Diene inverse electronic demand

Design of enamine-iminium cascades Examples of [4-1-2] reactions with enamine-activated dienes Inverse-electron-demand [4-1-2] reactions with enamine-activated dienophiles Enamine-iminium-enamine cascades... 

Diels-Alder reactions can be divided into normal electron demand and inverse electron demand additions. This distinction is based on the way the rate of the reaction responds to the introduction of electron withdrawing and electron donating substituents. Normal electron demand Diels-Alder reactions are promoted by electron donating substituents on the diene and electron withdrawii substituents on the dienophile. In contrast, inverse electron demand reactions are accelerated by electron withdrawing substituents on the diene and electron donating ones on the dienophile. There also exists an intermediate class, the neutral Diels-Alder reaction, that is accelerated by both electron withdrawing and donating substituents. 

Most reactions discussed can be classified into two types of [n s+iAs cycloadditions, the normal and inverse electron-demand cycloaddition reactions, based on the relative energies of the frontier molecular orbitals of the diene and the dieno-phile (Scheme 4.2) [4]. 

The normal electron-demand reaction is a HOMOdiene-LUMOdienophUeelectron-rich dienes and electron-deficient dienophiles (Scheme 4.2, left dotted line). The inverse electron-demand cycloaddition reaction is primarily controlled by a LUMOdiene HOMOdienophiie inter-... 

There are Diels-Alder reactions known where the electronic conditions outlined above are just reversed. Such reactions are called Diels-Alder reactions with inverse electron demand For example the electron-poor diene hexachlorocy-clopentadiene 21 reacts with the electron-rich styrene 22 ... 

However, when 3,5-diphenyl-4//-pyrazol-4-one, a reagent that undergoes Diels- Alder reactions with inverse-electron demand, is used, addition of the 2,4-diene part of oxepin to one of the two C-N double bonds of the pyrazolone is observed to give 4.232... 

Intermolecular [4C+2S] cycloaddition reactions where the diene moiety is contained in the carbene complex are less frequent than the [4S+2C] cycloadditions summarised in the previous section. However, 2-butadienylcarbene complexes, generated by a [2+2]/cyclobutene ring opening sequence, undergo Diels-Alder reactions with typical dienophiles [34,35] (Scheme 59). Also, Wulff et al. have described the application of pyranylidene complexes, obtained by a [3+3] cycloaddition reaction (see Sect. 2.8.1), in the inverse-electron-demand Diels-Alder reaction with enol ethers and enamines [87a]. Later, this strategy was applied to the synthesis of steroid-like ring skeletons [87b] (Scheme 59). 

In another aspect of the mechanism, the effects of electron-donating and electron-withdrawing substituents (p. 1065) indicate that the diene is behaving as a nucleophile and the dienophile as an electrophile. However, this can be reversed. Perchlorocyclopentadiene reacts better with cyclopentene than with maleic anhydride and not at all with tetracyanoethylene, though the latter is normally the most reactive dienophile known. It is apparent, then, that this diene is the electrophile in its Diels-Alder reactions. Reactions of this type are said to proceed with inverse electron demand ... 

Diels-Alder cycloadditions involving norbomene 57 [34], benzonorbomene (83), 7-isopropylidenenorbomadiene and 7-isopropylidenebenzonorbomadiene (84) as dienophiles are characterized as inverse-electron-demand Diels-Alder reactions [161,162], These compounds react with electron-deficient dienes, such as tropone. In the inverse-electron-demand Diels-Alder reaction, orbital interaction between the HOMO of the dienophile and the LUMO of the diene is important. Thus, orbital unsymmetrization of the olefin it orbital of norbomene (57) is assumed to be involved in these top selectivities in the Diels-Alder cycloaddition. 

Terrier et al. have widely described Bfxs 4-nitro-substituted participating in a series of Diels-Alder processes. Bfx 4-nitro-substituted system could participate as diene, C = C - C = C system, or heterodiene, C = C - NO2 system, in an inverse electron demand reaction [62,63] or as dienophile, C = C or N = O systems, in a normal electron demand reaction [64-68]. Fxs have been reported as 1,3-dipole through the substructure C = - 0 reacting with... 

BINOL in conjunction with TiCl2(0-/-Pr)2 gives good enantioselectivity in a D-A reaction with a pyrone as the diene.116 This is a case of an inverse electron demand reaction and the catalysts would be complexed to the diene. 

A further hetero-Diels-Alder reaction with inverse electron demand between o-QM 3 as the dienophile and either of the two diastereomers of spiro dimer 9 as the diene provided the spiro trimers 31 and 32 (Fig. 6.25). The absolute configuration was derived from NMR experiments. It was moreover shown that only two of the four possible stereoisomeric trimers were formed in the hetero-Diels-Alder reaction the attack of the o-QM 3 occurred only from the side syn to the spiro ring oxygen.28... 

While disilene 5 does not undergo Diels-Alder reactions with 1,3-dienes, the [4+2]-cycloaddition products are formed with heterodienes, e.g. 1,4-diazabutadienes [17] or a-ketoimines [19]. It can be deduced that the electron deficient properties of such dienes cause them to readily take part in hetero-Diels-Alder reactions, which have inverse electron demands. This is corroborated by theoretical calculations which predict an inverse electron demand of the Si-Si double bond it is strongly electron donating rather than electron accepting towards butadienes and other compounds [24,25]. 

Tetrazine (171) and its derivatives are electron-deficient cycloaddends, which undergo [4 + 2] cycloadditions with inverse electron demand. When bicyclopropylidene (3) was added to a dichloromethane solution of 171, its red color disappeared within 1.5 h at room temperature. The white crystalline product isolated in 86% yield turned out to be a mixture of at least two stereoisomeric compounds 174, trimers of the 8,9-diazadispiro[2.0.2.4]deca-7,9-diene (173) evidently formed via the normal [4 + 2]-cycloadduct 172 after nitrogen extrusion (Scheme 25) [13b]. 

In diene reactions with inverse electron demands simple alkenes are most reactive. This is why these reactions have been used to identify simple alkenes. 

Af-Acyliminium ions are known to serve as electron-deficient 4n components and undergo [4+2] cycloaddition with alkenes and alkynes.15 The reaction has been utilized as a useftil method for the construction of heterocycles and acyclic amino alcohols. The reaction can be explained in terms of an inverse electron demand Diels-Alder type process that involves an electron-deficient hetero-diene with an electron-rich dienophile. Af-Acyliminium ions generated by the cation pool method were also found to undergo [4+2] cycloaddition reaction to give adduct 7 as shown in Scheme 7.16 The reaction with an aliphatic olefin seems to proceed by a concerted mechanism, whereas the reaction with styrene derivatives seems to proceed by a stepwise mechanism. In the latter case, significant amounts of polymeric products were obtained as byproducts. The formation of polymeric byproducts can be suppressed by micromixing. 

The interactions of the occupied orbitals of one reactant with the unoccupied orbitals of the other are described by the third term of the Klopman-Salem-Fukui equation. This part is dominant and the most important for uncharged reaction partners. Taking into account that the denominator is minimized in case of a small energy gap between the interacting orbitals, it is clear that the most important interaction is the HOMO-LUMO overlap. With respect to the Diels-Alder reaction, one has to distinguish between two possibilities depending on which HOMO-LUMO pair is under consideration. The reaction can be controlled by the interaction of the HOMO of the electron-rich diene and the LUMO of the electron-poor dienophile (normal electron demand) or by the interaction of the LUMO of an electron-poor diene and the HOMO of an electron-rich dienophile (inverse electron demand cf Figure 1). 

Although Diels-Alder reactions can occur in the unsubstituted case, the reaction is most successful when the diene and the dienophile contain substituents which exert a favorable electronic influence [19]. In the normal electron demand case, the most favorable interactions are between dienes with electron-donating groups and dienophiles with electron-withdrawing groups. Cases have been reported in which inverse electron demand occurs and the electronic nature of the diene and dienophile are reversed [20], [21], [22]. This case of inverse electron demand is accounted for in the system. 

The classical 4 + 2 Diels-Alder reaction involves the thermally allowed cycloaddition of an electron-rich (nucleophilic) diene a=b-c=d with an electron-deficient (electrophilic) dienophile e=f. In the polar cycloaddition reactions considered here, the a=b-c=d system bears a positive charge and is so obviously ill-suited for a nucleophilic role that the first examples of polar cycloaddition appeared inexplicable in terms of cycloaddition theory then current. In 1962 Sauer and Wiest demonstrated the existence of a Diels-Alder reaction with inverse electron demand in which the electronic roles of a=b-c=d and e=f are exchanged, with the former becoming the electrophile and the latter... 

The aza-Diels-Alder reaction is an important and versatile tool for the preparation of nitrogen-containing heterocycles present in numerous natural products and drug candidates. It involves the [4 + 2] cycloaddition of either an imine with an electron-rich diene or an azabutadiene with an electron-rich alkene (inverse electron demand). Catalytic asymmetric variants employing not only metal complexes, but also organic molecules were disclosed over the last few years. 

Aiming at the pyranose form of sugars, normal type hetero-Diels-Alder reactions were extensively used for the synthesis of functionally substituted dihydropyran and tetrahydropyran systems (5-10) (see routes A - D in the general Scheme 1) which are also important targets in the "Chiron approach" to natural product syntheses (2.) Hetero-Diels-Alder reactions with inverse electron demand such as a, p-unsaturated carbonyl compounds (l-oxa-1,3-dienes) as heterodienes and enol ethers as hetero-dienophiles, are an attractive route for the synthesis of 3,4-dihydro-2H-pyrans (11). 

The reactivity of the produced complexes was also examined [30a,b]. Since the benzopyranylidene complex 106 has an electron-deficient diene moiety due to the strong electron-withdrawing nature of W(CO)5 group, 106 is expected to undergo inverse electron-demand Diels-Alder reaction with electron-rich alkenes. In fact, naphthalenes 116 variously substituted at the 1-, 2-, and 3-positions were prepared by the reaction of benzopyranylidene complexes 106 and typical electron-rich alkenes such as vinyl ethers, ketene acetals, and enamines through the Diels-Alder adducts 115, which simultaneously eliminated W(CO)6 and an alcohol or an amine at rt (Scheme 5.35). 

The Pechmann and Knoevenagel reactions have been widely used to synthesise coumarins and developments in both have been reported. Activated phenols react rapidly with ethyl acetoacetate, propenoic acid and propynoic acid under microwave irradiation using cation-exchange resins as catalyst <99SL608>. Similarly, salicylaldehydes are converted into coumarin-3-carboxylic acids when the reaction with malonic acid is catalysed by the montmorillonite KSF <99JOC1033>. In both cases the use of a solid catalyst has environmentally friendly benefits. Methyl 3-(3-coumarinyl)propenoate 44, prepared from dimethyl glutaconate and salicylaldehyde, is a stable electron deficient diene which reacts with enamines to form benzo[c]coumarins. An inverse electron demand Diels-Alder reaction is followed by elimination of a secondary amine and aromatisation (Scheme 26) <99SL477>. 

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