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Lewis nonchelating

A syn-selective asymmetiic nih o-aldol reaction has been reported for structurally simple aldehydes using a new catalyst generated from 6,6-bis[(tiiethylsilyl)ethynyl]BINOL (g in Scheme 3.18). The syn selectivity in the nitro-aldol reaction can be explained by steric hindrance in the bicyclic transition state as can be seen in Newman projection. In the favored h ansition state, the catalyst acts as a Lewis acid and as a Lewis base at different sites. In conbast, the nonchelation-controlled transition state affords anti product with lower ee. This stereoselective nitro-aldol reaction has been applied to simple synthesis of t/ireo-dihydrosphingosine by the reduction of the nitro-aldol product with H2 and Pd-C (Eq. 3.79). [Pg.61]

The second important group of configuralionally stable bis-protected a-amino aldehydes are the V-dibenzvl derivatives 5, easily prepared from amino acids in a three-step procedure65. These aldehydes react with various nucleophiles to normally provide the nonchelation-con-trolled adducts in high diastereoselectivity. This anti selectivity is observed when diethyl ether or telrahydrofuran is used as reaction solvent. Certain Lewis acidic nucleophiles or additives, such as tin(IV) chloride, in dichloromethane as solvent force chelation and therefore provide the. syn-adducts, once again with a high diastereoselectivity. [Pg.92]

The reaction between a-alkoxyaldehydes and allylsilanes is highly stereoselective in favor of chelation-controlled products if tin(IV) chloride is used as the Lewis acid, whereas boron trifluoride gives modest stereoselectivity in favor of the nonchelation-controlled product58. [Pg.348]

Titanium enolates, which are weak Lewis acids, add to 2-alkoxyaldehydes with remarkable stereoselectivity under nonchelation control 1. Thus, 2-benzyloxypropanal is attacked by the tris(isopropyloxy)titanium enolate 7 preferably from the 57-face, to give a 87 13 mixture of adducts with complete simple diastereoselectivity3,1. [Pg.565]

The combination of metal tuning and double stereodifferentiation helps to prepare chelation and nonchelation products in the imine series7. In the case of an alkoxy substituent adjacent to the aldimino, the chelation product 10 is predominantly obtained with allylmagnesium chloride, chloromagnesium allyltriethylaluminate or allylzinc bromide, while the use of allyl-boronates or allyltitanium triisopropoxide, which lack the requisite Lewis acidity for chelation, gives 11 with good Cram selectivity. [Pg.749]

These examples and those in Scheme 2.6 illustrate the key variables that determine the stereochemical outcome of aldol addition reactions using chiral auxiliaries. The first element that has to be taken into account is the configuration of the ring system that is used to establish steric differentiation. Then the nature of the TS, whether it is acyclic, cyclic, or chelated must be considered. Generally for boron enolates, reaction proceeds through a cyclic but nonchelated TS. With boron enolates, excess Lewis acid can favor an acyclic TS by coordination with the carbonyl electrophile. Titanium enolates appear to be somewhat variable but can be shifted to chelated TSs by use of excess reagent and by auxiliaries such as oxazolidine-2-thiones that enhance the tendency to chelation. Ultimately, all of the factors play a role in determining which TS is favored. [Pg.125]

The reaction of (Z)-/J-methylcrotylsilane with 2-benzyloxypropanal in the presence of chelative SnCL gives the awfi-homoallylic alcohol 40 diastereoselectively (equation 26)78. The use of chelative TiCLt versus nonchelative BF3 OEt2 Lewis acids also gives different stereoselectivity in the coupling of allylsilane with the aldehydes 41 (equation 27)79. [Pg.1804]

Stereoselective additions to chiral a- and -alkoxy aldehydes. Lewis-acid-catalyzed additions of enol silyl ethers to chiral ct-alkoxy or (3-alkoxy aldehydes can proceed with high 1,2- and 1,3-asymmetric induction. Moreover, the sense of induction can be controlled by the Lewis acid. Thus BF, which is nonchelating, can induce diastereo-... [Pg.494]

P-Keto esters and -keto amides, each substituted between the two carbonyl units with a 2-[2-(tri-methylsilyl)methyl] group, also undergo Lewis acid catalyzed, chelation-controlled cyclization. When titanium tetrachloride is used, only the product possessing a cis relationship between the hydroxy and ester (or amide) groups is product yields range from 65 to 88% (Table 8). While loss of stereochemistry in the product and equilibration of diastereomers could have occurred via a Lewis acid promoted retro aldol-aldol sequence, none was observed. Consequently, it is assumed that the reactions occur under kinetic, rather than thermodynamic, control. In contrast to the titanium tetrachloride promoted process, fluoride-induced cyclization produces a 2 1 mixture of diastereomeric products, and the nonchelating Lewis acid BF3-OEt2 leads to a 1 4.8 mixture of diastereomers. [Pg.247]

Thus, internal chelation of the Lewis-base functional group should be able to differentiate the reactivity of the two carbon-metal bonds toward two different electrophiles. Indeed, the internal chelation of the oxygen atom to the metal m, decreases the reactivity of the latter toward the first electrophile (such as phenylsulfonyl halide or phenylsulfonyl cyanide), and thus the nonchelated metal m2 reacts preferentially with this electrophile (Scheme 7-5) [8]. [Pg.148]

In the presence of ZnBr2, nonchelation controlled addition of lithiated MN-dimethylacetamide to 2,3-O-cyclohexylidene-4-deoxy-i.-threose benzylimine proceeds in high stereoselectivity. The absence of the Lewis acid results in a slight preference for the other isomer. The product is used in the synthesis of l-daunosamine (equation 49). ... [Pg.349]

An example of this type of effort is as follows. Complexation of the carbonyl oxygen of N/(-dibenzyl-a-amino aldehydes wiA Lewis acids such as BF3, ZnBr2 or SnCU, followed by ad tion of trimethylsilyl cyanide leads to adducts formed by a nonchelation-controlled process. Complexation with TiCU or MgBr2 affords the opposite stereochemistry preferentially, tl ugh a chelation-controlled process (Scheme 1). ... [Pg.460]

Usefiil levels of stereoselectivity were obtained in intermolecular addition reactions of C(3)-sub-stituted allylsilanes to chiral aldehydes. Lewis acids that are citable of chelating to heteroatoms have been used to direct the stereochemical course of allylsilane additions to a-alkoxy and a,p-dialkoxy carbonyl compounds. The allylation of a-benzyloxy iddehyde (94) in the presence of TiG4 and SnOt furnished products with high levels of syn stereoselection (syn-9. In contrast, under nonchelation-controlled reaction conditions (BF3-OEt2) allyltrimethylsilane reacted to form predonunantly the anti-1,2-diol product (anti-95), as shown in Scheme 45. [Pg.612]


See other pages where Lewis nonchelating is mentioned: [Pg.38]    [Pg.44]    [Pg.51]    [Pg.54]    [Pg.60]    [Pg.63]    [Pg.67]    [Pg.86]    [Pg.1015]    [Pg.201]    [Pg.796]    [Pg.449]    [Pg.643]    [Pg.1804]    [Pg.143]    [Pg.98]    [Pg.512]    [Pg.1696]    [Pg.143]    [Pg.181]    [Pg.321]    [Pg.337]    [Pg.339]    [Pg.358]    [Pg.321]    [Pg.337]    [Pg.339]    [Pg.358]   
See also in sourсe #XX -- [ Pg.203 ]




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