Thiophene ring intramolecular

It is estimated that thiophene reacts with phenyl radicals approximately three times as fast as benzene. Intramolecular radical attack on furan and thiophene rings occurs when oxime derivatives of type (112) are treated with persulfate (8UCS(Pt)984). It has been found that intramolecular homolytic alkylation occurs with equal facility at the 2- and 3-positions of the thiophene nucleus whereas intermolecular homolytic substitution occurs mainly at position 2. 

An alternative approach to thienothienopyridines involves intramolecular electrophilic attack at C-3 of the thiophene ring. In this way, the thienothiophene 82 can be cyclized to the benzothieno[2,3-/]thieno[2,3-c]pyridine 83 upon treatment with polyphosphoric acid (PPA) at 150°C (Equation 3). Similarly, treatment of the amide 84 with POCI3 gives the corresponding 1-alkyl-3,4-dihydro-benzothieno[3,2-g]thieno[3,2-f]pyridine 85 <1999PS(153)401> (Equation 4). 

The electron-rich thiophene ring system can be elaborated into complex, fused thiophenes by acid-mediated intramolecular annelation reactions. For example, treatment of alcohol 96 with trimethylsilyl triflate promoted a Friedel-Crafts acylation and subsequent dehydration giving benzo[b]thiophene 97, a potential analgesic <00JMC765>. Treatment of ketone 98 with p-toluenesulfonic acid resulted in the formation of fused benzo[b]thiophene 99 <00T8153>. Another variant involved the cyclization of epoxide 100 to fused benzo[f>]thiophene 101 mediated by boron trifluoride-etherate . 

Cyclometallation of thiophene imine 110 with platinum complex 111 proceeded to give metallacycle 112 via an intramolecular C-H insertion on the thiophene ring . 

The thiophene ring system can be utilized as a synthetic scaffold for the preparation of nonthiophene materials as the sulfur moiety can be removed by reduction (desulfurization) or extrusion (loss of SO2). The extrusion of sulfur dioxide from 3-sulfolenes (2,5-dihydrothiophene 1,1-dioxides) give dienes (butadienes or o-quinodimethanes) that can be utilized to prepare six-membered rings by cycloaddition chemistry. For example, thermolysis of 3-sulfolene 120 provided tricyclic pyrazole 122 via an intramolecular cycloaddition of the o-quinodimethane 121 that results by extrusion of sulfur dioxide <00JOC5760>. Syntheses of 3-sulfolenes 123 and 124 <00S507> have recently been reported. 

Litvinov et prepared selenophenothiophenes 14 and 15 according to Schemes 13 and 14 by inserting two functional groups into the thiophene ring, using lithiation methods, followed by intramolecular condensation of an acetic ester residue. The intermediates from the first three steps need not be isolated. 

An attractive approach toward the preparation of polycyclic systems containing a thiophene ring involves the intramolecular [3 - - 2] cycloaddition of thiocarbonyl ylides. A number of representative examples were reported using mesoionic compounds. Gotthardt et al. (151) used l,3-dithiolium-4-olates such as 89 bearing an olefinic side chain. Upon heating to 120 °C in xylene, the polycyclic tetrahy-drothiophene 90 was formed (Scheme 5.33). 

The analogue 269 reacted via a remarkable intramolecular cycloaddition to the thiophene ring to give 270 as the primary product, which was then partially consumed by intermolecular cycloadditions of 269 to both the pyrazole C=N and the residual thiophene C=C to give 271 and 272, respectively (166,167). 

A novel route to 2,3-dihydrothiophenes involved a titanocene-promoted carbene formation and subsequenct intramolecular cyclization onto a thiol ester <99SL1029>. Treatment of thioacetal 9 with the low-valent titanium complex 10 gave 2,3-dihydrothiophene 12 by intramolecular olefination of the thiol ester of titanium-carbene intermediate 11. Another metal-mediated cyclization onto the thiophene ring system involved the palladium-catalyzed cyclization of 1,6-diynes <99T485>. For example, treatment of thioether 1,6-diyne 13 with Pdlj in the presence of CO and Oj in methanol followed by treatment with base gave 14. 

The electron-rich thiophene ring system can be annelated by intramolecular Friedel-Crafts acylation reactions to give fused thiophenes <99IJC648, 99JMC2774>. The synthesis of a thiophene isostere of ninhydrin involved an intramolecular Friedel-Crafts acylation <99SL1450>. Specifically, treatment of thiophene 86 with thionyl chloride followed by aluminum chloride gave annelated thiophene 87. The synthesis of isothianinhydrin 88 was then accomplished in six steps from 87. 

Benzene and thiophene rings can of course often be interchanged in biologically active agents. The very broad structural latitude consistent with NSAID activity is by now a familiar theme as well. Preparation of the fused thiophene counterpart of the NSAID piroxicam (Chapter 11) starts with the reaction of thiophene (25-1), itself the product of a multistep sequence, with ethyl A-methylglycinate to give the sulfonamide (25-2). Treatment of that intermediate with a base leads to intramolecular Claisen condensation and thus the formation of the 3-ketoester (25-3). An amide-ester interchange with 2-aminopyridme (25-4) completes the synthesis of tenoxicam (25-5) [25]. 

Intramolecular diazo coupling can be also achieved <85JCS(Pl)l3l). Starting from suitable (o-aminophenyl)thiophenes various isomeric thieno[c]cinnolines have been obtained (Scheme 24). The reaction can proceed either at an a- or at (3-position of the thiophene ring. 

In intramolecular reactions, direct interaction with the thiophene ring is possible by appropriate positioning of the tether as shown for the 3-substituted thiophene (229), which resulted in alkylation to form (230) and (231) (equation 46).)6la In contrast, the rhodium(II) acetate catalyzed decomposition of the 2-... 

Radical methods have found limited application in the synthesis of sulfur heterocycles. A tandem tosyl radical addition and intramolecular trapping by a thiophene ring has been investigated [95SL763], Cyclization under sonication or thermal conditions gave the thiophene in 77-81% chemical yield. 

The molecule 42 is located on an inversion center and appears to be essentially planar, the dihedral angle between the two independent thiophene rings amounting to 2.5(5)°. One interesting feature is the short intramolecular S(l)-S(2) distance (3.066(5) A) when compared with the Van der Waals distance (S-S 3.7 A), indicating a degree of delocalization between the two sulfur atoms, as already postulated in various molecules with the same 1,5-sulfur-sulfur interaction where S-S distances around 3 A were observed <1996JOC6997>. 

This approach to the thiophene ring seems most direct and involves (1) intramolecular nucleophilic addition of thiol, thiolate, and dithiocarboxylate sulfurs and, in a rare case, sulfide sulfur to sp and sp carbons (2) electrophilic attack of sulfenium and sulfonium ions and their equivalents on unsaturated carbon-carbon bonds (3) addition of thiyl radicals to unsaturated carbon-carbon bonds (4) addition of vinyl and aryl radicals to the sulfur atom of sulfides and (5) electrophilic attack of a carbocation on the sulfur atom of sulfides. 

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