Heterocycles from cycloaddition reactions

Scheme 2.7 Formation of heterocycles from cycloaddition reactions of R2Si=SiR2-...

The nitrene 28 is not produced from the azide precursor, but from heterocycles via photolysis and thermolysis as shown in Sch. 11 [20]. Iminoacyl nitrenes react intramolecularly giving benzimidazoles with good yields (Sch. 11), and, dependending on the precursor used and the reaction conditions, varying amounts of carbodiimides are obtained. The reactivity of the acyl nitrenes is influenced by the substituent connected to the acyl group (see Sch. 10), however all acyl nitrenes are quite reactive and therefore rather unselective. Apart from cycloaddition reactions with Tt-bonds, insertion reactions into a-bonds, additions to lone pair electrons of... 

Treatment of acyl chlorides with pyridine and trifluoroacetic anhydride (TFAA) was assumed to involve generation of ketenes which can be subjected to electrophiUc attack by TFAA to afford jd-trifluoroacetylacetic acid derivatives 484. Quenching of the reactions with dienophiles resulted in construction of heterocycles 485 that clearly result from cycloaddition reactions of intermediate acylketenes generated by ehmination from 484 (Scheme 155) (1992TL1285, 1995T2573, 1995T2585). 

In theory, three isoxazolines are capable of existence 2-isoxazoline (2), 3-isoxazoline and 4-isoxazoline. The position of the double bond may also be designated by the use of the prefix A with an appropriate numerical superscript. Of these only the 2-isoxazolines have been investigated in any detail. The preparation of the first isoxazoline, 3,5-diphenyl-2-isoxazoline, from the reaction of )3-chloro-)3-phenylpropiophenone with hydroxylamine was reported in 1895 (1895CB957). Two major syntheses of 2-isoxazolines are the cycloaddition of nitrile A-oxides to alkenes and the reaction of a,/3-unsaturated ketones with hydroxylamine. Since 2-isoxazolines are readily oxidized to isoxazoles and possess some of the unique properties of isoxazoles, they also serve as key intermediates for the synthesis of other heterocycles and natural products. 

Al-Heterocycles, formation from olefins and acetylenes in a metallocomplex-catalyzed cycloaddition reaction and further transformations 98IZV816. 

The importance of the 1,3-dipolar cycloaddition reaction for the synthesis of five-membered heterocycles arises from the many possible dipole/dipolarophile combinations. Five-membered heterocycles are often found as structural subunits of natural products. Furthermore an intramolecular variant makes possible the formation of more complex structures from relatively simple starting materials. For example the tricyclic compound 10 is formed from 9 by an intramolecular cycloaddition in 80% yield ... 

Silylthioaldehydes 103, reactive dienophiles formed in situ from acetals according to a general method, are directly trapped with dienes to afford sulfur-containing heterocyclic compounds in good yield (Equation 2.29). Silylthioaldehydes are quite reactive in comparison with the aliphatic ones [102] which are rather inert in the cycloaddition reactions. 

The use of microwave-assisted multicomponent cycloaddition reactions allows unique heterocyclic scaffolds to be assembled rapidly from readily accessible starting materials. The three-component reaction of M-alkyl-l,4-DHP... 

Diazaphospholes are known to undergo facile 1,3-dipolar cycloaddditions with a variety of dipoles [2, 4, 7, 98], During recent years, some interesting [2+3] cycloaddition reactions have been reported. 2-Acyl-[l,2,3]diazaphospholes 6 were reported to undergo [2+3] cycloaddition with diazocumulene 92, the minor equilibrium isomer of a-diazo-a-silyl ketones 91, to form a bicyclic cycloadduct 93 (Scheme 29). Thermolysis of the cycloadduct results in the formation of tricyclic phosphorus heterocycle 94, which can be explained due to the possibility of two parallel reactions of cycloadduct. On the one hand, extrusion of molecular nitrogen from 93... 

Recently, much attention has been paid to hetero Diels-Alder reactions as powerful tools for the construction of heterocyclic compounds. For example, cycloaddition of 2,3-dimethylbuta-l,3-diene 41a with 1,2-thiazinylium salt 95, in acetonitrile at room temperature, resulted in the exclusive formation of product 76a resulting from cycloaddition across the C—S1 bond (see entry 1 in Table 15 and Equation 26) <1999TL1505>. Similarly, isoprene 41b and... 

Five-membered ring heterocycles can be the result of cycloaddition reactions of ADC compounds acting as 2n components with 1,3-dipoles, or as 47t components in cheletropic reactions. They can also result from nucleophilic attack on the ADC compound, followed by ring closure of the initial adduct. 

A rapid access to carbocyclic nucleosides, containing a fused isoxazoline ring has been proposed, starting from cyclopentadiene. The route involves a het-ero Diels-Alder cycloaddition reaction of nitrosocarbonylbenzene followed by a 1,3-dipolar cycloaddition of nitrile oxides, cleavage of the N-0 tether and transformation of the heterocyclic aminols into nucleosides via construction of purine and pyrimidine heterocycles (457). 

Regiospecilic intramolecular cycloadditions of nitrones to sulfur-substituted dienes, with 3-sulfolene precursors, has been realized (Scheme 2.217). The stereochemical outcome of these reactions is affected by the structure of the substituent (sulfide or sulfone) in the diene and by the chain length connecting the diene and nitrone (a) and (b) (see Scheme 2.211). The bicyclic products obtained from these reactions have been converted to interesting heterocyclic compounds (709). 

As shown in Scheme 2.21 Id, starting with N-allyl carbohydrate-nitrones (469), a series of chiral six- (470) and seven-membered(471) TV-heterocycles were synthesized (Scheme 2.227). A very interesting and useful aspect of this cycloaddition is the control of regioselectivity by the substitution at the nitrogen atom. Therefore, it is possible to direct reactions towards the syntheses of preferred six- or seven-membered heterocycles from carbohydrate derivatives (722). 

Finally, fully reduced heterocycles have been prepared either from a sequential azomethine imine cycloaddition-palladium-mediated cyclization process <2003T4451>, or from the reaction of A-( l-benzotriazolylalkyU-AyV-disubstitutcd hydrazine with methyl vinyl ether <1997JOC8210>. 

Finally, the reversibility of the nitrone/alkene [3+2] cycloaddition, mainly used to access the hexahydro-isoxa-zolo[2,3- ]pyridine ring system (see Section 11.10.3.7), can be used to functionalize these heterocycles. Accordingly, Holmes et al. found that a cycloreversion-cycloaddition reaction could be performed from 65 by simple heating in toluene at 190 °C. Under these conditions, the product of the reaction was found to be the exo-adduct 67 (Scheme 21) <2002J(P1)1494>. 

Closure of the oxadiazole ring is still achieved through cycloaddition between pyridine iV-oxides and isocyanates, affording adducts such as 142 (Scheme 38) <1995T6451>. Nonaromatic imine fV-oxides exhibited similar reactivities, since azasugar-derived fV-oxides as a mixture of 143 and 144 underwent cycloaddition reactions in the presence of phenyl isocyanate or trichloroacetonitrile. Compounds 145 and 146 (Scheme 39) were obtained from the aldoxime W-oxide 143 two other regioisomeric heterocycles arose from the ketoxime derivative 144 <1996T4467>. 

Abstract 1,3-Dipolar cycloaddition reactions (DCR) are atom-economic processes that permit the construction of heterocycles. Their enantioselective versions allow for the creation of up to four adjacent chiral centers in a concerted fashion. In particular, well-defined half-sandwich iridium (111) catalysts have been applied to the DCR between enals or methacrylonitrile with nitrones. Excellent yield and stereoselectivities have been achieved. Support for mechanistic proposals stems from the isolation and characterization of the tme catalysts. 

Wordy Over the past few years, we have encountered numerous examples of water as the perfect solvent. We observed this first in osmium-catalyzed dihydroxylation reactions and also in nucleophilic ring-opening reactions of epoxides. We also observed this in cycloaddition reactions and in most oxime ether, hydrazone, and aromatic heterocycle condensation processes.Finally, we observed it in formation reactions of an amide from a primary amine and an acid chloride using aqueous Schotten-Baumann conditions. ... 

The rhodium( 11)-catalyzed formation of 1,3-dipoles has played a major role in facilitating the use of the dipolar cycloaddition reaction in modern organic synthesis. This is apparent from the increasing number of applications of this chemistry for the construction of heterocyclic and natural product ring systems. This chapter initially focuses on those aspects of rhodium(II) catalysis that control dipole formation and reactivity, and concludes with a sampling of the myriad examples that exist in the Hterature today. 

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