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Sakurai, reaction

Named Organic Reactions, Second Edition T. Laue and A. Plagens 2005 John Wiley Sons, Ltd ISBNs 0-470-01040-1 (HB) 0-470-01041-X (PB) [Pg.246]

The intramolecular Sakurai reaction allows for the synthesis of functionalized bicyclic systems. By proper choice of the reaction conditions, especially of the Lewis acid or fluoride reagent used, high stereoselectivity can be achieved, which is an important aspect for its applicability in natural products synthesis. [Pg.247]

Propargylsilanes can also be employed in the Sakurai reaction. For example the enone 6, containing a propargylsilane side chain, undergoes an intramolecular Sakurai reaction, catalyzed by an acidic ion-exchange resin—e.g. Amberlyst-15—to give stereoselectively the bicyclic product 7 in good yield  [Pg.247]

As Lewis acid, titanium tetrachloride, boron trifluoride or ethylaluminum dichloride is often used. The stereochemical outcome of the reaction strongly depends on the Lewis acid used. The Sakurai reaction is a relatively new carbon-carbon forming reaction, that has been developed into a useful tool for organic synthesis.  [Pg.247]

Fleming, J. Dunogues, R. Smithers, Org. React. 1989, 37, 57-575 for competitive reaction pathways, and reactions with allyltriisopropylsilane see H.-J. Knolker, J. Prakt. Chem. 1997, 339, 304-314. [Pg.247]


Conventional synthetic schemes to produce 1,6-disubstituted products, e.g. reaction of a - with d -synthons, are largely unsuccessful. An exception is the following reaction, which provides a useful alternative when Michael type additions fail, e. g., at angular or other tertiary carbon atoms. In such cases the addition of allylsilanes catalyzed by titanium tetrachloride, the Sakurai reaction, is most appropriate (A. Hosomi, 1977). Isomerization of the double bond with bis(benzonitrile-N)dichloropalladium gives the y-double bond in excellent yield. Subsequent ozonolysis provides a pathway to 1,4-dicarbonyl compounds. Thus 1,6-, 1,5- and 1,4-difunctional compounds are accessible by this reaction. [Pg.90]

This section describes Michael-analogous processes in which, mostly under electrophilic conditions, ally - or alkynylsilanes undergo addition to enones or dienones (Sakurai reactions). The intramolecular addition of allylsilanes is an extremely useful reaction especially for the construction of carbocyclic ring systems, which occurs in a diastereoselective manner, in many cases with complete asymmetric induction. [Pg.937]

Sakurai reactions proceed regiospecifically with a large variety of electrophiles due to the so-called /1-effect5-9. However, allylsilanes are also known as masked allyl carbanions, which may be activated by the presence of fluoride ion10-12. [Pg.937]

In the Sakurai reaction, the product-determining step should be the nucleophilic addition of the allylsilane to the Lewis acid coordinated enone28. [Pg.939]

In the first example of an intramolecular Sakurai reaction, a six-membered ring was formed in the presence of boron trifluoride-diethyl ether complex starting from an acyclic enone36. [Pg.942]

In the synthesis of spirocyclic systems via an intramolecular Sakurai reaction, allylsilanes with an allyl moiety attached to the 3-position of the 2-cyclohexenone are required as starting materials. [Pg.942]

A variety of electrophilic catalysts promote the addition of allylic silanes to carbonyl compounds.86 The original catalysts included typical Lewis acids such as TiCl4 or BFj.87 This reaction is often referred to as the Sakurai reaction. [Pg.815]

Entries 4 and 5 are examples of use of the Sakurai reaction to couple major fragments in multistage synthesis. In Entry 4 an unusual catalyst, a chiral acyloxyboronate (see p. 126) was used to effect an enantioselective coupling. (See p. 847 for another application of this catalyst.) Entry 5 was used in the construction of amphidinolide P, a compound with anticancer activity. [Pg.827]

Scheme 1.14. Domino ene/Sakurai reaction for the synthesis of polysubstituted tetrahydropyrans. Scheme 1.14. Domino ene/Sakurai reaction for the synthesis of polysubstituted tetrahydropyrans.
A combination of a Sakurai reaction [447] as the first step with an ene reaction has been developed by Tietze and coworkers for the synthesis of steroids [448]. These studies are discussed in Chapter 4. [Pg.184]

Allylation of aldehydes or ketones using allylsilanes, known as the Hosomi-Sakurai reaction, is a useful method for obtaining homoallylic alcohols. TiIV compounds have been successfully applied to this reaction (Scheme 21) 80 Besides aldehydes and ketones, acylsilanes, 0,0-acetals, and A-,(7-acetals can be employed.81-83 1,4-Addition of an allyl group to an a,/ -unsaturated ketone has been also reported.84... [Pg.407]

The bromoallene (-)-kumausallene (62) was isolated in 1983 from the red alga Laurencia nipponica Yamada [64a], The synthesis of the racemic natural product by Overman and co-workers once again employed the SN2 -substitution of a propargyl mesylate with lithium dibromocuprate (Scheme 18.22) [79]. Thus, starting from the unsymmetrically substituted 2,6-dioxabicyclo[3.3.0]octane derivative 69, the first side chain was introduced by Swern oxidation and subsequent Sakurai reaction with the allylsilane 70. The resulting alcohol 71 was protected and the second side chain was attached via diastereoselective addition of a titanium acetylide. The synthesis was concluded by the introduction of two bromine atoms anti-selective S -substitution of the bulky propargyl mesylate 72 was followed by Appel bromination (tetrabromo-methane-triphenylphosphine) of the alcohol derived from deprotection of the bromoallene 73. [Pg.1011]

This tandem intramolecular silylformylation/Sakurai reaction has successfully been applied in a formal total synthesis of mycoticin A [75]. The scope and utility of these reactions was expanded to (Z)- and (E)-crotyl groups leading to the stereospecific incorporation of both anti and syn propionate units into the growing polyol chain (Scheme 21) [76]. [Pg.89]

Scheme 21 Synthesis of polyol fragments via silylformylation/Sakurai reaction... Scheme 21 Synthesis of polyol fragments via silylformylation/Sakurai reaction...
Scheme 22 Application of the silylformylation/Sakurai reaction in the synthesis of poly-ketides... Scheme 22 Application of the silylformylation/Sakurai reaction in the synthesis of poly-ketides...
Lewis acid-mediated addition of allylsilanes to carbon nucleophiles. Also known as the Hosomi-Sakurai reaction. The allylsilane will add to the carbonyl compound directly if it is not part of an a,P-unsaturated system (Example 2), giving rise to an alcohol. [Pg.518]

Simultaneously to the synthetic studies described above, our model studies had progressed. Although the synthetic challenge in this part of the project was marginal the structure elucidation of the final products was complicated [41]. Starting material for the syntheses was 1-acetyl-1-cyclopentene (58) which was converted into the frans-cyclopentane rac-59 by a Sakurai reaction and a carbonyl olefination (Scheme 16). The synthesis of czs-cyclo-... [Pg.17]

The introduction of the allylic silane moiety required for the intermolec-ular Hosomi-Sakurai reaction is depicted in Scheme 16. Following the formation of the enol triflate 97, a Stille coupling provided excess to the allylic alcohol 98 [51]. The allylic alcohol (98) was endowed with a phosphate leaving group for the subsequent allylic substitution. Utilizing a trimethylsilyl cuprate as nucleophile for the 5 2 reaction, the allylic phosphate was converted into the allylic silane 89. A useful substrate-induced diastereoselectivity in favour of (14i )-89 was encountered at small scale but decreased significantly upon up-scaling. [Pg.96]

The dihydropyran 88 served as the precursor for an oxocarbenium ion that was utilized as the acceptor for the intermolecular Hosomi-Sakurai reaction [53, 54]. Utilizing a second Hosomi-Sakurai reaction, pyran 88 was synthesized as outlined in Scheme 17 [53, 54]. Easy accessible MOM protect-... [Pg.96]


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Allylsilanes, Sakurai allylation reaction

Allylsilanes, Sakurai allylation reaction nucleophilicity

And the Sakurai reaction

Asymmetric reactions Sakurai allylation reaction

Aza-Sakurai reaction

Aza-Sakurai-Hosomi reaction

Carbonyl compounds Sakurai allylation reaction

Catalytic reactions Sakurai allylation reaction, asymmetric

Enantioselective Sakurai-Hosomi Allylation Reactions

Enantioselective Sakurai-Hosomi reaction

Hosomi-Sakurai Allylation and Related Reactions

Hosomi-Sakurai reaction

Promoters Sakurai allylation reaction

Sakurai

Sakurai allylation reaction

Sakurai allylation reaction Lewis acid-carbonyl complex

Sakurai allylation reaction mechanism

Sakurai multicomponent reactions

Sakurai reaction Alkylaluminum halides

Sakurai reaction Allyltrimethylsilane

Sakurai reaction Samarium iodide

Sakurai reaction Titanium chloride

Sakurai reaction mechanism

Sakurai reaction special

Sakurai reaction stereoselectivity

Sakurai-Hosomi allylation reaction

Sakurai-Hosomi reaction complexes

Sakurai-carbonyl-ene reaction

Silyl-modified Sakurai reaction

The Modified Sakurai and Related Reactions

The Silyl-modified Sakurai Reaction

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