Cycloaddition reactions diene oxidation

The cycloaddition reaction of 1,2,4-tiiazines 7V-oxides proceeds differently from the reaction of the corresponding 1,2,4-tiiazines. Thus the 1,2,4-triazine 4-oxide 55 acts only as a diene in the reaction with 1 -diethylaminopropyne to afford 2-methyl-4-(dimethylamino)pyrimidines 111. At the same time the 1,2,4-triazine 4-oxides 55 react with l-(dimethylamino)-l-ethoxyethylene by 1,3-dipolar cycloaddition to give 5-methyl-1,2,4-tiiazines 112 (78CB240). 

Nitro compounds have been converted into various cyclic compounds via cycloaddition reactions. In particular, nitroalkenes have proved to be useful in Diels-Alder reactions. Under thermal conditions, they behave as electron-deficient alkenes and react with dienes to yield 3-nitrocy-clohexenes. Nitroalkenes can also act as heterodienes and react with olefins in the presence of Lewis acids to yield cyclic alkyl nitronates, which undergo [3+2] cycloaddition. Nitro compounds are precursors for nitrile oxides, alkyl nitronates, and trialkylsilyl nitronates, which undergo [3+2]cycloaddition reactions. Thus, nitro compounds play important roles in the chemistry of cycloaddition reactions. In this chapter, recent developments of cycloaddition chemistry of nitro compounds and their derivatives are summarized. 

The P-nitroso phosphine oxide 406 behaves as an N-O heterodienophile and reacts with the 1,3-diene part of the molecule in a cycloaddition reaction to form the 2,4 ,5,6,7,8-hexahydro-8-phenyl-[l,2]azaphosphorino[l,6-3][l,2]oxa-zine 8-oxide 407 containing an stereogenic cyclic phosphorus atom (Scheme 64). 31P NMR spectroscopy shows one single peak indicating the formation of only one diastereomer <2002JOG6174>. 

The [4+ 4]-cycloaddition reaction of tethered bis-dienes has been used by Wender and co-workers in total synthesis as exemplified in syntheses of ( )-salsolene oxide and (-l-)-asteriscanolide (Scheme 28). In the synthesis of ( )-salsolene oxide, a nickel(0)-catalyst cleanly effects the cycloaddition of the two conjugated dienes in compound 93 to afford the bicyclo[5.3.1]undecadiene in a good yield and with moderate selectivity.99 The first synthesis of (-l-)-asteriscanolide was accomplished in only 13 steps. The key [4+ 4]-cycloaddition reaction efficiently set the requisite eight-membered ring of (-l-)-asteriscanolide in good yield and with excellent diastereoselectivity.100 The diastereoselective [4 + 4]-cycloaddition has also been applied to the synthesis of the core ring system found in several sesterterpenes such as the ophiobolins (Scheme 28).101... 

Although cycloaddition reactions have yet to be observed for alkene radical cations generated by the fragmentation method, there is a very substantial literature covering this aspect of alkene radical cation chemistry when obtained by one-electron oxidation of alkenes [2-16,18-26,28-31]. Rate constants have been measured for cycloadditions of alkene and diene radical cations, generated oxidatively, in both the intra- and intermolecular modes and some examples are given in Table 4 [91,92]. 

Epoxidation of amidoallenes with dimethyldioxirane leads to allene oxides as reactive intermediates which can be trapped with dienes in a [4+ 3]-cycloaddition reaction. Exposure of a mixture of amidoallene 177 with cydopentadiene to a small excess of dimethyldioxirane at -45 °C produced endo-bicydooctanone 178 in 60% yield (Eq. 13.60) [69]. The allene oxide is electrophilic, since no reaction takes place with methyl acrylate. 

Details of various routes to allylphosphine oxides (43) have been reported, and the subsequent synthesis of 1,3-dienes has been illustrated by many examples.37 Also described are stereochemical aspects of these diene syntheses and of subsequent Diels-Alder cycloaddition reactions.37 High regioselectivity is observed in migrations of the diphenylphosphinoyl group from unsymmetrical sites, as in (44), in that both products have a double bond exocydic to the cyclohexane ring.38... 

Substituted 4,5-dihydro-5-vinylisoxazoles (40), obtained by regio- and stereospecific cycloaddition of nitrile oxides to dienes, undergo smooth osmium-catalyzed c/s-hydro-xylation to give amino-polyol precursors (equation 28)45. The reaction is anti selective, the diastereomeric ratios ranging from 73 27 up to 99 1. Highest stereoselectivities were observed when R3 was methyl. Thus, whereas osmylation of 40a afforded a 78 22 mixture of 41a and 42a, respectively, in 80% overall yield, similar treatment of 40b resulted in a 92 8 mixture of 41b and 42b, respectively, in 70% overall yield. The cycloaddition-osmylation sequence allows control of the relative configuration of up to 4 contiguous asymmetric centers. 

Bis-allylic oxidation of 23 and related cyclohexa-1,4-dienes provides a convenient and general preparation of cyclohexa-2,5-dien-l-ones (Scheme 7). These cross-conjugated die-nones are substrates for a variety of photochemical rearrangement and intramolecular cycloaddition reactions. Amide-directed hydrogenations of dienones 24a and 24b with the homogeneous iridium catalyst afford cyclohexanones 25a and 25b, containing three stereogenic centers on the six-... 

While both hydrogenation and epoxidation reactions of (7) (and substituted forms) occur on the oxepin valence tautomer, cycloaddition reactions proceed more readily on the arene oxide form (where the diene is closer to planarity). Thus the dienophiles DM AD and maleic anhydride (MA) readily yielded [4 + 2] cycloadducts with (7) as shown in Scheme 22 (67AG(E)385). A similar type of singlet oxygen cycloaddition reaction gave an unstable endoperoxide (106) which upon heating yielded trans-benzene trioxide quantitatively (equation 14). (75JOC3743). 

The presence of substituents at the 2,7-positions of (7) results in an almost total preference for the oxepin form and this may explain why the arene oxide forms of oxepins (98) (78TL2999) and (108) (79JOC468) apparently did not participate in cycloaddition reactions. Oxepins (16) and (108) thus adopted the role of dienes in [4 + 2] cycloaddition reactions with azo compounds (equation 16). 

Arene oxide-oxepin systems have also been reported to undergo [2 + 4] or [4 + 6] pericyclic cycloaddition reactions with heterocyclic dienes like the tetrazine 279 and the triazine 280. 65 Thus 86 96 reacts with 279 and 280 to yield the dihydrooxepino [4,5-d] pyridazine 281 and the oxepino [4,5-c] pyridine 282, respectively, via a [2 + 4] cycloaddition as well as the phthalazine 283 and isoquinoline 284, respectively, probably via a [6 + 4] cycloaddition reaction. However, 157 gives only 285 and 286 arising from a [2 + 4] cycloaddition reaction. 

Nitrile oxides react with the methyl enol ethers of (Rs)-l -fluoro-alkyl-2-(p-tolylsulfinyl)ethanones to produce (45,5/f,/fs)-4,5-dihydroisoxazoles with high regio-and diastereo-selectivity.87 In the 1,3-dipolar cycloaddition of benzonitrile oxide with adamantane-2-thiones and 2-methyleneadamantanes, the favoured approach is syn, as predicted by the Cieplak s transition-state hyperconjugation model.88 The 1,3-dipolar cycloaddition reaction of acetonitrile oxide with bicyclo[2.2.l]hepta-2,5-diene yields two 1 1 adducts and four of six possible 2 1 adducts.89 Moderate catalytic efficiency, ligand acceleration effect, and concentration effect have been observed in the magnesium ion-mediated 1,3-dipolar cycloadditions of stable mesitonitrile oxide to allylic alcohols.90 The cycloaddition reactions of acryloyl derivatives of the Rebek imide benzoxazole with nitrile oxides are very stereoselective but show reaction rates and regioselectivities comparable to simple achiral models.91. 

The cyclopent-2-enone required for the photodimerisation is prepared by the hydrolysis and oxidation of 3-chlorocyclopentene, which is obtained by the low temperature addition of hydrogen chloride to cyclopentadiene. The latter is obtained by heating dicyclopentadiene. This depolymerisation is an example of a reverse (or retro) Diels-Alder cycloaddition reaction the diene readily reforms the dicyclopentadiene on standing at room temperature. 

The generation of six-membered ring systems by means of cycloaddition reactions can be divided into two main approaches. The first is the cyclotrimerizationofalkynes utilizing low-valent iron catalyst systems, whereas the second approach is the Diels-Alder (DA) reaction of a diene and a dienophile. The latter reaction can itself be divided into three subclasses DA reactions with normal, neutral and inverse electron demand are known. The electronic structure of the educts dictates the oxidation state of the catalyst system required to perform the diverse classes of DA reactions. Nevertheless, for each subclass examples can be found. 

Free 1,2,5-triphospha Dewar benzene derivative 95 is formed in two steps from 3 mol of 44a by oxidative decomplexation of the triphosphacyclohexa-l,4-diyl-2,5-diene ligand of the Hf complex 96 <1997CB1491>. An organometallic [2+1+1] cycloaddition reaction between the phosphinidene complex 97, 44a, and a coordinated CO gives access to the 1,2-diphosphacyclobutenone complex 98 (Scheme 31) <1998CEJ1917>. 

Recently, the reaction of masked ortho-benzoquinone [92] with C60 was tested [93]. The [4+2] cycloaddition reaction of such electron-deficient dienes with fullerenes resulted in the formation of highly functionalized bicyclo [2.2.2] octenone-fused fullerenes. The reactants were generated in situ by the oxidation of the readily available 2-methoxy phenols with hypervalent iodine agents. For the several different masked ortho-benzoquinones that were tested, it was found that the yield of the cycloadducts depends on the nature of the starting materials and the reaction conditions. Other Diels-Alder reactions of such electron-deficient dienes with electron-poor fullerenes involved tropones [94], 1,3-butadienes substituted with electron-withdrawing groups [95], and 2-pyrone [96]. 

Copper(I) catalysis is very well established to promote intramolecular [2+2] photocycloaddition reactions of l,n-dienes (review [351]). The methodology recently enjoyed a number of applications [352-354], It is assumed that CuOTf, which is commonly applied as the catalyst, coordinates the diene and in this way mediates a preorganization. The Ghosh group recently reported a number of CuOTf-catalyzed photochemical [2+2] cycloaddition reactions, in which an organocopper radical complex was proposed as a cyclization intermediate (which should, however, have a formal Cu(II) oxidation state) (selected references [355-357]). A radical complex must, however, not be invoked, since the process may either proceed by a [2+2] photocycloaddition in the coordination sphere of copper without changing the oxidation state or according to a cycloisomerization/reductive elimination process. 

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