Microwave irradiation heterocycle synthesis

Dave, C.G. and Shah, R.D., Gould-jacob type of reaction in the synthesis of thieno[3,2-e]pyrimido [ 1,2-c ]pyrimidines a comparison of classical heating vs solvent-free microwave irradiation, Heterocycles, 1999,51, 1819-1826. 

Microwave and fluorous technologies have been combined in the solution phase parallel synthesis of 3-aminoimidazo[l,2-a]pyridines and -pyrazines [63]. The three-component condensation of a perfluorooctane-sulfonyl (Rfs = CgFiy) substituted benzaldehyde by microwave irradiation in a single-mode instrument at 150 °C for 10 min in CH2CI2 - MeOH in the presence of Sc(OTf)3 gave the imidazo-annulated heterocycles that could be purified by fluorous solid phase extraction (Scheme 9). Subsequent Pd-catalyzed cross-coupling reactions of the fluorous sulfonates with arylboronic acids or thiols gave biaryls or aryl sulfides, respectively, albeit it in relatively low yields. 

A number of new MCRs, that are either facilitated or accelerated by microwave irradiation, have been reported recently for the synthesis of simple N-, 0- and S-containing heterocycles. These one-pot domino processes offer... 

Fewer procedures have been explored recently for the synthesis of simple six-membered heterocycles by microwave-assisted MCRs. Libraries of 3,5,6-trisubstituted 2-pyridones have been prepared by the rapid solution phase three-component condensation of CH-acidic carbonyl compounds 44, NJ -dimethylformamide dimethyl acetal 45 and methylene active nitriles 47 imder microwave irradiation [77]. In this one-pot, two-step process for the synthesis of simple pyridones, initial condensation between 44 and 45 under solvent-free conditions was facilitated in 5 -10 min at either ambient temperature or 100 ° C by microwave irradiation, depending upon the CH-acidic carbonyl compound 44 used, to give enamine intermediate 46 (Scheme 19). Addition of the nitrile 47 and catalytic piperidine, and irradiation at 100 °C for 5 min, gave a library of 2-pyridones 48 in reasonable overall yield and high individual purities. 

Despite that the thiophene ring is considered as a bioisoster of the benzene ring, the synthesis and chemistry of thiophene analogs of heterocycles with therapeutic interest remain poorly studied. One of the most recent examples concerns the synthesis of new substituted thioisatoic anhydrides (6 and 7-arylthieno[3,2-d] [1,3]oxazine-2,4-diones), which were prepared on a large scale under microwave irradiation conditions. A small library of thiophene ureidoacids was easily performed using a Normatron microwave reactor (500 W) with high yields and good purity [4,5] (Scheme 4). 

Synthesis of Heterocycles Using Polymer-Supported Reagents under Microwave Irradiation... 

Abstract Controlled microwave heating has foimd many important applications in the synthesis of heterocycles. Almost all kinds of heterocycles have been prepared (or their preparation attempted) with the aid of microwaves. Many examples of cyclocondensations, reactions where two or more fimctional groups combine with the loss of another small molecule (usually water), have been described. Moreover, microwave irradiation successfully induces cycloaddition reactions, especially in the cases where high temperatures are required. This review collects the most representative examples of the application of microwaves to these two kinds of transformations. Except for a few examples, all the reactions selected have been carried out imder controlled microwave irradiation using dedicated instruments. 

The Pictet-Spengler reaction has mainly been investigated as a potential source of polycyclic heterocycles for combinatorial apphcations or in natural product synthesis [149]. Tryptophan or differently substituted tryptamines are the preferred substrates in a cyclocondensation that involves also aldehydes or activated ketones in the presence of an acid catalyst. Several versions of microwave-assisted Pictet-Spengler reactions have been reported in the hter-ature. Microwave irradiation allowed the use of mild Lewis acid catalysts such as Sc(OTf)3 in the reaction of tryptophan methyl esters 234 with different substituted aldehydes (aliphatic or aromatic) [150]. Under these conditions the reaction was carried out in a one-pot process without initial formation of the imine (Scheme 86). 

Crosignani S, Linclau B (2006) Synthesis of Heterocycles Using Polymer-Supported Reagents under Microwave Irradiation. I 129-154... 

A simple two-step synthesis of 5H-alkyl-2-phenyloxazol-4-ones has been reported by Trost and coworkers (Scheme 6.209) [377]. a-Bromo acid halides were condensed with benzamide in the presence of pyridine base at 60 °C to form the corresponding imides. Microwave irradiation of the imide intermediates in N,N-dimethylacetamide (DMA) containing sodium fluoride at 180 °C for 10 min provided the desired 5H-alkyl-2-phenyloxazol-4-ones (oxalactims) in yields of 44—82%. This class of heterocycles served as excellent precursors for the asymmetric synthesis of a-hydroxycar-boxylic acid derivatives [377]. 

A method for microwave-assisted transesterifications has been described by Van-den Eynde and Rutot [73], The authors investigated the microwave-mediated deriva-tization of poly(styrene-co-allyl alcohol) as a key step in the polymer-assisted synthesis of heterocycles. Several /i-ketoesters were employed in this procedure and multigram quantities of products were obtained when neat mixtures of the reagents in open vessels were subjected to microwave irradiation utilizing a domestic micro-wave oven (Scheme 7.65). The successful derivatization of the polymer was confirmed by IR, 1H NMR, and 13C NMR spectroscopic analyses. The soluble supports... 

The synthesis of biologically significant fluorinated heterocyclic compounds has been accomplished by 1,3-dipolar cycloaddition of nitrones to fluorinated dipolarophiles [51], This reaction was noticeably improved under solvent-free conditions and using microwave irradiation (Eq. (8) and Tab. 3.5). 

This chapter will deal with applications of microwave irradiation in the synthesis of heterocycles by a variety of means, excluding cycloadditions, which will be described in the next chapter. We have chosen to report first reactions in solution in organic solvents, then heterogeneous reactions without solvent under a variety of conditions, and finally to deal with emerging techniques which employ ionic liquids. 

The purpose of this section is to highlight the applications of microwave irradiation to multistep synthesis of polyheterocyclic systems with potent pharmaceutical value. When conventional thermal procedures (metal or oil bath) fail, and irrespective of the conditions needed in the homogeneous phase, microwave irradiation can be used as an alternative to classical methods enabling development of easy and rapid access to new heterocycles. 

These examples of the use of microwave irradiation in the synthesis of heterocyclic compounds show the great versatility of this technique, which can be used under a variety of experimental conditions. Even when there is no improvement of yields, or rates, or specificity, the technique is worthwhile owing to its simplicity. It can be foreseen that microwave ovens are going to be among the basic equipment of research laboratories in the near future. Combinatorial and parallel synthesis under the action of microwave irradiation is becoming a powerful tool for discovery of new molecules and should develop very rapidly. 

The hetero-Diels-Alder reaction is one of the most important methods of synthesis of heterocycles, yet as a potentially powerful synthetic tool it has found relatively little general use. Microwave irradiation has been used to improve reactions involving heterodienophiles and heterodienes of low reactivity. 

An 8000-member library of trisamino- and aminooxy-l,3,5-triazines has been prepared by use of highly effective, microwave-assisted nucleophilic substitution of polypropylene (PP) or cellulose membrane-bound monochlorotriazines. The key step relied on the microwave-promoted substitution of the chlorine atom in monochlorotriazines (Scheme 12.7) [35]. Whereas the conventional procedure required relatively harsh conditions such as 80 °C for 5 h or very long reaction times (4 days), all substitution reactions were found to proceed within 6 min, with both amines and solutions of cesium salts of phenols, and use of microwave irradiation in a domestic oven under atmospheric reaction conditions. The reactions were conducted by applying a SPOT-synthesis technique [36] on 18 x 26 cm cellulose membranes leading to a spatially addressed parallel assembly of the desired triazines after cleavage with TFA vapor. This concept was later also extended to other halogenated heterocycles, such as 2,4,6-trichloropyrimidine, 4,6-dichloro-5-nitropyrimidine, and 2,6,8-trichloro-7-methylpurine, and applied to the synthesis of macrocyclic peptidomimetics [37]. 

Microwave-mediated transesterification of commercially available neat poly(styr-ene-co-allyl alcohol) with ethyl 3-oxobutanoate, ethyl 3-phenyl-3-oxopropanoate, and diethyl malonate provided the desired polymer-supported /i-dicarbonyl compounds (Scheme 12.18) [65]. Multigram quantities of these interesting building blocks for heterocycle synthesis were obtained simply by exposing the neat mixture of reagents to microwave irradiation in a domestic microwave oven for 10 min. 

In another article, however, [59] it was shown that in the most case this reaction gave mixtures of two heterocycles 53 and 54. To develop procedures allowing regioselective synthesis of both heterocyclic systems, the authors of [59] studied an influence of temperature regime and catalyst type on the direction of this MCR. With application of ultrasonication and microwave irradiation it was estabhshed that the reaction studied can pass under kinetic and thermodynamic control. 

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