Siloxycyclopropane

The aryl- and heteroarylfluorosilanes 541 can be used for the preparation of the unsymmetrical ketones 542[400], Carbonylation of aryl triflate with the siloxycyclopropane 543 affords the 7-keto ester 545. In this reaction, transme-tallation of the siloxycyclopropane 543 with acylpalladium and ring opening generate Pd homoenolate as an intermediate 544 without undergoing elimination of/3-hydrogen[401],... 

The transmetallation of the siloxycyclopropane 751 with the aryl- or alke-nylpalladium 752 generates the Pd homoenolate 753. and subsequent reductive elimination gives the /3-aryl or alkenyl ketone 754[618]. It should be noted that the Pd homoenolate 753 generated in this reaction undergoes reductive elimination without d-elimination. 

The chiral siloxycyclopropane 106 undergoes carbonylative homocoupling to form the 4-ketopimelate derivative 108 via the palladium homoenolate 107 without racemization. The reaction is catalytic in CHCI3, but stoichiometric in benzene[93]. 

Kuwajima, I. and Nakamura, E. Metal Homoenolates from Siloxycyclopropanes. 155,1-39 (1990). 

Longifolene has also been synthesized from ( ) Wieland-Miescher ketone by a series of reactions that feature an intramolecular enolate alkylation and ring expansion, as shown in Scheme 13.26. The starting material was converted to a dibromo ketone via the Mr-silyl enol ether in the first sequence of reactions. This intermediate underwent an intramolecular enolate alkylation to form the C(7)—C(10) bond. The ring expansion was then done by conversion of the ketone to a silyl enol ether, cyclopropanation, and treatment of the siloxycyclopropane with FeCl3. 

METHOXYCARBONYLMETHYLATION OF ALDEHYDES VIA SILOXYCYCLOPROPANES METHYL 3,3-DIMETHYL-4-OXOBUTANOATE... 

C. Methyl 3,3-dimethyl-4-oxobutanoate (3). A 50-mL flask, connected to a gas bubbler and equipped with a magnetic stirring bar, is charged with 20 mL of dichloromethane (or tetrahydrofuran), 2.16 g (10.0 mmol) of siloxycyclopropane 2 and 3.64 g (30.0 mmol) of triethylamine hydrofluoride (NEt3-HF) prepared in situ (Note 15). This mixture is stirred for 1 hr at room temperature (Note 16) and diluted with 20 mL of water. The aqueous phase is extracted with three 20-mL portions of dichloromethane. The combined organic phases are dried with magnesium sulfate, filtered, and concentrated on a rotary evaporator (bath temperature below 40°C). Crude product 3 is distilled with a Kugelrohr oven (oven temperature 105°C, 10 mm) to provide 1.26 g (87%) of pure 3 as a colorless liquid (Note 17). 

Siloxycyclopropane 2 is eluted very quickly. Final fractions contain dimethyl lumarate and maleate. If mixtures of 2 with these carbene dimers are obtained, the nitration through alumina has to be repeated. 

A major advantage of the sequence presented here is that the aldehyde group is protected at the siloxycyclopropane stage, which allows convenient storage of this stable intermediate. Of equal importance is the valuable carbanion chemistry that can be carried out a to the ester function. Efficient substitution can be achieved by deprotonation with LDA and subsequent reaction with electrophiles.12-13-6 This process makes several a-substituted [1-formyl esters available. Other ring opening variants of siloxycyclopropanes - mostly as one-pot-procedures - are contained in Scheme I. They underscore the high versatility of these intermediates for the synthesis of valuable compounds.6 Chiral formyl esters (see Table, entries 2-5) are of special... 

Entry Silyl Enol Ether Siloxycyclopropane (% yield) y-Oxoalkanoate (% yield)... 

Treatment of triarylbismuth difluorides with silylenolethers or siloxycyclopropanes in the presence of BF3 gave oxoalkyltriarylbismuth tetrafluoroborates (Scheme 21).24S,246,246a... 

On the other hand, the use of [Rh(CO)2Cl]2 as a catalyst results in ring opening of the siloxycyclopropanes 13 to the silyl enol ethers 14 with high stereoselectivity [10]. The 2-siloxyrhodacyclobutane 15a is proposed to undergo j8-elimination to give jr-allylrhodium 16a followed by reductive elimination to the silyl enol ether 14a. 1-Trimethylsiloxybicyclo[n.l.0]alkanes serve as / -metallo-carbonyl compounds via desilylation with a variety of transition metals [11]. The palladium-catalyzed reaction of the siloxycyclopropanes 17 under carbon monoxide in chloroform provides a route to the 4-keto pimelates 18. In the presence of aryl triflates, the 1,4-dicarbonyl compounds 19 are... 

The reaction of TeCl4 with siloxycyclopropanes, followed by treatment with DMSO, or bases such TMEDA, EtjN and pyridine, gives a-methylene ketones via the intermediacy of jS-oxoalkyl- or bis(/l-oxoalkyl)tellurium trichlorides or dichlorides. ... 

The last few years have seen the development of an entirely new methodology in which the metal homoenolate is prepared by ring opening of siloxycyclopropanes with metal halides Eq. (4). In these reactions, a very subtle balance of... 

The chemistry of cyclopropanol [7] has long been studied in the context of electrophilic reactions, and these investigations have resulted in the preparation of some 3-mercurio ketones. As such mercury compounds are quite unreactive, they have failed to attract great interest in homoenolate chemistry. Only recent studies to exploit siloxycyclopropanes as precursors to homoenolates have led to the use of 3-mercurio ketones for the transition metal-catalyzed formation of new carbon-carbon bonds [8] (vide infra). 

In 1977, an article from the authors laboratories [9] reported an TiCV mediated coupling reaction of 1-alkoxy-l-siloxy-cyclopropane with aldehydes (Scheme 1), in which the intermediate formation of a titanium homoenolate (path b) was postulated instead of a then-more-likely Friedel-Crafts-like mechanism (path a). This finding some years later led to the isolation of the first stable metal homoenolate [10] that exhibits considerable nucleophilic reactivity toward (external) electrophiles. Although the metal-carbon bond in this titanium complex is essentially covalent, such titanium species underwent ready nucleophilic addition onto carbonyl compounds to give 4-hydroxy esters in good yield. Since then a number of characterizable metal homoenolates have been prepared from siloxycyclopropanes [11], The repertoire of metal homoenolate reactions now covers most of the standard reaction types ranging from simple... 

Table 1. Siloxycyclopropanes prepared by the Simmons-Smith reaction...

The carbenoid from Et2Zn/CH2I2 [17], particularly when generated in the presence of oxygen [18], is more reactive than the conventional Simmons-Smith reagents. The milder conditions required are suitable for the preparation of 1-[16, 19] or 2-alkoxy-l-siloxycyclopropanes [20], which are generally more sensitive than the parent alkyl substituted siloxycyclopropanes (Table 2). Cyclopropanation of silyl ketene acetals is not completely stereospecific, since isomerization of the double bond in the starting material competes with the cyclopropanation [19]. 

The recent surge of interests in metal homoenolate chemistry has been stimulated by the recognition that the siloxycyclopropane route can afford novel reactive homoenolate species that are stable enough for isolation, purification, and characterization. The stability of such homoenolates crucially depends on the subtle balance of nucleophilic and electrophilic reactivity of the two reactive sites in the molecule. Naturally, homoenolates with metal-carbon bonds that are too stable do not serve as nucleophiles in organic synthesis. 

Similarly, siloxycyclopropanes (e.g., 3) react smoothly with mercuric acetate in methanol at 20 °C to give 3-mercurio ketones (e.g., 4) [8]. The attack of the metal occurs in such a way that the less alkyl-substituted bond is cleaved. Thus, starting from the enol silyl ether, the overall sequence represents a-mercurio-methylation of the parent ketone. The reaction is likely to proceed via an ionic intermediate Eq. (10). 

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