Diels-Alder reaction metal carbonyls

The LPDE system is applied to several reactions in which the metal ions coordinate to the lone pairs of heteroatoms, thereby activating the substrate. Initially, the effectiveness was shown in Diels Alder reactions (Scheme 1). In a highly concentrated (5.0 M) LPDE solution, Diels- Alder reactions proceeded smoothly.6-7 Generally, a catalytic amount of LiC104 is not effective in this reaction. In some cases, a catalytic amount of an additional Bronsted acid, such as camphorsulphonic acid (CSA), gives better results.8 An interesting double activation of carbonyl moieties by using dilithium compounds has been reported (compound... 

The utility of bis(oxazoline)-Cu(II) complexes as catalysts for the Diels-Alder reaction has been examined in a number of other systems. Aggarwal et al. (205) demonstrated that a-thioacrylates behave as effective two-point binding substrates for these catalysts. With cyclopentadiene, catalyst 271d induces the reaction at -78°C to provide the cycloadduct in 94 6 diastereoselectivity and >95% ee. Aggarwal proposes that the metal binds to the carbonyl oxygen and to the sulfur atom. The sulfur substituent is placed opposite the ligand substituent thereby shielding the bottom face of the alkene. Considerably lower selectivities are observed with 5-Me substrates. 

A further useful reaction sequence, reported by Aumann [219], is based on the Diels-Alder reaction of 2-pyranylidene complexes with enamines (Figure 2.36). Retro-Diels-AIder reaction of the initially formed 3-oxabicycIo[2.2.2]octan-2-ylidene complex leads to elimination of metal hexacarbonyl and formation of a substituted cyclohexadiene. Although this sequence can also be performed with the corresponding carbonyl compounds (2//-2-pyranones), these normally... 

Crystal structure of 60 revealed that the complex existed as a dimeric species where the two chromium centers are bridged through the indane oxygen and each chromium metal bears one molecule of water (Figure 17.6). It was therefore proposed, as for the inverse electron-demand hetero Diels-Alder reaction, that the barium oxide desiccant removed one molecule of bound water from the catalyst dimer, which opened one coordination site for binding of the substrate carbonyl.26... 

An important challenge in the asymmetric catalytic Diels-Alder reaction is the use of simple ketone dienophiles to obtain high enantioselectivity. Indeed, the success of chiral Lewis acid-mediated Diels-Alder reactions is founded upon the use of dienophiles such as aldehydes, esters, quinones [36-43], and bidentate chelating carbonyls [44-47], where high levels of lone pair discrimination are achieved in the metal association step, an organizational event that is essential for enantiocontrol. In contrast, Lewis acid coordination to ketone dienophiles is generally non-selective, since the participating lone pairs are positioned in similar steric and electronic environments (Eq. 4). The ability for diastereomeric activa-... 

Recently a comparative study of the asymmetric Diels-Alder reactions of both (5)-benzyl 2-p-tolylsulfinylacrylate (167) and (S)-benzyl methyl 2-p-tolylsulfinyl maleate (168) was carried out.104 Consequently, improved mechanistic models were developed in order to explain the behavior of such sulfinyl maleate and acrylate dienophiles in asymmetric Diels-Alder reactions.104 It was postulated that conformational equilibrium around the C-S bond must be completely shifted toward the rotamer with the sulfinyl oxygen in an s-cis arrangement (the most stable from an electrostatic point of view), making favored approach of the diene from the less hindered upper face supporting the lone electron pair (Fig. 7). The chelation of the sulfinyl and carbonyl oxygens with metals shifts the conformational equilibria... 

Carbonyl compounds have also been used as electrophiles with the intermediate 719 to afford a-allenic alcohols758,783 788 1016 1030,1033-1051 and, after hydrolysis, the corresponding hydroxy enones1034 1037 1051. The chiral acrylate equivalent endo-2-acryloylisoborneol (726), used in metal-free Diels-Alder reactions, has been prepared by reaction of (-El-camphor with compound 7191039 (Scheme 190). 

These complexes are the first examples of multifunctional catalysts and demonstrate impressively the opportunities that can reside with the as yet hardly investigated bimetallic catalysis. The concept described here is not limited to lanthanides but has been further extended to main group metals such as gallium [31] or aluminum [32]. In addition, this work should be an incentive for the investigation of other metal-binaphthyl complexes to find out whether polynuclear species play a role in catalytic processes there as well. For example, the preparation of ti-tanium-BINOL complexes takes place in the presence of alkali metals [molecular sieve ( )]. A leading contribution in this direction has been made by Kaufmann et al, as early as 1990 [33], It was proven that the reaction of (5)-la with monobromoborane dimethyl sulfide leads exclusively to a binuclear, propeller-like borate compound. This compound was found to catalyze the Diels-Alder reaction of cyclopentadiene and methacrolein with excellent exo-stereoselectivity and enantioselectivity in accordance with the empirical rule for carbonyl compounds which has been presented earlier. 

The Diels-Alder reaction is a key reaction in organic synthesis. Its high versatility in the synthesis of six-membered ring compounds and its potential for the control of up to four stereogenic centers have attracted much attention. Lewis acid catalysis has further enhanced the scope of this reaction. Lewis acids activate the dienophile by coordination to a Lewis basic substituent (usually a carbonyl group) and direct the stereochemistry. Boron Lewis acids are often the catalysts of choice for the Diels-Alder reaction. Early (Ti(IV)) and late (Cu(II)) transition metal complexes in combination with chiral ligands have also been used with much success and the reader is referred to the relevant chapters in this book. 

It has been reported that several transition metal complexes catalyze the hetero-Diels-Alder reaction between a variety of aldehydes, in particular benzaldehyde, and Danishefsky s diene (Sch. 52). With the [CpRu(CHIRAPHOS)] complex the ee is modest (25 %) (entry 1) [192]. The chiral complex VO(HFBC)2 performs better in this reaction (entry 2) [193]. In experiments directed towards the synthesis of anthra-cyclones, this complex was used in cycloadditions between anthraquinone aldehydes with silyloxy dienes. One example is shown in Sch. 53 [194]. Compared with the chiral aluminum catalyst developed earlier by Yamamoto and co-workers [195], the vanadium catalyst results in lower enantioselectivity but has advantages such as ease of preparation, high solubility, stability towards air and moisture, and selective binding to an aldehyde carbonyl oxygen in the presence of others Lewis-basic coordination sites on the substrate. 

Triorganylbismuthines can mediate such C-C bond forming reactions as shown in Scheme 5.38 in the presence or absence of a transition metal salt. Tributylbismuthine promotes the allylation of carbonyl compounds with allylic bromide [91HAC297] and the olefination of diazo compounds with carbonyl compounds in the presence of catalytic amounts of a copper(I) halide [90TL5897]. A combination of triphenylbismuthine and WCle promotes the metathesis of olefins, while a similar combination with TiC facilitates the stereoselective Diels-Alder reaction of unsaturated esters [76TMC183, 93JOC4783]. 

This is an important area with many available methods. We shall look first at organic catalysis and then change to catalysis by metal complexes. The same type of intermediate 117 used for conjugate addition is clearly also suitable for Diels-Alder reactions with the same proviso it must be more reactive then the a,(5-unsaturated carbonyl compound as that too can do Diels-Alder reactions. And of course the first formed product 118 must hydrolyse rapidly to release the catalyst 102. 

The carbonyl ene reaction is between a similarly reactive aldehyde and an alkene rather than aketene. Glyoxalate esters and chloral are typical of the carbonyl compounds involved. Asymmetric versions rely on Lewis acid catalysts similar to those used in Diels-Alder reactions based on Ti and A1 among other metals.43 A simple example is the formation of 190 from methyl glyoxalate and an alkene 189 catalysed by 0.5mol% of a BINOL-Ti complex 191. Other alkenes that react well are 192 -195. 

Early applications of chiral Lewis acid catalyzed stereoselective Diels Alder reactions used either boron- or aluminum-derived systems in carbocyclic ring formation18 1Q, or studied the effect of chiral shift reagents, such as Eu(hfc)3, in hetero-Diels-Alder cycloadditions of carbonyl compounds to dienes20 23,77, 78. The latter type of transition metal catalyzed addition is classified as heterocarboration and is described in Section 1.5.8.4. 

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