Thermal intramolecular

Tricyclic 84 was prepared [91JCS(P1)1762] by the thermal intramolecular rearrangement of dichloro(pyrrolidinylcycloheptenyl)triazine 83. Its structure was confirmed by X-ray crystallography (Scheme 21). 

A sequence of two thermal intramolecular cycloadditions has been used to develop a short synthetic approach to tetrahydrothiopyrans [122], The multiple process includes an m m-hetero- and an intramolecular-carbon Diels-Alder reaction. An intramolecular /zctcro-Diels-Alder reaction of divinyl-thioketone 134 afforded a 9 1 mixture of cycloadducts 135 and 136 which then underwent a second intramolecular cycloaddition which syn o H-2)-exo-diastereoselectively led to hexacyclic tetrahydrothiopyrans 137 and 138, respectively (Scheme 2.51). 

The Alder-ene reaction has traditionally been performed under thermal conditions—generally at temperatures in excess of 200 °C. Transition metal catalysis not only maintains the attractive atom-economical feature of the Alder-ene reaction, but also allows for regiocontrol and, in many cases, stereoselectivity. A multitude of transition metal complexes has shown the ability to catalyze the intramolecular Alder-ene reaction. Each possesses a unique reactivity that is reflected in the diversity of carbocyclic and heterocyclic products accessible via the transition metal-catalyzed intramolecular Alder-ene reaction. Presumably for these reasons, investigation of the thermal Alder-ene reaction seems to have stopped almost completely. For example, more than 40 papers pertaining to the transition metal-catalyzed intramolecular Alder-ene reaction have been published over the last decade. In the process of writing this review, we encountered only three recent examples of the thermal intramolecular Alder-ene reaction, two of which were applications to the synthesis of biologically relevant compounds (see Section 10.12.6). 

Thermal intramolecular [2 + 2]-cydoadditions of phenylsulfonyl-substituted allenes 33 gave 34 stereoselectively. An initial carbon-carbon bond formation occurred at the central allenic carbon and the proximal olefmic carbon. The resulting non-allylic radical 35 is unstable and cyclizes rapidly which may account for the high stereoselectivity [30]. 

A thermal intramolecular allene 1,2-diazine Diels-Alder reaction proceeded at 160 °C to afford indole derivatives [158],... 

Although thermal [2 + 2] cycloadditions are forbidden as concerted reactions by the orbital symmetry conservation rules the same structural features which promote intermolecular cy-cioadditions will also promote intramolecular reactions. In addition, the proximity between two alkene moieties dictated by the tether length and rigidity would make these processes entropically favorable. A few reports have documented thermal intramolecular cycloadditions to cyclopropenes and activated alkenes. The thermal Cope rearrangement of allylcyclopropenes apparently proceeds by a two-step mechanism in which intramolecular [2 + 2] adducts have been observed.72-73... 

Bisacryloylimides 7 undergo thermal intramolecular cycloadditions giving either head-to-head or head-to-tail cyclobutanes 8 or 9, respectively, depending on the substituent at the double... 

A thermal intramolecular [2 + 2] cycloaddition between an electrophilic allene and a conjugated diene has been reported for substrates 40 and 42.27,28 Interestingly, the analog of 40 without the methyl group gives the [4 + 2] product. 

Further research on this subject was recently reported, in relation to the use of dienynes as substrates for intramolecular cycloaddition. While thermal intramolecular [4+2] cycloadditions of enynes with alkenes only took place at high temperatures, the gold(I) catalyzed transformations provided bi- or tri-cyclic ring systems under mild conditions [152]. 

The photoconversion of spiro[benzofuran-2,r-cyclohexa-3, 5 -diene]-2, 3(2//)-diones to dibenzofurans is recorded (81JCS(Pi)870). It was proposed that excitation of the dienone chromophore of the grisedienone (401) causes either concerted or radical ring opening to pairs of stereoisomeric dienylketenes. One member of each pair can undergo a thermal intramolecular va + tts cyclization to yield a /3-lactone subsequent loss of C02 would yield the products. 

The thermal intramolecular 2 + 2-cycloaddition of 4,4,-disubstituted-2,2/-bis(phenyl-ethynyl)biphenyls (1) yielded the intermediate l,2-diphenylcyclobuta[l]phenanthrenes (2), which could be trapped with 2,3,4,5-tetraphenylcyclopenta-2,4-dione (3) to produce the Diels-Alder adduct (4). Thermal decarbonylative ring opening of (4) gave 9,10,11,12,13,14-hexaphenylcycloocta[l]phenanthrenes (5) as the final product in 12-23% yield (Scheme l).1... 

Alkynes are poor dienophiles in the Diels- Alder reaction decomposition occurs by an attempted thermal intramolecular Diels-Alder reaction of dienynes at 160 °C. In contrast, the Ni-catalysed [4+2] cycloaddition of the dienyne 50 proceeded smoothly at room temperature using tri(hexafluoro)isopropyl phosphite to give 51, which was converted to the yohimbine skeleton 52 [15]. The same reaction is catalysed by RhCl(Ph3P)3 in trifluoroethanol [16]. Intramolecular Diels-Alder reactions of the 6,8-dieneyne 53 and the 1,3,8-triene 55, efficiently catalysed by [Rh(dppe)(CH2CH2)2]SbF6 at room temperature, gave 54 and 56 [17],... 

Diphenyl-3-[3-(2-phenylimidazol-l-yl)propyl]-l,2,4-triazine (70) underwent thermal intramolecular addition (with loss of nitrogen) to give the tricyclic intermediate (71) and thence (by loss of benzonitrile) 2,3-diphenyl-5,6,7,8-tetrahydro-l,5-naphthyridine (72) [substrate, antioxidant (2,6-di-terf-butyl-4-methylphenol), l,3,5-Pr 3C6H3, reflux, 3 h 92%] that could be aromatized to 2,3-diphenyl-1,5-naphthyridine (73) (l,3,5-Pr 3C6H3, reflux, air, 24h 91%) the latter product (73) was also made directly from the triazine (70) (neat substrate, Se, 330°C, 10 h 85%) analogs likewise.137,522... 

In general, the addition is sensitive to steric factors and the approach geometry is such that interactions are minimised, while the regiochemistry may again be explained in terms of the formation of the more stable biradical intermediate. In other cases a thermal intramolecular addition occurs, eg.107 b) ... 

A complementary access to extended indole and carbazole systems is based on the thermal intramolecular benzannulation of ortfio-al kyn ylan i 1 i nocarbene complexes or on a photo-induced benzannulation of phenylpyrrolylcarbene complexes. The first example involves an intramolecular access to the carbazole skeleton. Refluxing a solution of orflio-alkyn yl phen yl amino carbene complex 109 in acetonitrile gave a 63 % yield of benzocarbazole 110. Less strongly coordinating solvents (TBME, THF, or di-n-butyl ether) or other substituents less bulky than 2,4,6-trimethylphenyl (for example, phenyl or 4-methylphenyl) led to a considerably reduced yield (Scheme 39) [83]. 

A new synthesis of ( )-actinidine has been reported it is interesting in that it has, as its key step, the thermal intramolecular cycloaddition of an acetylenic pyrimidine.34 A further synthesis of ( )-muscopyridine, based on a regioselective cyclopentenone annulation, has been described.35... 

Tetrahydroalstonine 7-7, a heteroyohimboid alkaloid, has been synthesised in enantiopure form by Martin et al. by means of an oxa Diels-Alder reaction as key step. The trienic precursor 7-5 underwent a thermal intramolecular cycloaddition to form a 5 1 mixture of 7-6 and its 15/J-epimer. The main cycloadduct was then subjected to a straightforward sequence to yield the natural product 7-7 (Fig. 7-2) [483-485]. In earlier work, Ogasawara et al. have employed a con-ceptionally different domino Knoevenagel-hetero Diels-Alder approach to this alkaloid and other natural products [486-488]. 

Reaction of l,3-benzoxazin-4-ones (43, 44) or trithioisatoic anhydride (45) with amidrazones (46, 47) or thiosemicarbazide (48) resulted in the formation of 3-(l-amidino)- (49-51) and 3-(l-thioureido)pyrimidines (52) respectively. Compounds 49-52 underwent thermal intramolecular cyclization to the corresponding l,2,4-triazolo[l,5-c]quinazolines (53-56) [68CB2106 76MI1 80PHA582 83MI1 85H(23)2357] (Scheme 18). 

There are only few known ring-contraction reactions of heterocines with three heteroatoms. They lead to more favorable smaller ring systems or to bicyclic or bridged products of transannular transformations. Examples of analogous photo- and thermal intramolecular transformations are discussed in Section 14.08.5.1. 

Imidoyl isothiocyanates 74 are readily available through stepwise nucleophilic substitution of iV-phenyl(phenyl-imino)methylchloromethanimidoyl chloride with secondary amines and potassium thiocyanate. Subsequent thermal intramolecular cyclization of intermediates 74 affords substituted 1,3,5-benzotriazocine derivatives 75 (Equation 8 <2005ARK96>). 

Thermal intramolecular cycloaddition reactions of unsaturated nitrones 1341 derived from a series of N- 2-alkenyl)-2-pyrrolecarbaldehydes 1340 and benzylhydroxylamine lead to competitive formation of two kinds of intramolecular cycloadducts, namely the fused- and the bridged-ring regioisomers 1342 and 1343, respectively (Scheme 255) <2001T8323>. Further elaboration of compounds 1342 and 1343 has given pyrrolizidine and indolizidine derivatives, respectively. A similar regiochemical trend was observed when aldehydes 1340 were reacted with (/ )-a-methylbenzylhydroxylamine in order to synthesize optically active compounds. 

Coverage in this chapter is restricted to the use of alkenes or alkynes as enophiles (equation 1 X = Y = C) and to the use of ene components in which a hydrogen is transferred. Coverage in Sections 1.2 and 1.3 is restricted to ene components in which all three heavy atoms are carbon (equation 1 Z = C). Thermal intramolecular ene reactions of enols (equation 1 Z = O) with unactivated alkenes are presented in Section 1.4. Metallo-ene reactions are covered in the following chapter. Use of carbonyl compounds as enophiles, which can be considered as a subset of the Prins reaction, is covered in depth in Volume 2, Chtqiter 2.1. Addition of enophiles to vinylsilanes and allylsilanes is covered in Volume 2, Chapter 2.2, while addition of enophiles to enol ethers is covered in Volume 2, Chapters 2.3-2.S. Addition of imines and iminium compounds to alkenes is presented in Volume 2, Part 4. Use of alkenes, aldehydes and acetals as initiators for polyene cyclizations is covered in Volume 3, Chapter 1.9. Coverage of singlet oxygen, azo, nitroso, S=N, S=0, Se=N or Se=0 enophiles are excluded since these reactions do not result in the formation of a carbon-carbon bond. 

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