Siloxy 1 + 2 cycloaddition

Coupling of alkenylcarbene complexes and siloxy-substituted 1,3-dienes affords vinylcyclopentene derivatives through a formal [3C+2S] cycloaddition process. This unusual reaction is explained by an initial [4C+2S] cycloaddition of the electron-poor chromadiene system as the 471 component and the terminal double bond of the siloxydiene as the dienophile. The chromacyclohexene intermediate evolves by a reductive elimination of the metal fragment to generate the [3C+2S] cyclopentene derivatives [73] (Scheme 26). 

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>. 

In addition to siloxy- and alkoxy-substituted VCPs, alkyl- and H-substituted VCPs are also effective in the intermolecular [5 + 2]-cycloaddition reaction (Scheme 11). In general, an increase in the steric bulk of the cyclopropane substituent (H vs. Me vs. Pr1) leads to increased reaction rates, putatively through preferential population of the more reactive as-oid arrangement of the vinyl and cyclopropane moieties.43... 

Modes of cycloaddition of alkylideneallyl cation are also controlled by the reaction conditions. [4 + 3] Cycloaddition occurs in the reaction with furan. The [4 + 3] cycloaddition with furan was observed for the siloxy-substituted allyl cation 5S, but not for the methoxy-substituted allyl cation 5M. The lower electrophilicity of 5S may prefer the concerted pathway of [4 + 3] cycloaddition in competition with the stepwise pathway to yield a [3 + 2] cycloadduct and an electrophilic substitution product. 

Kende described an impressive example of the use of the [34-4] cycloaddition in natural product synthesis (Scheme 14.10) [101]. A key nortropinone intermediate for the total synthesis of ( )-isostemofoHne 105 was acquired through the tropane system 104, which was formed from the [34-4] cycloaddition of pyrrole 103 and a siloxy-substituted vinylcarbenoid of 87 in 90% yield. 

An elegant application of the [3 + 4] cycloaddition methodology was showcased in model studies directed toward the synthesis of the core skeleton of CP-263114 115 (Scheme 14.12) [103]. The key step is the intramolecular [3 + 4] cycloaddition of furan with the siloxy-substituted vinyldiazoacetate in 112. The oxabicychc system 113 was obtained in 68% yield and was converted in eight steps to furnish the core structure 114 [103]. 

But there are many cases known where the (4+2) cycloaddition fails even with siloxy-activated dienes, e.g., methyl (E)-crotonate does not react with diene 1 at normal pressure and elevated temperature llO C), whereas the aprotic double Michael addition does give the desired bicyclo[2.2.2]octane in high yield. This reaction gives mainly (92%) bicyclic esters with the endo configuration. 

Silyl-substituted diazoketones 29 cycloadd with aryl isocyanates to form 1,2,3-triazoles 194 (252) (Scheme 8.44). This reaction, which resembles the formation of 5-hydroxy-l,2,3-triazoles 190 in Scheme 8.43, has no analogy with other diazocarbonyl compounds. The beneficial effect of the silyl group in 29 can be seen from the fact that related diazomethyl-ketones do not react with phenyl isocyanate at 70 °C (252). Although the exact mechanistic details are unknown, one can speculate that the 2-siloxy-1-diazo-1-alkene isomer 30 [rather than 29 (see Section 8.1)] is involved in the cycloaddition step. With acyl isocyanates, diazoketones 29 cycloadd to give 5-acylamino-l,2,3-thiadiazoles 195 by addition across the C=S bond (252), in analogy with the behavior of diazomethyl-ketones and diazoacetates (5). 

The construction of the tricyclo[5.2.0.02,6]nonane (26, n = 1) and tricyclo[6.2.0.02,7]decane (26, n = 2) frameworks involved the [2 4- 2] cycloaddition of readily accessible31,32 l,2-bis(trimethyl-siloxy)cyclobutene and cnone 25, n = 1 or 2, respectively.33 The yields (75-80%) were good for adducts 26a, c, e, and g. Lower yields (40-50%) were observed for adducts 26b and 26f, while adduct 26d was only isolated in a trace amount. The most interesting and important reaction, related to the total synthesis of eudesmane sesquiterpenes, was the photochemical reaction of (-)-piperitone (25g) with l,2-bis(trimethylsiloxy)cyclobutene, which gave c/.v,(5wf/u W-2/j,7/i-dimethyl-4/ -isopropyl-l f ,8Jf -bis(triniethylsiloxy)tricyclo[6.2.0.0z 7]dec-3-one (26g) with the relative cis configuration of the methyl (R2) and isopropyl (R3) groups.33,34 Some of the other photochemical [2 + 2] cycloaddition reactions utilizing l,2-bis(trimethyl-siloxy)cyclobutene are shown by the formation of 2735,36 and 28.37... 

The [2 + 2] cycloaddition of tetrafluoroethene (1) with silyl- and siloxy-substituted alkenes (9) can be a preparatively useful reaction.21... 

Cycloaddition of 1-Dimethylamino-3-siloxy-1,3-butadiene with Methyl Acrylate Application to the Synthesis of 4-Hydroxyethyl-2-cyclohexen-1-one. 

The control of regiochemistry has been rationalized on the basis of the orbital coefficients of the HOMOs and LUMOs, but in fact, it is not well understood. In most cases such cycloadditions are not regiospecific and isomeric mixtures are formed, although one regioisomer usually predominates. Qualitative estimation of the electron distributions in the diene and dienophile can often be used to predict the major product. For example, C-l of siloxy diene (A) should be much more electron rich than C-4. In addition C-3 of acrylate (B) should be more electron deficient than C-2. 

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,... 

The availability of phosphaalkenes and phosphaalkynes has led to a further route for the synthesis of phosphiranes and phosphirenes by the formal addition of carbenes or carbenoides to P-C multiple bonds. An example already depicted in Scheme 6 involved in the [2+1] cycloaddition reaction of a stable phosphinotrimethylsilylcarbene to tert-butylphosphaalkyne <1995JA10785, 1999CEJ274>. A carbenoid was also used in the synthesis of an unusual phosphirene from a siloxy-substituted phosphaalkene (Equation 30) <1997JOM(529)127>. 

The synthetic scheme of Suzuki et al. [59] was based on the fact that adducts resulting from furan addition often rearrange to phenols (compare with [61]). In our group, we also investigated the reactions of naphthoquinones with siloxy-furans such as 64. However, instead of the expected [4 + 2] cycloaddition, a Michael addition that proceeded without catalyst occurred in the reaction with 3-chlorojuglone (63) [39]. Interestingly, both the Michael acceptor 63 and the donor 64 reacted in a 1,4-reaction mode. The regio- and stereochemistry of the product 65 were confirmed by x-ray analysis (Scheme 18). 

Cycloalkenones generally perform poorly as dienophiles in Diels-Alder reactions but their reactivity can be enhanced by Lewis acids [105]. SnCU is effective in promoting the Diels-Alder reaction between simple 1,3-butadienes, for example isoprene and piperylene, and cyclopentenone esters (Eq. 67) [106], Cycloaddition does not, however, occur in the presence of SnCU when the diene contains an oxygen-bearing substituent such as an alkoxy or siloxy group. For such compounds, as is generally true for the Diels-Alder reactions of cycloalkenones, other Lewis acids such as zinc chloride are more effective. 

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