with carbon monoxide, which leads to carbonylation and affords 2-cyclopentenone upon hydrolysis [33]. 

An extensive review of the synthesis of a wide variety of five-membered heterocyclic compounds, via the formal 3-1-2-cycloaddition reactions of aziridines with alkenes, alkynes, nitriles, carbonyl groups, and heterocumulenes, has been presented." Supercritical CO2 has been used as the solvent in the formal 3-1-2-cycloaddition reactions of A-benzyl- and A-cyclohexyl-2-benzoyl-3-phenylaziridines with allenoates to yield pyrrole derivatives." The Lewis acid-catalysed intramolecular formal 3-1-2-cycloaddition reactions of 2-methyleneaziridines with tethered alkenes or alkynes (23) yielded cw-octahydrocyclopenta[c]pyrroles (24) after reductive workup. The reaction mechanism proceeds in a stepwise manner via a 2-aminoallyl cation (Scheme The Cu(I)/DTBM-Segphos-catalysed 1,3-dipolar cycloaddition reactions of a-silylimines and activated alkenes yielded highly enriched 5-unsubstituted a-quaternary proline cycloadducts with excellent diastereo- and enantio-selectivities (73-99% The... 

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