Silyl enol ethers Diels-Alder reaction

The most frequently encountered, and most useful, cycloaddition reactions of silyl enol ethers are Diels-Alder reactions involving silyloxybutadicncs (Chapter 18). Danishefsky (30) has reviewed his pioneering work in this area, and has extended his studies to include heterodienophiles, particularly aldehydes. Lewis acid catalysis is required in such cases, and substantial asymmetric induction can be achieved using either a chiral lanthanide catalyst or an a-chiral aldehyde. 

The scope and efficiency of [4+2] cycloaddition reactions used for the synthesis of pyridines continue to improve. Recently, the collection of dienes participating in aza-Diels Alder reactions has expanded to include 3-phosphinyl-l-aza-l,3-butadienes, 3-azatrienes, and l,3-bis(trimethylsiloxy)buta-l, 3-dienes (1,3-bis silyl enol ethers), which form phosphorylated, vinyl-substituted, and 2-(arylsulfonyl)-4-hydroxypyridines, respectively <06T1095 06T7661 06S2551>. In addition, efforts to improve the synthetic efficiency have been notable, as illustrated with the use of microwave technology. As shown below, a synthesis of highly functionalized pyridine 14 from 3-siloxy-l-aza-1,3-butadiene 15 (conveniently prepared from p-keto oxime 16) and electron-deficient acetylenes utilizes microwave irradiation to reduce reaction times and improve yields <06T5454>. 

A similar enantiomer-selective activation has been observed for aldol " and hetero-Diels-Alder reactions.Asymmetric activation of (R)-9 by (/f)-BINOL is also effective in giving higher enantioselectivity (97% ee) than those by the parent (R)-9 (91% ee) in the aldol reaction of silyl enol ethers (Scheme 8.12a). Asymmetric activation of R)-9 by (/f)-BINOL is the key to provide higher enantioselectivity (84% ee) than those obtained by (R)-9 (5% ee) in the hetero-Diels-Alder reaction with Danishefsky s diene (Scheme 8.12b). Activation with (/ )-6-Br-BINOL gives lower yield (25%) and enantioselectivity (43% ee) than the one using (/f)-BINOL (50%, 84% ee). One can see that not only steric but also electronic factors are important in a chiral activator. 

Pyrroles are obtained by reduction of 1,2-diazines (80JMC481). This reaction has been used in conjunction with inverse electron demand Diels-Alder reactions to prepare 3,4-disubstituted pyrrole-2, 5-dicarboxylic acid derivatives(Scheme 67). Silyl enol ethers or enamines can also serve as the electron-rich dienophiles thus, silyl ethers of ester enolates give 3-methoxypyrroles (84JOC4405). 

Stereoselective synthesis of /1-amino esters via asymmetric aldol-type and aza-Diels-Alder reactions has been reviewed.81 Siliranes react cleanly with benzaldehyde to produce oxasilacyclopentanes—with inversion—under conditions of Bu OK catalysis enolizable aldehydes yield silyl enol ethers.82... 

Diels-Alder reaction with cyclopentadienes. An improved synthesis of a key intermediate (6) to gibberellic acid (7) begins with the cycloaddition of 1 to a 2 1 mixture of 2- and l-(2-bromoallyl)cyclopentadiene (2) to give the adduct 3 in which the acetyl group has the enr/o-orientation. The silyl enol ether of 3 when heated undergoes a Cope rearrangement to give a eis-hydrindene (4), which was converted... 

Diels-Alder reactionsBoth 1,4-dicyanonaphthalene (DCN) and 2,6,9,10-te-tracyanoanthracene (TCA) have been used as sensitizers to effect photochemical [4 + 2]cycloadditions of electron-rich dienes and electron-rich dienophiles, which do not normally undergo thermal cycloadditions. These cycloadditions are known as triplex Diels-Alder reactions because they are postulated to involve as an intermediate a three-membered complex of sensitizer, dienophile, and diene. This reaction is useful for synthesis of bicyclo[2.2.2]octenes from some silyl enol ethers, alkenes, or arylalkynes. 

C(2)-C(3) fused polycyclic cephalosporins have received considerable attention as new candidates for /3-lactam antibiotics. An access to tricyclic cephalosporins based on metal-promoted alkenylation of 3-trifloxy-A3-cephem and subsequent Diels-Alder reaction has been published <1996TL5967>. Alternatively, the reaction of a cephalosporin triflate with silyl enol ethers and silylketene acetals has been described to afford tri- and tetracyclic cephalosporins <1996TL7549>. A related process is the formation of fused polycyclic cephalosporins 27 and 28 bearing a wide range of functionalities from the reaction of cephalosporin triflates 26 with unsaturated compounds (alkenes and alkynes) and a base (Scheme 5) <1997JOC4998>. These studies have suggested that the reaction proceeds via the intermediacy of a six-membered cyclic allene which undergoes concerted nZs + K2a cycloaddition with alkenes and acetylenes. 

The reactions of silenes with aldehydes and ketones is another area whose synthetic aspects have been particularly well-studied4,6 7 10 12. The favoured reaction pathways for reaction are generally ene-addition (in the case of enolizable ketones and aldehydes) to yield silyl enol ethers and [2 + 2]-cycloaddition to yield 1,2-siloxetanes (equation 44), but other products can also arise in special cases. For example, the reaction of aryldisilane-derived (l-sila)hexatrienes (e.g. 21a-c) with acetone yields mixtures of 1,2-siloxetanes (51a-c) and ene-adducts (52a-c) in which the carbonyl compound rather than the silene has played the role of the enophile (equation 45)47,50 52 98 99. Also, [4 + 2]-cycloadducts are frequently obtained from reaction of silenes with a,/i-unsaturated- or aryl ketones, where the silene acts as a dienophile in a formal Diels-Alder reaction6 29,100-102. 

Figure 4-7 shows a typical hetero Diels-Alder reaction of a nitrosoalkene. Upon in situ generation of the heterodiene 4-34 from the oxime 4-33, cycloaddition occurred in the presence of the silyl enol ether 4-35 to give the 5,6-dihydro-4H- 1,2-oxazine 4-36 in excellent yield [366]. Such conversions are very suitable for achieving kinetic resolutions of -/Z-isomeric silyl enol ethers since the Z-isomers are distinctly less reactive towards 4-34 [367]. 

Scheme 1.20. Double Michael-type addition of dienolate 220 to Cgo, affording after workup the thermodynamically more stable Irans-disubstiluted ketone ( )-219. Due to steric congestion, the corresponding civ-adduct is not available through Diels-Alder reaction with the silyl enol ether corresponding to 220. Reduction of the racemic ketone ( )-219 with DIBAL-H diastereoselec-tively affords alcohol ( )-223.

Three reactions, which were known from the literature to be catalyzed by Lewis acids were selected as test reactions. A, was the Reetz alkylation of silyl enol ethers with -butyl chloride for which titanium tetrachloride is known to be useful [52]. B, was the Diels-Alder reaction between furan and acetylenedicarboxylic ester for which aluminium trichloride is a good catalyst [53]. C, was a Friedel-Crafts acylation for which aluminium trichloride is the preferred catalyst [54]. The reactions are summarized in Scheme 6. 

A Alkylation of silyl enol ether B, Diels-Alder reaction, C, Friedel-Crafts reaction. b As a rough estimate of the kinetics, f50, which is defined as the time necessary to obtain 50% of the final yield was used. 

Conjugate addition of enol silyl ethers can also be effected in this way.7 A similar reaction with dienol silyl ethers affords cyclized products. This variation of a Diels-Alder reaction can be useful because it can afford stereoisomers of the products formed by reactions catalyzed by conventional Lewis acids. 

Mukaiyama Aldol Condensation. As expected, the chiral titanium complex is also effective for a variety of carbon-carbon bond forming processes such as the aldol and the Diels-Alder reactions. The aldol process constitutes one of the most fundamental bond constructions in organic synthesis. Therefore the development of chiral catalysts that promote asymmetic aldol reactions in a highly stereocontrolled and truly catalytic fashion has attracted much attention, for which the silyl enol ethers of ketones or esters have been used as a storable enolate component (Mukaiyama aldol condensation). The BINOL-derived titanium complex BINOL-TiCl2 can be used as an efficient catalyst for the Mukaiyama-ty pe aldol reaction of not only ketone si ly 1 enol ethers but also ester silyl enol ethers with control of absolute and relative stereochemistry (eq 11). ... 

Copper complexes derived from bis(-2,6-dichlorophenyle-dene)-( 15,25)-1,2-diaminocyclohexane (11) catalyze various reactions such as Diels-Alder reaction, aziridination (eq 20), cyclopropanation, and silyl enol ether addition to pyruvate esters. Although the scope of these reactions may be sometimes limited, enantioselectivities are generally high. The same complex (with copper(I) salts) catalyzes the asymmetric insertion of silicon- hydrogen bond into carbenoids. ... 

The synthetic value of highly oxygenated 1,3-dienes in both the Diels-Alder and hetero Diels-Alder reaction is evident from the outstanding work of the Danishefsky group. They typically prepared such compounds, e.g. (52), by converting the a q>ropriate ketone into its enol silyl ether. 

The la-promoted imino Diels-Alder reaction is highly susceptible to the Lewis acid employed and to the structure of substrates. iV-Phenyl aromatic aldimine 34 readily cyclizes with the silyl enol ether of 35 under the influence of 10 mol % Ic to give exo adduct 36 exclusively (Sch. 26), whereas up to 98 % endo selectivity is observed when AICI3 is used at 20 °C [55a]. 

Keck also investigated asymmetric catalysis with a BINOL-derived titanium complex [102,103] for the Mukaiyama aldol reaction. The reaction of a-benzyloxyalde-hyde with Danishefsky s dienes as functionalized silyl enol ethers gave aldol products instead of hetero Diels-Alder cycloadducts (Sch. 40) [103], The aldol product can be transformed into hetero Diels-Alder type adducts by acid-catalyzed cyclization. The catalyst was prepared from BINOL and Ti(OPr )4, in 1 1 or 2 1 stoichiometry, and oven-dried MS 4A, in ether under reflux. They reported the catalyst to be of BINOL-Ti(OPr% structure. 

In the presence of 10 mol % Sc(OTf)3, A-benzylideneaniline reacts with 2-trans-l-methoxy-3-trimethylsiloxy-l, 3-butadiene (Danishefsky s diene) [23] to afford the corresponding aza Diels-Alder adduct, a tetrahydropyridine derivative, quantitatively (Eq. 7) [24]. In the reaction of A -benzylideneaniline with cyclopentadiene under the same conditions, on the other hand, the reaction course ehanged and a tetrahydroqui-noline derivative was obtained (Eq. 8). In this reaction, the imine aeted as an azadiene toward one of the double bonds of cyclopentadiene as a dienophile [25]. In the reaction with 2,3-dimethylbutadiene a mixture of tetrahydropyridine and tetrahydroqui-noline derivatives was obtained. A vinyl sulfide, a vinyl ether, and a silyl enol ether worked well as dienophiles to afford the tetrahydroquinoline derivatives in high yields [26,27]. 

Kobayashi et al. found that lanthanide triflates were excellent catalysts for activation of C-N double bonds —activation by other Lewis acids required more than stoichiometric amounts of the acids. Examples were aza Diels-Alder reactions, the Man-nich-type reaction of A-(a-aminoalkyl)benzotriazoles with silyl enol ethers, the 1,3-dipolar cycloaddition of nitrones to alkenes, the 1,2-cycloaddition of diazoesters to imines, and the nucleophilic addition reactions to imines [24], These reactions are efficiently catalyzed by Yb(OTf)3. The arylimines reacted with Danishefsky s diene to give the dihydropyridones (Eq. 14) [25,26], The arylimines acted as the azadienes when reacted with cyclopentadiene, vinyl ethers or vinyl thioethers, providing the tet-rahydroquinolines (Eq. 15). Silyl enol ethers derived from esters, ketones, and thio-esters reacted with N-(a-aminoalkyl)benzotriazoles to give the /5-amino carbonyl compounds (Eq. 16) [27]. The diastereoselectivity was independent of the geometry of the silyl enol ethers, and favored the anti products. Nitrones, prepared in situ from aldehydes and N-substituted hydroxylamines, added to alkenes to afford isoxazoli-dines (Eq. 17) [28]. Addition of diazoesters to imines afforded CK-aziridines as the major products (Eq. 18) [29]. In all the reactions the imines could be generated in situ and the three-component coupling reactions proceeded smoothly in one pot. 

Compounds with an additional 2-vinyl group, easily available in two steps from a,J -unsaturated ketones, are of special interest. If the reactive vinyl ketone moiety is liberated, it can be trapped in situ by suitable nucleophiles, e.g. CH-acids, generating polyfunctional compounds or by a diene unit which undergoes an intramolecular Diels-Alder reaction (equation 93). Besides, radical additions to the vinylcyclopropane are also possible giving silyl enol ethers as ring-opened products . Future synthetic applications of theses processes are obvious. 

Two homo Diels-Alder reactions and a hetero Diels-Alder reaction, each using a silyloxydiene, have been used in a total synthesis of vinemycinone methyl ester (236) by Danishefsky (84JA2453 85JA1285). Ketoaldehyde 231, prepared by two Diels-Alder cycloadditions, reacted with diene 230 in chloroform in the presence of Eu (fod)j to produce the silyl enol ether... 

Further extension of the reaction pool of Schilf bases 138 was achieved by their reaction with tran -l-methoxy-3-(trimethylsilyloxy)-1,3-butadiene (Danishefsky s diene) to give 2-substituted 5,6-didehydro-piperidin-4-ones 164 [135,136] (Scheme 10.54). The reaction is considered to be a sequence of an initial Mannich reaction between the imine and the silyl enol ether, followed by an intramolecular Michael addition and subsequent elimination of methanol. If the reaction was terminated by dilute ammonium chloride solution, then the Mannich bases 163 could be isolated and further transformed to the dehydropiperidinones 164 by treatment with dilute hydrochloric acid. This result proved that the reaction pathway is not a concerted hetero Diels-Alder type process between the electron-rich diene and the activated imine. The use of hydrogen chloride as a terminating agent resulted in exclusive isolation of the piperidine derivatives 164 formed with... 

Eor comparison, ATPH can be used for this kind of differentiation more efficiently in the hetero-Diels-Alder reaction [58]. With ATPH, silyl enol ether Si-1 exhibited adequate potential for the aldolization unlike the observed poor reactivity with KSA alone using the above Eu-catalyst (Scheme 2-26 Table 2-4). Even the /i-sub-stituents of the aldehydes can be differentiated (entries 4 and 5, Table 2-4). The het-ero-atom-containing aldehyde was effectively discriminated, showing non-chelation ability of ATPH (entry 6, Table 2-4). When aldehydes are encapsulated in the ATPH cavity, the hitherto small steric effects turned out in these cases to be dominant. The importance of the effect of the cavity was illustrated further by a comparative experiment with bulky MAD (5 6=3.7 1). 

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