Reactions of Cycloadducts

There are several well-known transformations of 3,6-dihydrothiazine oxides and 3,6-dihydrothiazine imines. In most of these reactions, either the cyclic sulfinamide mdety and/OT the carbon-carbon double bond is involved. For example, a 3,6-dihydrothiazine oxide can be hydrolyzed under either acidic or basic conditions to afford a homoallylic amine derivative [Eq. (17)]. 

This transformation probably proceeds through an allylic sulfinic acid which loses SO2 via a retro-ene process. The mechanism of this reaction was first investigated by Mock and Nugent and was examined further by Weinreb et 

The Weinreb group investigated the hydrolysis of dihydrothiazine oxide 39, prepared from ( , )-tetramethylbutadiene, which was demonstrated to afford only sulfonamide 40 having an E double bond and the erythro configuration [Eq. (18)]. 

Similarly, hydrolysis of 41, derived from ( ,Z)-tetramethylbutadiene, yielded only sulfonamide 42 with an E double bond and the threo configuration [Eq. (19)]. 

These results are best rationalized by a concerted retro-ene reaction of intermediate sulfinic acid 43 [Eq. (20)] 

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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... 

The generation of the carbcxi-carbon double bond of unsaturated nitrogen heterocycles by the rDA reaction of cycloadducts that act as protected ethylenes has been accomplished. Azetines have been prepared by this method. Another example is the synthesis of l-methyl-3-pyrroline (201). By protecting the ethylene of N-methylmaleimide (199) with furan and then reducing with lithium aluminum hydride, adduct (200) was obtained (equation 86). Pyrolysis of adduct (200) at 250-300 C gave l-methyl-3-pyrroline (201) in 60% isolated yield. The ethylene moiety of N-substituted maleimides can also be generated via rDA reactions. Examples include the generation of N-phenylmaleimide (equation 87) and of N-acetoxymaleimide (equation 88). ... 

Fukuyama and Yung (81TL3759) used adduct 69 as a key starting material for the synthesis of methyl ( )-3-(3-cyana-6-oxabicyclo[3.I.0]hex-2-en-5-yl)-2-propenoate (81). The reaction of cycloadduct 69 with methyl lithioacetate gave unsaturated ester 77. Reduction in acidic media of the conjugated double... 

Mild acid converts it to the product and ethanol. With the higher temperatures required of the cyano compound [1003-52-7] (15), the intermediate cycloadduct is converted direcdy to the product by elimination of waste hydrogen cyanide. Often the reactions are mn with neat Hquid reagents having an excess of alkene as solvent. Polar solvents such as sulfolane and /V-m ethyl -pyrrol i don e are claimed to be superior for reactions of the ethoxy compound with butenediol (53). Organic acids, phenols, maleic acid derivatives, and inorganic bases are suggested as catalysts (51,52,54,59,61,62) (Fig. 6). 

Reaction of the A-nitrosoglycine (394) with acetic anhydride gave the anhydro-5-hydroxy-l,2,3-oxadiazolium hydroxide (395). Reaction with DMAD resulted in formation of the intermediate 1 1 cycloadduct (396) which was not isolated and which lost CO2 under the thermal reaction conditions to give dimethyl l-phenylpyrazole-3,4-dicarboxylate (397) (83MI40300). This reaction is capable of considerable variation in terms of the substituents... 

A similar product is obtained from the reaction of anhydro-4(5)-hydroxy-l,2,3-triazolium hydroxide (398). In this case reaction with DMAD occurred in 1 hour in boiling benzene. Extrusion of methyl isocyanate from the initial 1 1 cycloadduct (399) occurred during the reaction giving (400). 

Dipoles can also be built into heterocyclic systems, and though of limited use, they may also be utilized for the synthesis of [5,6] ring-fused systems. Reaction of 2 3H)-benzothiazolethione with (chlorocarbonyl)phenylketene in warm anhydrous benzene gave the heteroaromatic betaine (416). On heating with DMAD in boiling toluene the tricyclic pyridinone (418) was obtained, presumably by elimination of COS from the intermediate cycloadduct (417) (80JOC2474). 

Although in its reactions with several mesoionic systems diphenylthiirene dioxide (439) does not lose SO2 from the cycloadducts, in its reactions with pyridinium, quinolinium and isoquinolinium phenacylides it behaves as an acetylene equivalent. Thus, reaction of (439)... 

A particularly interesting system where nitrogen is lost cheletropically after formation of the initial [4 + 2] cycloadduct involves the thermal reaction of azirines with tetrazines (82) (74CC45, 74TL2303, 74CC782, 75JHC183). A variety of heterocyclic products are produced depending on the structure of the azirine and tetrazine used and the reaction conditions. 

Four-membered heterocycles are easily formed via [2-I-2] cycloaddition reac tions [65] These cycloaddmon reactions normally represent multistep processes with dipolar or biradical intermediates The fact that heterocumulenes, like isocyanates, react with electron-deficient C=X systems is well-known [116] Via this route, (1 lactones are formed on addition of ketene derivatives to hexafluoroacetone [117, 118] The presence of a trifluoromethyl group adjacent to the C=N bond in quinoxalines, 1,4-benzoxazin-2-ones, l,2,4-triazm-5-ones, and l,2,4-tnazin-3,5-diones accelerates [2-I-2] photocycloaddition processes with ketenes and allenes [106] to yield the corresponding azetidine derivatives Starting from olefins, fluonnaied oxetanes are formed thermally and photochemically [119, 120] The reaction of 5//-l,2-azaphospholes with fluonnated ketones leads to [2-i-2j cycloadducts [121] (equation 27)... 

Certain 1,5 diazabicyclo[3 3 0]oct-2-enes can be transformed unexpectedly into 4//-5,5-dihydro-l, 2 diazepines on heating [209] 1,5-Dipoles formed on heating of l,5-diazabicyclo[3 3 0]oct-2-enes [210] can be trapped with olefins to give [3+2] cycloadducts At elevated temperatures, they undergo a [3+2] cycloreversion Tins reaction sequence offers a simple route to dienes with interesting substitution patterns, for example, 1,1 bis(trifluoromethyl)-l,3-butadiene [211] The [3+2] cycloadducts that arise from the reaction of the 1,5 dipoles with acetylenes undergo... 

Interestingly, the intramolecular cycloadduct 97 (15%) was obtained from the reaction of 3,4-dicyanofuroxan with 1,5-cyclooctadiene. In contrast, with nor-bomadiene only intermolecular products 98 (30%) and 99 (14%) were obtained (85T727) (Scheme 48). 

Reaction of 2-(A -allylamino)-3-formyl-4//-pyrido[l, 2-u]pyrimidin-4-ones 219 in EtOH with HONH2 HCI yielded ( )-oximes 220 at 0°C and 221 (R = PhCH2) under reflux. Heating 220 (R = H) in a boiling solvent afforded cw-fused tetracyclic cycloadducts 221 (R = H). In an aprotic solvent (e.g., benzene or MeCN) the main a>fused cycloadducts 221 (R = H) were accompanied by a mixture of trauA-fused cycloadducts 222, A -oxides 223 and tetracyclic isoxazoline 224 (96T887). The basicity of the 2-allylamino moiety of compounds 219 affected the rate of the conversion. Cycloadditions were also investigated in dioxane and BuOH. 

Thermal cycloadditions of butadiene to 3-bromo- 133 and 3-methoxy-5-methylene-2(5//)-furanones 220 were studied (95TL749). These systems contain substituents at C3 capable of stabilizing also a possible radical intermediate, influencing hereby the rate and/or the course of the reaction. Thus, the reaction of 133 and 220, respectively, with butadiene at 155°C afforded mixtures of the expected 1,4-cycloadducts 221 and 222, respectively, and of the cyclobutane derivatives... 

It was found that the reaction of 5-acetoxy- and 5-benzoyloxy-2(5//)-furanones 174 with aryl nitrile oxides afforded only one cycloadduct, the condensed isox-azoline 233 (88TL5317). In principle, there are four possible cycloadducts 233 and 234 resulting from the anti approach of the 1,3-dipolarophile to the acetoxy group (with exo configuration of the acetoxy substituent), and two further isomers... 

Formylation of the V-allyl indole derivatives 311 (obtained by allylation of the indole 310) afforded l-allyl-7-formyl-indole 312. Subsequent condensation of 7-formyl indole derivatives 312 with ethyl acetate in presence of sodium ethoxide gave 313 (89S322). Reaction of 312 with N-methylhydroxylamine hydrochloride afforded the cycloadduct, tetracyclic... 

Reaction of the mesoionic oxazolone 620 with acetylenedicarboxylic ester 621 gave the cycloadduct 622 in aprotic solvents and the Michael adducts... 

The borane catalyst 4 is also effective in the Diels-Alder reaction of furan (Scheme 1.11). In the presence of a catalytic amount of this reagent a-bromoacro-lein or a-chloroacrolein reacts with furan to give the cycloadduct in very good chemical yield with high optical purity [6d]. 

Yamamoto et al. have reported a chiral helical titanium catalyst, 10, prepared from a binaphthol-derived chiral tetraol and titanium tetraisopropoxide with azeotropic removal of 2-propanol [16] (Scheme 1.22, 1.23, Table 1.9). This is one of the few catalysts which promote the Diels-Alder reaction of a-unsubstituted aldehydes such as acrolein with high enantioselectivity. Acrolein reacts not only with cyclo-pentadiene but also 1,3-cyclohexadiene and l-methoxy-l,3-cyclohexadiene to afford cycloadducts in 96, 81, and 98% ee, respectively. Another noteworthy feature of the titanium catalyst 10 is that the enantioselectivity is not greatly influenced by reaction temperature (96% ee at... 

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