Cyclic dienophiles

Dienophilic cyclic a-carbonylazo compounds (triazoline diones, indazolone, phthalazine dione) prepared in a flow cell, by anodic oxidation of the corresponding hydrazino compounds in acidic methanol or acetonitrile, react with dienes (Scheme 50) [72, 73]. 

Diels-Alder is the preparation of cyclic olefins from dienes and a dienophile... 

Cycloaddition reactions where bis(trifluoromethyl)-substituted hetero-1,3-dienes act as dienophiles have been descnbed for open-chain and cyclic dienes [115, 126, 127] The balance of the diene -dienophile activity of bis(tnfluoro-methyl)-substituted hetero-l,3-dienes can be influenced strongly by the substituents bonded to the inuno nitrogen atom For instance, A/-(arylsulfonyl) denvatives of tnfluoroacetaldimine and hexafluoroacetone imine do not act as dienes but exhibit only the dienophile reactivity of electron deficient imines [5 229, 234,235, 236 237] (equation 52)... 

The 5-methylene-2(5//)-furanone 216 was found to be a good dienophile in Diels-Alder reactions with acyclic dienes (R = H, 2-Me, 2,3-di-Me, 1-Me, 1,3-di-Me). The reaction took place specifically at the cxo-cyclic double bond to give the corresponding spiro adducts 217 in good yields (Scheme 59) (90JOC3060). 

Extension of this work by reacting 5-nitropyrimidine with 0,0-ketene acetals and with other cyclic and non-cyclic enamines showed that also with these electron-rich dienophiles the addition is regioselective and gives rise to the formation of 2-mono- or 2,3-disubstituted 5-nitropyridines (Scheme 30). Thus, reaction of 5-nitropyrimidine with the cyclic N,S-ketene acetals 4,5-dihydro-1 -methyl-2-methylthiopyrrole and 4,5,6,7-tetrahydro-1 -methyl-2-methylthioazepine gives in low yields 2,3-dihydro-1-methyl-5-nitropyr-olo[2,3-h]pyridine and the 5,6,7,8-tetrahydro-9-methyl-3-nitropyrido [2,3-Z)]azepine, respectively (89T2693) (Scheme 30). 

Mechanistically the observed stereospecificity can be rationalized by a concerted, pericyclic reaction. In a one-step cycloaddition reaction the dienophile 8 adds 1,4 to the diene 7 via a six-membered cyclic, aromatic transition state 9, where three r-bonds are broken and one jr- and two cr-bonds are formed. The arrangement of the substituents relative to each other at the stereogenic centers of the reactants is retained in the product 10, as a result of the stereospecific y -addition. 

One of the most powerful tools for the formation of cyclic molecules is the Diels-Alder reaction (/). The reaction generally involves the combination of a diene with a dienophile according to the diagram. There are surprisingly few limitations on the... 

The diene must adopt what is called an s-cis conformation, meaning "cis-like" about the single bond, to undergo a Diels-Alder reaction. Only in the s-cis conformation are carbons 1 and 4 of the diene close enough to react through a cyclic transition state. In the alternative s-trans conformation, the ends of the diene partner are too far apart to overlap with the dienophile p orbitals. 

Another reaction unique to conjugated dienes is the Diels-Alder cycloaddition. Conjugated dienes react with electron-poor aikenes (dienophiles) in a single step through a cyclic transition slate to yield a cyclohexene product. The reaction is stereospecific, meaning that only a single product stereoisomer is formed, and can occur only if the diene is able to adopt an s-cis conformation. 

Cycloaddition reactions are those in which two unsaturated molecules add together to yield a cyclic product. For example, Diels-AJder reaction between a diene (four tt electrons) and a dienophile (two tt electrons) yields a cyclohexene. Cycloadditions can take place either by suprafacial or antarafacial pathways. Suprafacial cycloaddition involves interaction between lobes on the same face of one component and on the same face of the second component. Antarafacial cycloaddition involves interaction between lobes on the same face of one component ancl on opposite faces of the other component. The reaction course in a specific case can be found by looking at the symmetry of the HOMO of one component and the lowest unoccupied molecular orbital (LUMO) of the other component. 

Cycioaddition reaction (Sections 14.4, 30.6) A peri cyclic reaction in which two reactants add together in a single step to yield a cyclic product. The Diels-Alder reaction between a diene and a dienophile to give a cyclohexene is an example. 

The polyene character of 1 /7-azcpines makes them susceptible not only to a variety of electro-cyclic reactions, but also to cycloaddition with a variety of dienophiles, and to dimerization by [6 + 4] 7i-pericyclic reactions. 

A special method, with only two examples, starts from 1,2,4-triazines.20 21 Diels-Alder reaction with the strained dienophile dimethyl tricyclo[4.2.2.02,5]deca-3,7,9-triene-7,8-dicarboxylate (14) is followed by an elimination of nitrogen via a retro-Diels-Alder process. The formed product, however, cannot be isolated, but reacts via another retro-Diels-Alder reaction and an electro-cyclic reaction to provide the azocine derivative 15. The sequence order of the reactions is not clear, but both pathways lead to the same product. 

Barluenga et al. have described novel vinylcarbene complexes containing a cyclic BF2 chelated structure which temporarily fixes the s-cis conformation of the exocyclic C=C and Cr=C double bonds. These boroxycarbene complexes behave as dienophiles with 2-amino-l,3-butadienes in a remarkably regio- and exo-selective way. Moreover, high degrees of enantioselectivity are reached by the use of chiral 2-aminodienes derived from (S)-methoxymethylpyrrolidine [101] (Scheme 54). 

Conjugated cyclohexenones [6] have also been easily prepared by combining the cycloaddition of dimethylaminobutadiene 4 and several cyclic and acyclic dienophiles followed by the elimination of the amino group from the cycloadducts under acidic conditions. Scheme 2.3 summarizes some of these results. 

Pyrano-[4,2-b]-pyrrol-5-ones (40) and pyrano-[4,3-b]-pyrrol-6-ones (41) (Figure 2.4) are stable cyclic analogs of pyrrole 2,3-quinodimethane and undergo Diels Alder reaction [40, 41] with various dienophiles to afford indole derivatives after loss of carbon dioxide. 

Ferrocenium hexafluorophosphate (48) and catecholboronbromide (49) (Figure 3.6) are efficient catalysts that have been tested in the cycloadditions of cyclic and acyclic dienes with a variety of dienophiles [48]. Catalyst 48 is less active than 49, but is less corrosive. 

Inverse electron-demand Diels-Alder reaction of (E)-2-oxo-l-phenylsulfo-nyl-3-alkenes 81 with enolethers, catalyzed by a chiral titanium-based catalyst, afforded substituted dihydro pyranes (Equation 3.27) in excellent yields and with moderate to high levels of enantioselection [81]. The enantioselectivity is dependent on the bulkiness of the Ri group of the dienophile, and the best result was obtained when Ri was an isopropyl group. Better reaction yields and enantioselectivity [82, 83] were attained in the synthesis of substituted chiral pyranes by cycloaddition of heterodienes 82 with cyclic and acyclic enolethers, catalyzed by C2-symmetric chiral Cu(II) complexes 83 (Scheme 3.16). 

Cycloalkenones and/or their derivatives can also behave as dienic partners in the Diels-Alder cycloaddition. It is well documented [41] that cyclic acetals, for example, can interconvert with ring-opened enol ether forms, in a reversible manner the latter compounds can then be trapped by various dienophiles. Thus dienes 119 and 120 reacted with [60]-fullerene (Ceo) at high pressure, affording highly thermally stable products [42] (Scheme 5.16). Ketones 123 and 124 could be directly obtained by cycloaddition of enol forms 121 and 122 of 2-cyclopen-ten-and 2-cyclohexen-l-one, respectively. 

When the diene is cyclic, there are two possible ways in which addition can occur if the dienophile is not symmetrical. The larger side of the dienophile may be under the ring endo addition), or it may be the smaller side exo addition) ... 

There are, broadly speaking, three possible mechanisms that have been considered for the uncatalyzed Diels-Alder reaction. In mechanism a there is a cyclic six-centered transition state and no intermediate. The reaction is concerted and occurs in one step. In mechanism b, one end of the diene fastens to one end of the dienophile first to give a diradical, and then, in a second step, the other ends become fastened. A diradical formed in this manner must be a singlet that is, the... 

Diels-Alder reaction is one of the most fundamental reactions for organic synthesis. Its synthetic utility is unquestioned. The stereochemistry of the reactions has attracted much attention. The retention of stereochemistry in the diene and the dienophile, the predominant formation of endo-attack products in the reactions of cyclic dienes, and highly controlled regioselectivity in the reactions of substimted dienes and... 

The secondary orbital interaction has been applied to explain enantioselective catalytic Diels-Alder reactions of cyclic dienes and acetylenic dienophiles [23, 24]. 

Diels-Alder disconnection of (S) reveals a cyclic dienophile (11) in which Me and H must be ais since they are also cis in (S), and the one step synthesis duly gi ves c-ir, product. 

Sulphines may react as dienophiles with 1,3-dienes with the formation of cyclic sulphoxides. Unstable 2,2-dichloro-5,6-dihydro-2ff-thiin-l-oxide 191 was formed in an exothermic reaction between 173aandcyclopentadieneat — 40 (equation 101). The simplest, parent sulphine, CH2 = S = O, prepared in situ by treatment of a-trimethylsilylmethanesulphinyl chloride with cesium fluoride, reacts with cyclopentadiene to give bicyclic, unsaturated sulphoxide 192 as a mixture of two diastereoisomers in a 9 1 ratio (equation 102). On the other hand, a,j8-unsaturated sulphine 193 (generated by thermolysis of 2-benzylidene-l-thiotetralone dimer S-oxide) in boiling toluene behaves as a 1,3-diene and was trapped by norborene forming sulphoxide 194 in 78% yield ° (equation 103). 

Diels-Alder reactions are found to be little influenced by the introduction of radicals (cf. p. 300), or by changes in the polarity of the solvent they are thus unlikely to involve either radical or ion pair intermediates. They are found to proceed stereoselectively SYN with respect both to the diene and to the dienophile, and are believed to take place via a concerted pathway in which bond-formation and bond-breaking occur more or less simultaneously, though not necessarily to the same extent, in the transition state. This cyclic transition state is a planar, aromatic type, with consequent stabilisation because of the cyclic overlap that can occur between the six p orbitals of the constituent diene and dienophile. Such pericyclic reactions are considered further below (p. 341). 

In the Diels-Alder reaction with inverse electron demand, the overlap of the LUMO of the 1-oxa-l,3-butadiene with the HOMO of the dienophile is dominant. Since the electron-withdrawing group at the oxabutadiene at the 3-position lowers its LUMO dramatically, the cycloaddition as well as the condensation usually take place at room or slightly elevated temperature. There is actually no restriction for the aldehydes. Thus, aromatic, heteroaromatic, saturated aliphatic and unsaturated aliphatic aldehydes may be used. For example, a-oxocarbocylic esters or 1,2-dike-tones for instance have been employed as ketones. Furthermore, 1,3-dicarbonyl compounds cyclic and acyclic substances such as Meldmm s acid, barbituric acid and derivates, coumarins, any type of cycloalkane-1,3-dione, (1-ketoesters, and 1,3-diones as well as their phosphorus, nitrogen and sulfur analogues, can also be ap-... 

Recently, Denmark and coworkers have developed a new strategy for the construction of complex molecules using tandem [4+2]/[3+2]cycloaddition of nitroalkenes.149 In the review by Denmark, the definition of tandem reaction is described and tandem cascade cycloadditions, tandem consecutive cycloadditions, and tandem sequential cycloadditions are also defined. The use of nitroalkenes as heterodienes leads to the development of a general, high-yielding, and stereoselective method for the synthesis of cyclic nitronates (see Section 5.2). These dipoles undergo 1,3-dipolar cycloadditions. However, synthetic applications of this process are rare in contrast to the functionally equivalent cycloadditions of nitrile oxides. This is due to the lack of general methods for the preparation of nitronates and their instability. Thus, as illustrated in Scheme 8.29, the potential for a tandem process is formulated in the combination of [4+2] cycloaddition of a donor dienophile with [3+2]cycload-... 

Cyclic ADC compounds are similarly prepared by oxidation of the corresponding cyclic hydrazine derivatives. The most commonly encountered compounds are the 3//-l,2,4-triazole-3,5(4//)-diones (5), and in particular the 4-phenyl derivative (5, R = Ph), usually abbreviated as PTAD. Similarly, the abbreviation MTAD is used for the 4-methyl derivative. First prepared by Thiele,18 PTAD remained unused in organic synthesis until Cookson reported its powerful dienophilic properties some 70 years later.19 PTAD is an isolable, red, crystalline compound, prepared by r-butyl hypochlorite oxidation of 4-phenylurazole.20 Other oxidants which have been successfully... 

It is the combination of exceptional reactivity and reasonable stability, either as a solid or in solution, that makes PTAD such an ideal dienophile. However, PTAD is decomposed to N2, CO and phenyl isocyanate by the action of UV light.61 The cyclic ADC compounds (6-23) all undergo the Diels-Alder reaction, although with the exception of phthalazine-l,4-dione (13, R = H), they have been used only occasionally. l,3,4-Thiadiazole-2,5-dione (11) is of comparable reactivity to PTAD,38 but like the other cyclic compounds (6-23) has the slight disadvantage in that it has to be generated in situ. 

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