Diene heterodienophiles

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>. 

Examples of the use of heterodienophiles under the action of microwave irradiation are not common. Soufiaoui [84] and Garrigues [37] used carbonyl compounds as die-nophiles. The first example employed solvent-free conditions the second is an example of the use of graphite as a susceptor. Cycloaddition of a carbonyl compound provided a 5,6-dihydro-2H-pyran derivative. These types of reaction proceed poorly with aliphatic and aromatic aldehydes and ketones unless highly reactive dienes and/or Lewis acid catalysts are used. Reaction of 2,3-dimethyl-l,3-butadiene (31) with ethyl glyoxylate (112) occurred in 75% yield in 20 min under the action of microwave irradiation. When conventional heating is used it is necessary to heat the mixture at 150 °C for 4 h in a sealed tube to obtain a satisfactory yield (Scheme 9.33). 

Acyl nitroso compounds react with 1, 3-dienes as N-O heterodienophiles to produce cycloadducts, which have found use in the total synthesis of a number of nitrogen-containing natural products [21]. The cycloadducts of acyl nitroso compounds and 9,10-dimethylanthracene (4, Scheme 7.3) undergo thermal decomposition through retro-Diels-Alder reactions to produce acyl nitroso compounds under non-oxidative conditions and at relatively mild temperatures (40-100°C) [11-14]. Decomposition of these compounds provides a particularly clean method for the formation of acyl nitroso compounds. Photolysis or thermolysis of 3, 5-diphenyl-l, 2, 4-oxadiazole-4-oxide (5) generates the aromatic acyl nitroso compound (6) and ben-zonitrile (Scheme 7.3) [22, 23]. Other reactions that generate acyl nitroso compounds include the treatment of 5 with a nitrile oxide [24], the addition of N-methyl morpholine N-oxide to nitrile oxides and the decomposition of N, O-diacylated or alkylated N-hydroxyarylsulfonamides [25-29]. 

J0rgensen and co-workers (229,230) examined the use of a-ketoesters and 1,2-diones as heterodienophiles in reactions with Danishefsky s diene. Catalyst 269c was found to exert the highest facial bias in these reactions, and is generally tolerant of substitution on the dione. These reactions may be conducted with as little as 0.05 mol% catalyst loadings. 

The formation of heterocycles by cycloaddition reactions of conjugated dienes is the subject of this chapter. Almost the entire account is devoted to the Diels-Alder reaction of dienes with heterodienophiles to yield six-membered ring compounds (equation 1). Many such reactions have been reported and there is a plethora of reviews. Somela p are general others are cited at appropriate places in the text. This account is highly selective, concentrating on recent work with particular regard to the stereochemistry of these processes. 

Weinreb SM (1991) Heterodienophile additions to dienes. Trost BM, Fleming I (eds) Comprehensive organic synthesis, vol 4. Pergamon, Oxford, pp 401 109... 

The versatility of these [4+2] heterocyclization reactions is a consequence of the wide range of ene and diene components which can be used. In addition to alkenes and alkynes functioning as ene components, a variety of heterodienophiles is available such as electron-deficient imines (e.g. equation 89), nitriles e.g. equation 90), electrophilic carbonyl compounds (e.g. equation 91), thiocarbonyl compounds (e.g. equation 92), singlet oxygen (e.g. equation 93), nitroso compounds (e.g. equation 94), sulfenylsulfonamides (e.g. equation 95) and azo compounds (e.g. equation 96). Many of these reactions proceed with excellent regioselectivity and stereoselectivity, probably because in many instances they involve... 

Ab initio and density functional theoretical studies of the 4 + 2-cycloaddition of 2-azabutadiene with formaldehyde predict a concerted reaction that agrees well with experimental evidence.184 The azadiene A-plienyl-l-aza-2-cyanobuta-l,3-diene reacts with electron-rich, electron-poor, and neutral dipolarophiles under mild thermal conditions.185 5,6-Diliydro-4//-1,2-oxazines have been shown to be usefiil as synthon equivalents of 2-cyano-l-azabuta-1,3-dienes.186 The intramolecular Diels-Alder reaction of 1-aza-l,3-butadienes (106) can be activated by a 2-cyano substituent (Scheme 37).187 Stereoselectivity in the hetero-Diels-Alder reactions of heterobutadienes, nitrosoalkenes, and heterodienophiles has been extensively reviewed.188 The azadiene l-(f-butyldimethylsilyloxy)-l-azabuta-1,3 -diene (107) reacts with halobenzo-quinones, naphthoquinones, and A-phcnylmalcimidc to yield low to good yields of various pyridine heterocycles (108) (Scheme 38).189 The 4 + 2-cycloaddition of homophthalic anhydride with A-(cinnamylidcnc)tritylaminc produces the 3,4-adduct whereas with A -(cinnamylidcnc)bcnzylidinc the 1,2-adduct is produced.190... 

The HDA reaction allows for rapid access to chiral six-membered heterocyclic structures that serve as valuable intermediates in organic synthesis. The first highly enantioselective HDA reaction promoted by a chiral hydrogen bond donor was reported from the Rawal laboratory. While investigating the cycloaddition reactions of amino-siloxy diene 115, it was observed that this diene was exceptionally reactive to heterodienophiles, and underwent HDA reactions with various aldehydes at room temperature, even in the absence of any added catalyst (Scheme 6.14). Subsequent treatment of the intermediate cycloadducts (116) with acetyl chloride afforded the corresponding dihydro-4-pyrones (117) in good overall yields [101]. Further studies of this reaction revealed a pronounced solvent effect,... 

Most importantly, the scope of the Diels-Alder reaction is very high - not only allowing the synthesis of cyclohexenes and 1,4-cyclohexadienes using 1,3-butadienes and alkenes and alkynes, respectively, but also giving access to a multitude of different heterocycles by exchanging the atoms a-d in the butadiene as well as the atoms e and f in the alkene by hetero atoms such as oxygen, nitrogen and sulfur. However, also dienes and dienophiles with several other atoms as phosphorous, boron, silicone, and selenium have been described. Thus, many different heterodienes and heterodienophiles have been developed over the years (Tables 1-1 and 1-2). 

This method, developed by Krafft and Meinke, provided the first route to RCH=Se systems that enabled the chemistry of this heterodienophile to be explored (86JA1314 87TL5121 88JA8671). Aryl- and alkyl-substituted derivatives 69 fragment on treatment with fluoride ions at room temperature to afford selenoaldehydes (70), which are trapped by dienes to give Diels-Alder adducts, e.g., 71 (predominantly endo isomer). Other dienes used include isoprene, 2-ethoxybutadiene, and l,3-diphenylbenzo[c]furan (88JA8671). 

Indolones such as (40) have been exploited on a few occasions as heterodienophiles (equation 12). Cycloaddition of (40 R = Ph) with several dienes was regioselective (cf. equation 12). The reactions with ( ,Z)- and ( , )-2,4-hexadiene were syn stereoselective with respect to the diene but exolendo selectivity was not determined. With the related dienophile (40 R = C02Et), regioselectivity deteriorated in the cycloadditions. 

Cycloadditions with these heterodienophiles are usually regioselective and are in accord with FMO theory. The reactions are syn selective with the diene component. Other stereochemical features of the process are outlined in some of the examples described below, as well as in previous reviews. -" It should also be mentioned that only aldehydes and some ketones act as dienophiles. Except for rare exceptions, other types of carbonyl compounds apparently do not participate in Diels-Alder cycloadditions. 

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