Tris silyl enol ethers

A neat mixture of the /l-unsaturated ketone (10mmol), triethylsilane (11 mmol), and tris(triphenylphosphine)rhodium(i) chloride (0.01 mmol) was stirred at 50°C for 2h, and the product silyl enol ether was distilled directly (yields 90-98%). 

Rhodium-catalysed addition (10) of hydridosilanes (Chapter 17) to a/3-unsaturated carbonyl compounds can be performed regioselectively, to afford either the product of 1,2-addition, or, perhaps more usefully, that of 1,4-addition, i.e. the corresponding silyl enol ether this latter process is an excellent method for the regiospecific generation of silyl enol ethers. Of all catalyst systems investigated, tris(triphenylphosphine)rhodium(l) chloride proved to be the best. 

A similar ring expansion has been reported in the oxidation of cyclopropanol 225 with manganese(III) tris(2-pyridinecarboxylate) to generate the / -keto radical, which is allowed to add to the silyl enol ether 226 [124], The... 

The 1,4-reduction of a,/3-unsaturated aldehydes is best carried out with diphenylsilane in the presence of zinc chloride and tetrakis(triphenylphosphine) palladium436 or a combination of triethylsilane and tris(triphenylphosphine) chlororhodium 437 Other practical approaches use phenylsilane with nickel (0) and triphenylphosphine438 and diphenylsilane with cesium fluoride.83 It is possible to isolate the initial silyl enol ether intermediate from the 1,4-hydrosilylation of o, /3-unsaturated aldehydes (Eq. 264).73,411 The silyl enol ethers are produced as a mixture of E and Z isomers. 

The aldol reactions introduced thus far have been performed under basic conditions where enolate species are involved as the reactive intermediate. In contrast to the commonly accepted carbon-anion chemistry, Mukaiyama developed another practical method in which enol species can be used as the key intermediates. He is the first chemist to successfully demonstrate that acid-catalyzed aldol reactions using Lewis acid (such as TiCU) and silyl enol ether as a stable enol equivalent can work as well.17 Furthermore, he developed the boron tri-fluoromethane sulfonate (triflate)-mediated aldol reactions via the formation of formyl enol ethers. 

With these results in hand, we have next introduced new types of Lewis acids, e.g scandium tris(-dodecyl sulfate) (4a) and scandium trisdodecanesul-fonate (5a) (Chart 1).[1S1 These Lewis acid-surfactant-combined catalysts (LASCs) were found to form stable colloidal dispersions with organic substrates in water and to catalyze efficiently aldol reactions of aldehydes with very water-labile silyl enol ethers. 

Tris(trimethylsilyl)silane [20,21], thiols [22], germanes [23-25] and gallium hydride [26] can be added easily to terminal alkynes in the presence of Et3B/02. This process was extended to internal alkenes (Scheme 8, Eq. 8a) as well as silyl enol ethers (Eq. 8b) by using tri-2-furylgermane. In this last case, basic or acidic treatment of the main syn /J-siloxygcrmanc furnishes the corresponding E- or Z-alkene, respectively [24],... 

In contrast, the closely related palladium acetate-promoted intramolecular alkylation of alkenes by tri-methylsilyl enol ethers (Scheme 4)6,7 has been used to synthesize a large number of bridged carbocyclic systems (Table 1). In principle, this process should be capable of being made catalytic in palladium(II), since silyl enol ethers are stable to a range of oxidants used to carry the Pd° -> Pd11 redox chemistry required for catalysis. In practice, catalytically efficient conditions have not yet been developed, and the reaction is usually carried out using a full equivalent of palladium(II) acetate. This chemistry has been used in the synthesis of quadrone (equation 2).8 With the more electrophilic palladium(II) trifluoroace-tate, methyl enol ethers underwent this cyclization process (equation 3).9... 

When 349 is generated thermally at 140 °C from mesitoyl-tris(trimethylsilyl)silane, the silyl enol ether 472 was isolated as the sole product". 472 results from isomerization of the siloxetane 470 (equation 156)". 

Arylation of silyl enol ethers.1 Silyl enol ethers of methyl n- or sec-alkyl ketones undergo arylation when treated with an aryl bromide and tri-n-butyltin fluoride and a... 

Diinetiiyl(2,4,<>-tri-f-biitylplienoxy.)dilorasi]ane (1). This silane is suggested as an alternative to the expensive t-butyldimethylchlorosilane. It is more easily prepared (equation I) and is comparable as a silylation reagent. The resulting silyl enol ethers... 

Allyl cyanides can be added across alkynes in the presence of a nickel catalyst prepared from (COD)2Ni and (4-CF3CeH4)3P in situ to give functionalized di- or tri-substituted acrylonitriles in a highly stereoselective manner, presumably via n-allylnickel intermediates. a-Siloxyallyl cyanides also react at the y -position of a cyano group with both internal and terminal alkynes to give silyl enol ethers, which can be converted into the corresponding aldehydes or ketones upon hydrolysis.70... 

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. 

Mixtures of 4-(difluoroiodo)toluene and anhydrous phosphoric acid form a nonisolated hypervalent iodine species, probably PhI(0H)(0P03H2), which reacts with silyl enol ethers producing tris-ketol phosphates. Interestingly, mono- or bis-ketol phosphates could not be obtained using the appropriate stoichiometry. 

The selective cyclopropanation of the a-enone silyl enol ether 75, by methylene iodide and the zinc-silver couple 2), is remarkable. Only the double bond bearing the tri-methylsiloxy group reacted to yield the 1-trimethylsiloxy vinylcyclopropane 76 when not more than 1.1 equivalent of the Simmons-Smith reagent was used, but the bis-cyclopropanation product 77 was obtained in good yield with an excess (3 equivalents) of the cyclopropanating reagent, Eq. (24) 42). 

The silyl enol ether may be obtained from the Fluka Chemical Corp., 255 Oser Avenue, Hauppauge, NY 11788. Alternatively, it may be prepared by the following modification of the procedure of Walshe and co-workers.2 The Walshe procedure is followed exactly with 36 g (0.30 mol) of acetophenone, 41.4 g (0.41 mol) of tri ethyl amine, 43.2 g (0.40 mol) of chlorotri-methylsilane, 60 g (0.40 mol) of sodium iodide, and 350 nt of acetonitrile. After extraction, the organic layer is dried over potassium carbonate and then concentrated with a rotary evaporator under reduced pressure. The crude product is a mixture of 97% of the desired silyl enol ether and 3% of acetophenone, as shown by gas chromatography. The crude product is distilled in a Claisen flask at a pressure of about 40 mm. After a small forerun (ca. 3... 

We might consider using the lithium enolate or the silyl enol ether. As we need the kinetic enolate (the enolate formed on the less substituted side of the ketone), we shall be using the lithium enolate to make the silyl enol ether, so it would make sense to try that first. 

Allyl silanes react with a wide variety of electrophiles, rather like the ones that react with silyl enol ethers, provided they are activated, usually by a Lewis acid. Titanium tetrachloride is widely used but other successful Lewis acids include boron trifluoride, aluminium chloride, and trim ethyls ilyl tri-flate. Electrophiles include the humble proton generated from acetic add. The regiocontrol is complete. No reaction is observed at the other end of the allylic system. All our examples are on the allyl silane we prepared earlier in the chapter. 

Compared to the great variety of Lewis acid catalysts for the catalytic asymmetric aldol reaction the field of nucleophilic (Lewis base) catalysts is less explored. This strategy involves the transient activation of the latent enolate equivalent via Lewis base coordination to the silyl enol ether (Scheme 9) [3], For instance the tri-chlorosilyl enol ether 50 is able to expand its valency at the silicon atom from four to five and six. It reacts with an aldehyde (51), proceeding through a closed Zimmerman-Traxler-like transition state (54), to give 53 after quenching with saturated aqueous NaHCO, [16]. 

This vanadium method enables the cross-coupling only in combinations of silyl enol ethers having a large difference in reactivity toward radicals and in their reducing ability. To accomplish the crosscoupling reaction of two carbonyl compounds, we tried the reaction of silyl enol ethers and a-stannyl esters based on the following consideration. a-Stannyl esters (keto form) are known to be in equilibrium with the enol form such as stannyl enol ethers, but the equilibrium is mostly shifted toward the keto form. When a mixture of an a-stannyl ester such as 45 and a silyl enol ether is oxidized, it is very likely that the stannyl enol ether will be oxidized preferentially to the silyl enol ether. The cation radical of 45 apparently cleaves immediately giving an a-keto radical, which reacts with the silyl enol ether selectively because of the low concentration of the stannyl enol... 

On the basis of these studies, a tetrafunctional silyl enol ether (18) carrying four such enolate functions has been prepared the corresponding trifunctional compound is also available [142]. These silyl enolates effectively couple living poly(vinyl ethers) with the chloride counteranion to form tri- and tetraarmed polymers (e.g., 19, Scheme 10) [205]. Similar chemistry also operates with living cationic poly(a-methylstyrene) but specifically needs the additional use of an amine to accelerate the release of the trimethylsilyl groups [159,207]. 

OL-Silyl ketones,l Silyl enol ethers with sterically hindered silyl groups rearrange to a-silyl ketones in the presence of /i-BuLi (2 equiv.) and KO-f-Bu (2.5 equiv.). Tri-methylsilyl ethers do not undergo this rearrangement, but triisopropylsilyl (TIPS) and diisopropylmethylsilyl (DIMS) ethers do if they contain an allylic a-proton. The silyl group rearranges preferentially to the less hindered terminus of the intermediate allyl anion. The rearrangement is less useful with acyclic substrates because of side reactions. 

SnCU is also the principal source of alkyltin chlorides, R SnCl4 [51]. Allyltrialkyl-tin reagents react with SnCU to produce allyltrichlorotin species through an Se2 pathway (Eq. 32) [52-56], Allyltrimethylsilanes react with SnCU to produce the corresponding allyltrichlorotin (Eq. 33) [57]. Silyl enol ethers react with SnCU to give a-tri-chlorotin ketones (Eq. 34) [58]. Transmetalation or metathesis reactions of this type... 

In contrast, moderate enantioselectivity is observed in the protonation of l-(tri-methylstannyl)methyl-2-phenylcyclohexene as a (Z)-allyltrimethyltin, and the absolute stereochemical selectivity is analogous to that in the protonation of the silyl enol ether derived from 2-phenylcyclohexanone (Sch. 6). 

As shown in Scheme 38, several primary alkyl-substituted cyclohexanones have been prepared by Lewis acid catalyzed phenylthioalkylation of the TMS enol ether of cyclohexanone followed by reductive removal of a phenylsulfenyl group. The two-step neopentylation sequence is particularly noteworthy. This methodology has been used to prepare numerous a-alkylated cyclic and acyclic ketones. a-Alkylated aldehydes can be produced in a like manner. a-Alkylidenation can also be accomplished by oxidative removal of sulfur. Lee and coworkers have found that TMS triflate-catalyzed reactions of silyl enol ethers of cyclic ketones and aldehydes with saturated and unsaturated l,l-dimethoxy-(i>-tri-methylstannanes, followed by addition of titanium tetrachloride, provide novel routes to fused and spiro-cyclic ring systems. Phenylthiomethylstannylations of silyl enol ethers have also been reported. ... 

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