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Stereoselective allylation

Ikegami s successful synthesis of racemic 720 materialized by initial conversion of 701 to 725 via a 1,2-carbonyl transposition sequence (Scheme LXXVIII) Treatment of 725 with methoxycarbene, deprotection, and oxidation provided 72 6. Acid-promoted cyclopropane ring cleavage and added functional group manipulation led to 727 which could be allylated stereoselectively. The tricyclic enone 724 was subsequently produced conventionally. [Pg.70]

Alkylation of aldol type educts, e.g., /3-hydroxy esters, using LDA and alkyl halides leads stereoselectively to erythro substitution. The erythro threo ratio of the products is of the order of 95 5. Allylic and benzylic bromides can also be used. The allyl groups can later be ozonolysed to gjve aldehydes, and many interesting oligofunctional products with two adjacent chiral centres become available from chiral aldol type educts (G. Prater, 1984 D. Seebach, 1984 see also M. Nakatsuka, 1990, p. 5586). [Pg.27]

A conceptually surprising and new route to prostaglandins was found and evaluated by C.R. Johnson in 1988. It involves the simple idea to add alkenylcopper reagents stereo-selectively to a protected chiral 4,5-dihydroxy-2-cyclopenten-l-one and to complete the synthesis of the trisubstituted cyclopentanone by stereoselective allylation of the resulting enolate. [Pg.276]

Allylation of the 10-carborane 236 (pKa = 18-22) with diallyl carbonate is possible under neutral conditions to give 237[146], Allylation and rearrangement of the trialkylalkynylborane 238 affords the trisubstituted alkene 239 stereoselectively [ 147],... [Pg.322]

Silyl ethers serve as preeursors of nucleophiles and liberate a nucleophilic alkoxide by desilylation with a chloride anion generated from CCI4 under the reaction conditions described before[124]. Rapid intramolecular stereoselective reaction of an alcohol with a vinyloxirane has been observed in dichloro-methane when an alkoxide is generated by desilylation of the silyl ether 340 with TBAF. The cis- and tru/u-pyranopyran systems 341 and 342 can be prepared selectively from the trans- and c/.y-epoxides 340, respectively. The reaction is applicable to the preparation of 1,2-diol systems[209]. The method is useful for the enantioselective synthesis of the AB ring fragment of gambier-toxin[210]. Similarly, tributyltin alkoxides as nucleophiles are used for the preparation of allyl alkyl ethers[211]. [Pg.336]

Carboxylate anions are better nucleophiles for allylation. The monoepoxide of cyclopentadiene 343 is attacked by AcOH regio- and stereoselectively via tt-aliylpalladium complex formation to give the m-3,5-disubstituted cyclopen-tene 344[212]. The attacks of both the Pd and the acetoxy anion proceed by inversion (overall retention) to give the cis product. [Pg.337]

Allylic phosphates are used for carbonylation in the presence of amines under pressure. Carbonylation of diethyl neryl phosphate (389) affords ethyl homonerate (390), maintaining the geometric integrity of the double bond[244]. The carbonylation of allyl phosphate in the presence of the imine 392 affords the /3-lactam 393. The reaction may be explained by the formation of the ketene 391 from the acyl phosphate, and its stereoselective (2 + 2] cycloaddition to the imine 392 to give the /3-lactam 393(247],... [Pg.342]

Highly regio- and stereoselective 4a-deuteration in steroids is possible by the hydrogenolysis of the cyclic allylic /3-carbonate 628 with NaBD4. the extent of 6a-deuteration is only 3%[393],... [Pg.376]

The Pd-catalyzed hydrogenolysis of vinyloxiranes with formate affords homoallyl alcohols, rather than allylic alcohols regioselectively. The reaction is stereospecific and proceeds by inversion of the stereochemistry of the C—O bond[394,395]. The stereochemistry of the products is controlled by the geometry of the alkene group in vinyloxiranes. The stereoselective formation of stereoisomers of the syn hydroxy group in 630 and the ami in 632 from the ( )-epoxide 629 and the (Z)-epoxide 631 respectively is an example. [Pg.376]

The stereoselective allylic rearrangement of the allylic alcohol 798 catalyzed by PdCl2(MeCN)2 and Ph3P under Mitsunobu inversion conditions is explained as proceeding via a rr-allylpalladium intermediate[496]. The smooth rearrangement of the allylic p-tolylsulfone 799 via a rr-allylpalladium intermediate is catalyzed by a Pd(0) catalyst[497]. [Pg.400]

Hydrosilylation of I-vinyl-1-cyclohexene (77) proceeds stereoselectively to give the (Z)-l-ethylidene-2-silylcyclohexane 78, which is converted into (Z)-2-ethylidenecyclohe.xanol (79)[74]. Hydrosilylation of cyclopentadiene affords the 3-silylated 1-cyclopentene 80. which is an allylic silane and used for further transformations[75.75a]. Cyclization of the 1,3,8, lO-undecatetraene system in the di(2.4-pentadienyl)malonate 69 via hydrosilylation gives the cyclopentane derivative 81. which corresponds to 2.6-octadienylsilanc[l8,76]. [Pg.435]

An asymmetric synthesis of estrone begins with an asymmetric Michael addition of lithium enolate (178) to the scalemic sulfoxide (179). Direct treatment of the cmde Michael adduct with y /i7-chloroperbenzoic acid to oxidize the sulfoxide to a sulfone, followed by reductive removal of the bromine affords (180, X = a and PH R = H) in over 90% yield. Similarly to the conversion of (175) to (176), base-catalyzed epimerization of (180) produces an 85% isolated yield of (181, X = /5H R = H). C8 and C14 of (181) have the same relative and absolute stereochemistry as that of the naturally occurring steroids. Methylation of (181) provides (182). A (CH2)2CuLi-induced reductive cleavage of sulfone (182) followed by stereoselective alkylation of the resultant enolate with an allyl bromide yields (183). Ozonolysis of (183) produces (184) (wherein the aldehydric oxygen is by isopropyUdene) in 68% yield. Compound (184) is the optically active form of Ziegler s intermediate (176), and is converted to (+)-estrone in 6.3% overall yield and >95% enantiomeric excess (200). [Pg.436]

This reaction illustrates a stereoselective preparation of (Z)-vinylic cuprates, which are very useful synthetic intermediates. They react with a variety of electrophiles such as carbon dioxide, epoxides, aldehydes, allylic halides, alkyl halides, and acetylenic halides they undergo... [Pg.7]

Another useful modification of this reagent is the reaction of CF3CCI3 with zinc and DMF in the presence of AICI3 [60, 63] (equation 53). The alcohol product can be treated subsequently with DAST, thionyl chloride, or phosphorus chlorides to afford the allyl substitution product regio- and stereoselectively [66] (equation 54). [Pg.683]

Intramolecular cycloadditions of substrates with a cleavable tether have also been realized. Thus esters (37a-37d) provided the structurally interesting tricyclic lactones (38-43). It is interesting to note that the cyclododecenyl system (w = 7) proceeded at room temperature whereas all others required refluxing dioxane. In each case, the stereoselectivity with respect to the tether was excellent. As expected, the cyclohexenyl (n=l) and cycloheptenyl (n = 2) gave the syn adducts (38) and (39) almost exclusively. On the other hand, the cyclooctenyl (n = 3) and cyclododecenyl (n = 7) systems favored the anti adducts (41) and (42) instead. The formation of the endocyclic isomer (39, n=l) in the cyclohexenyl case can be explained by the isomerization of the initial adduct (44), which can not cyclize due to ring-strain, to the other 7t-allyl-Pd intermediate (45) which then ring-closes to (39) (Scheme 2.13) [20]. While the yields may not be spectacular, it is still remarkable that these reactions proceeded as well as they did since the substrates do contain another allylic ester moiety which is known to undergo ionization in the presence of the same palladium catalyst. [Pg.65]

Recently, Charette et al. have also demonstrated this behavior in the stereoselective cyciopropanations of a number of enantiopure acyclic allylic ethers [47]. The high degree of acyclic stereocontrol in the Simmons-Smith cyclopropanation has been extended to synthesis several times, most notably in the synthesis of small biomolecules. Schollkopf et al. utilized this method in their syntheses of cyclopropane-containing amino acids [48 a, b]. The synthesis of a cyclopropane-containing nucleoside was also preformed using acyclic stereocontrol [48c]. [Pg.105]

Dipolar cydoadditions are one of the most useful synthetic methods to make stereochemically defined five-membered heterocydes. Although a variety of dia-stereoselective 1,3-dipolar cydoadditions have been well developed, enantioselec-tive versions are still limited [29]. Nitrones are important 1,3-dipoles that have been the target of catalyzed enantioselective reactions [66]. Three different approaches to catalyzed enantioselective reactions have been taken (1) activation of electron-defident alkenes by a chiral Lewis acid [23-26, 32-34, 67], (2) activation of nitrones in the reaction with ketene acetals [30, 31], and (3) coordination of both nitrones and allylic alcohols on a chiral catalyst [20]. Among these approaches, the dipole/HOMO-controlled reactions of electron-deficient alkenes are especially promising because a variety of combinations between chiral Lewis acids and electron-deficient alkenes have been well investigated in the study of catalyzed enantioselective Diels-Alder reactions. Enantioselectivities in catalyzed nitrone cydoadditions sometimes exceed 90% ee, but the efficiency of catalytic loading remains insufficient. [Pg.268]

Most asymmetric induction processes with Chital auxiliaries involve a stereo-differentiating reaction that affords one diastereomet as the primary product To obtain the desired enantiomer, the Chiral auxiliary must be removed Highly dia-stereoselective reactions between otganocoppet reagents and allylic substrates with... [Pg.262]

A modern variant is the intramolecular magnesium-ene reaction, e.g. the reaction of the alkene-allylic-Grignard compound 9 to give the five-membered ring product 10. This reaction proceeds regio- and stereoselectively, and is a key step in a synthesis of the sesquiterpenoid 6-protoilludene ... [Pg.105]


See other pages where Stereoselective allylation is mentioned: [Pg.45]    [Pg.27]    [Pg.67]    [Pg.325]    [Pg.326]    [Pg.32]    [Pg.62]    [Pg.95]    [Pg.299]    [Pg.300]    [Pg.304]    [Pg.337]    [Pg.370]    [Pg.374]    [Pg.403]    [Pg.483]    [Pg.297]    [Pg.917]    [Pg.105]    [Pg.210]    [Pg.211]    [Pg.91]    [Pg.102]    [Pg.120]    [Pg.329]    [Pg.172]    [Pg.186]   
See also in sourсe #XX -- [ Pg.171 , Pg.177 , Pg.330 , Pg.340 ]

See also in sourсe #XX -- [ Pg.163 , Pg.167 , Pg.319 ]

See also in sourсe #XX -- [ Pg.163 , Pg.167 , Pg.319 ]




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Acyclic stereoselective synthesis allyl metal reagents

Alcohols, allylic stereoselectivity

Allyl alcohols stereoselective

Allyl carbonates stereoselective

Allyl external stereoselection

Allyl internal stereoselection

Allyl relative stereoselection

Allyl-substrate-controlled stereoselective

Allyl-substrate-controlled stereoselective reactions

Allylation stereoselection

Allylation stereoselectivity

Allylation stereoselectivity

Allylations stereoselective, allyltrimethylsilane

Allylic alcohols stereoselective hydroformylation

Allylic alcohols stereoselective/asymmetric

Allylic derivatives stereoselective cyclopropanation

Allylic derivatives stereoselectivity

Allylic internal stereoselection

Allylic p-hydroxysulfoxides stereoselective hydroxylation

Allylic stereoselective

Allylic stereoselective

Allylic stereoselective alkylation

Keck stereoselective allylation

Mannose, stereoselective allylation

Stereoselective allyl rearrangement

Stereoselective allylation reduction

Stereoselective allylic alkylations

Stereoselective arylation, allylic esters

Stereoselective reactions allylations, allyltrimethylsilane

Stereoselective synthesis allyl organometallics

Stereoselectivity allylic strain

Stereoselectivity allylic zinc-aldehyde reaction

Stereoselectivity epoxidation of allylic alcohols

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